Insulin Modulates Intracellular Apolipoprotein B mRNA Traffic
into RNA Granules/Cytoplasmic P Bodies: Implications in
Translational Control
by
Navaz Karimian Pour
A thesis submitted in conformity with the requirements for the degree of Master of Science
Graduate Department of Biochemistry
Faculty of Medicine
University of Toronto
©Copyright by Navaz Karimian Pour 2012
ii
Insulin Modulates Intracellular Apolipoprotein B mRNA Traffic into RNA Granules/ Cytoplasmic P Bodies: Implications in Translational Control
Navaz Karimian Pour
Master of Biochemistry
Department of Biochemistry University of Toronto
2012
Abstract
Apolipoprotein B (ApoB) synthesis is partially regulated at the translational level;
however, the molecular mechanisms that govern translational control of apoB mRNA
remains largely unknown. We imaged intracellular apoB mRNA traffic and determined
whether insulin silences apoB mRNA translation by trafficking into translationally-silenced
cytoplasmic RNA granules called Processing Bodies (PBS). ApoB mRNA was visualized by
using a strong interaction between the bacteriophage MS2 protein and a specific phage RNA
sequence that binds MS2 protein. We observed a statistically significant increase in the
localization of apoB mRNA into PBs, 4h, 8h, and 16h after insulin treatment. Conversely,
acute insulin treatment (1h) did not show any significant effect. Insulin was also found to
reduce polysomal association of apoB mRNA 4h and 16h post treatment in HepG2 cells.
Overall, our data suggest that chronic insulin treatment silences apoB translation in HepG2
cells by localizing apoB mRNA into PBs and reducing translationally-competent mRNA
pools.
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Table of Contents
Abstract .................................................................................................................................................. ii
Table of Contents .................................................................................................................................. iii
List of Figures ....................................................................................................................................... vi
List of Tables....................................................................................................................................... viii
List of abbreviations .............................................................................................................................. ix
I. Introduction ......................................................................................................................................... 1
1.1 Introduction to Lipoproteins......................................................................................................... 1
1.2 Apolipoprotein B .......................................................................................................................... 1
1.2.1 The Importance of Studying ApoB ....................................................................................... 2
1.2.2 Structural Features of Human ApoB Gene, mRNA, and Protein .......................................... 3
1.2.3 ApoB Protein Function and Importance ................................................................................ 6
1.2.4 Hepatic Regulation of ApoB Gene Expression ..................................................................... 6
1.3 Role of Insulin in Metabolic Regulation of ApoB ..................................................................... 12
1.3.1 Insulin Signaling Pathways Involved in ApoB Biosynthesis and Regulation ..................... 13
1.3.2 ApoB Overproduction in Insulin Resistance States (Type 2 Diabetes and Obesity) .......... 14
1.4 The Process of mRNA Translation ............................................................................................ 15
1.4.1 Translation Initiation ........................................................................................................... 15
1.4.2 Translation Elongation ........................................................................................................ 16
1.4.3 Translation Termination ...................................................................................................... 16
1.5 Translational Control ................................................................................................................. 16
1.6 The RNA Journey in the Cytosol ............................................................................................... 18
1.7 Localization of RNA in the Cytoplasm ...................................................................................... 19
1.7.1 Cytoplasmic RNA Granules ................................................................................................ 19
1.7.2 Stress Granules (SGs).......................................................................................................... 20
1.7.3 Processing Bodies (PBs) ..................................................................................................... 20
1.8 Rationale for the Current Studies ............................................................................................... 21
1.8.1 Objective ............................................................................................................................. 24
1.8.2 Hypothesis ........................................................................................................................... 24
1.8.3 Specific Aims ...................................................................................................................... 25
II. Materials and Methods .................................................................................................................... 26
iv
2.1 Polysomal Profiling .................................................................................................................... 26
2.1.1 Cell Culture ......................................................................................................................... 26
2.1.2 Insulin Treatment and Cell lysis .......................................................................................... 26
2.1.3 Sucrose Gradient and Ultracentrifugation ........................................................................... 27
2.1.4 Sucrose Gradient Fractionation ........................................................................................... 27
2.1.5 Total RNA Extraction, cDNA Synthesis, and Real-Time PCR .......................................... 28
2.1.6 Statistic Analysis ................................................................................................................. 29
2.2 Cytoplasmic RNA Granules ....................................................................................................... 31
2.2.1 Preparation of LB Media and LB Plates ............................................................................. 31
2.2.2 Plasmids .............................................................................................................................. 31
2.2.3 Transformation and Plasmid DNA Amplification .............................................................. 33
2.2.4 Restriction Enzyme Digestion ............................................................................................. 34
2.2.5 Gel extraction ...................................................................................................................... 34
2.2.6 Ligation Reaction ................................................................................................................ 35
2.2.7 Construction of pCMV-MS2bs-24X-cyto Plasmid ............................................................. 35
2.2.8 Construction of pCMV-5’URT-apoB15%-3’UTR-MS2-24X-cyto Chimeric Plasmid ...... 35
2.2.9 Direct DNA Sequencing...................................................................................................... 36
2.2.10 Transient Transfection Experiments ................................................................................. 36
2.2.11 Preparation of Collagen Coated plates .............................................................................. 37
2.2.12 GFP Expression and Insulin Treatment............................................................................. 38
2.2.13 Immunostaining Experiments ........................................................................................... 38
2.2.14 Confocal Microscopy Imaging .......................................................................................... 39
2.2.15 Using hDCP1a, a Second Primary Antibody, to Detect P bodies ..................................... 39
2.2.16 Puromycin Treatment ........................................................................................................ 39
2.2.17 Statistical Analysis of Imaging Data ................................................................................. 40
III. Results ............................................................................................................................................ 41
3.1 Polysome Profiling ..................................................................................................................... 41
3.1.1 Results of Constructing a Linear Sucrose Gradient ............................................................ 41
3.1.2 Effect of Insulin on apoB mRNA Translation ..................................................................... 42
3.1.3 Under conditions that inhibit apoB mRNA polysomal association, insulin acutely stimulates global translation ......................................................................................................... 46
3.1.4 Effect of Insulin on Beta-2-microglobulin mRNA Distribution (as a control) ................... 47
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3.1.5 Determination of ApoB mRNA Abundance and Optimization of Real Time PCR Experiments using Internal Controls ............................................................................................ 49
3.1.6 Effect of Acute Insulin Treatments on ApoB mRNA Translation (Data Normalized to Internal Control Gene) ................................................................................................................. 52
3.1.7 Effect of Chronic Insulin Treatments on ApoB mRNA Translation (Data Normalized to Internal Control Genes) ................................................................................................................ 54
3.1.8 Effect of Insulin on Polysomal Distribution of Beta-2-microglobulin mRNA ................... 56
3.2 Translational Control of ApoB mRNA: Role of Cytoplasmic Ribonucleoproteins ................... 57
3.2.1 Construction of pCMV-MS2bs-24X-cyto Plasmid ............................................................. 57
3.2.2 Construction of pCMV-5’UTR-ApoB15%-3’UTR-MS2bs-24X-cyto Chimeric Plasmid .. 60
3.2.3 Detection of P Bodies (PBs) in HepG2 Cells and the Influence of Puromycin on PB formation ...................................................................................................................................... 62
3.2.4 Employing the MS2 Tagging System to Visualize ApoB mRNA in HepG2 Cells ............ 65
3.2.5 Transfection of HepG2 Cells with pMS2-GFP-SV40 NLS Plasmid .................................. 66
3.2.6 Insulin Induces Co-localization of ApoB mRNA with P Bodies ........................................ 69
3.2.7 Insulin does not affect the Co-localization of Beta-Globin mRNA with P Bodies ............. 71
3.2.8 Statistical Analysis .............................................................................................................. 75
IV. Discussion ...................................................................................................................................... 77
4.1 Polysome Profiling ..................................................................................................................... 78
4.2 Storage of ApoB mRNA in Cytoplasmic RNA Granules .......................................................... 80
4.3 Postulated Mechanism of Insulin Modulation of ApoB mRNA Traffic into P bodies .............. 85
V. Conclusions ..................................................................................................................................... 88
VI. Future Directions ........................................................................................................................... 90
Reference List ...................................................................................................................................... 91
Appendix ............................................................................................................................................ 104
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List of Figures
Figure 1 Schematic diagram of the pentapartite structural model of apoB and a three-dimensional consensus
model for LDL ............................................................................................................................................... 5
Figure 2 Synthesis of a linear sucrose gradient. ................................................................................................... 42
Figure 3 Effect of short-term insulin treatment on apoB mRNA association with polysomes............................. 44
Figure 4 Effect of long-term insulin treatment on apoB mRNA association with polysomes ............................ 45
Figure 5 Insulin acutely stimulates global mRNA translation in HepG2 cells. .................................................... 47
Figure 6 Effect of long-term insulin treatment on Beta-2-microglobulin mRNA (positive control) association
with polysomes ............................................................................................................................................ 48
Figure 7 Validation of potential internal control genes ........................................................................................ 51
Figure 8 Effect of short-term insulin treatment on apoB mRNA association with polysomes (data normalized to
internal control genes) .................................................................................................................................. 53
Figure 9 Effect of long-term insulin treatment on apoB mRNA association with polysomes (data normalized to
internal control genes) .................................................................................................................................. 55
Figure 10 Effect of long-term insulin treatment on B2M mRNA (positive control) association with polysomes
(Data normalized to internal control genes) ................................................................................................. 56
Figure 11 Construction of pCMV-MS2bs-24X-cyto plasmid. ............................................................................. 59
Figure 12 Construction of pCMV-5’UTR-ApoB15%-3’UTR-MS2bs-24X-cyto plasmid. .................................. 61
Figure 13 Detection of P bodies in the cytoplasm of HepG2 cells. ...................................................................... 63
Figure 14 Effect of puromycin on P body formation ........................................................................................... 64
Figure 15 Construction map of MS2-GFP and apoB mRNA reporter plasmids .................................................. 66
Figure 16 Expression of pMS2-GFP-SV40 NLS vector and the effect of NLS. .................................................. 68
Figure 17 Visualizing apoB mRNA traffic in HepG2 Cells: Long-term exposure to insulin induced co-
localization of apoB mRNA with P bodies .................................................................................................. 70
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Figure 18 Visualizing apoB mRNA traffic in HepG2 Cells: Short term exposure to insulin did not induce co-
localization of apoB mRNA with P bodies .................................................................................................. 71
Figure 19 Effect of insulin on the co-localization of beta-globin mRNA with P bodies ...................................... 74
Figure 20 Quantification of apoB mRNA co-localization with P bodies ............................................................. 76
Figure 21 Quantification of beta-globin mRNA co-localization with P bodies ................................................... 76
Figure 22. A proposed model for insulin modulation of apoB mRNA traffic into P bodies ................................ 87
Figure 23 Visualizing apoB mRNA traffic in HepG2 Cells: 4 hour exposure to insulin induced co-localization
of apoB mRNA with P bodies. ................................................................................................................... 104
Figure 24 Visualizing apoB mRNA traffic in HepG2 Cells: 8 hour exposure to insulin induced co-localization
of apoB mRNA with P bodies. ................................................................................................................... 105
Figure 25 Visualizing apoB mRNA traffic in HepG2 Cells: 16 hour exposure to insulin induced co-localization
of apoB mRNA with P bodies. ................................................................................................................... 106
Figure 26 Visualizing apoB mRNA traffic in HepG2 Cells: 1 hour exposure to insulin din not induce co-
localization of apoB mRNA with P bodies ................................................................................................ 107
Figure 27 Effect of serum starvation on the co-localization of apoB mRNA with P bodies. ............................. 108
Figure 28 Effect of serum starvation on the co-localization of beta-globin mRNA with P bodies .................... 109
Figure 29 Effect of 1hour insulin exposure on the co-localization of beta-globin mRNA with P bodies. ......... 110
Figure 30 Effect of 4 hour insulin exposure on the co-localization of beta-globin mRNA with P bodies. ........ 111
Figure 31 Effect of 8 hour insulin exposure on the co-localization of beta-globin mRNA with P bodies. ........ 112
Figure 32 Effect of 16 hour insulin exposure on the co-localization of beta-globin mRNA with P bodies ....... 113
viii
List of Tables
Table 1 Characteristics of Plasma Lipoproteins. .................................................................................................... 3
Table 2 Primers used in Real Time PCR reactions .............................................................................................. 30
Table 3 List of primers used in PCR reaction to generate proper restriction sites at both ends of the 5’UTR-
apoB15%-3’UTR fragment. ......................................................................................................................... 36
Table 4 Primers used for direct sequencing ......................................................................................................... 37
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List of abbreviations
Acronym Definition ACF apobec-1 complementation factor AMEM alpha modification of eagles medium APO Apolipiprotein ApoB apolipoprotein B APOBEC-1 ApoB mRNA editing catalytic subunit 1 ASH1 achaete-Scute Homologue-1 ATCC american Type Culture Collection B2M beta-2-microglobulin BiP binding immunoglobulin protein C/EBP CCAAT/enhancer binding protein Caco-2 human colonic adenocarcinoma cells CBP20 cap-binding protein 20 CCR4-NOT cDNA
carbon catabolite repression 4- Negative on TATA complementary DNA
CE cholesteryl ester CHX cyclohexamide CM chylomicrons COS CV-1 (simian) in Origin, and carrying the SV40 genetic material CPEB cytoplasmic polyadenylation element binding protein Cy3 Cyanine CYFIP1 cytoplasmic FMR1 interacting protein 1 DAPI 4',6-Diamidino-2-Phenylindole Dcp1a mRNA-decapping enzyme 1A DIC differential interference contrast DNA deoxyribonucleic acid DTT dithiothreitol Edc3 enhancer of mRNA-decapping protein 3 eEFs eukaryotic elongation factors eFG elongation factor G EGP contain eIF4E, eIF4G and Pab1 eIFs eukaryotic initiation factors ER endoplasmic reticulum ERAD endoplasmic reticulum associated protein degradation eRFs eukaryotic release factors FBS fetal bovine serum FMRP fragile X mental retardation 1 protein Foxa2 forkhead box protein A2 G3BP Ras-GAP SH3 domain binding protein GAPDH Glyceraldehyde 3-phosphate dehydrogenase
x
Acronym Definition GFP green fluorescent protein gp78 glycoprotein 78 GTP guanosine triphosphate hDcp1 human decapping protein 1 HDL high density lipoproteins HepG2 human hepatoma cell line HIV-1 human immunodeficiency virus type 1 HMBS hydroxymethyl-bilane synthase HNF hepatocyte nuclear factor HPRT1 Hypoxanthine phosphoribosyltransferase 1 hsps heat shock proteins IDL intermediate density lipoproteins IL-6 interleukin 6 IR insulin receptor IRES internal ribosomal entry site IRS insulin receptor substrate LB lysogeny broth LDL low density lipoprotein LDLR low density lipoprotein receptor Lsm1-7 like sm LUC Luciferase MAPK/ERK mitogen-activated protein kinase/extracellular signal regulated kinase mRNA messenger ribonucleic acid mRNP messenger ribonucleoprotein MTP microsomal triglyceride transfer protein Pab1 poly A binding protein PABP poly A binding protein P-body processing body PBs Processing Bodies PBS phosphate buffered saline PCR polymerase chain reaction PERPP post-ER pre-secretory proteolysis PI3-K phosphatidylinositol 3-kinase PKC protein kinase C PUFAs polyunsaturated fatty acids P-value probability value RNA Ribonucleic acid RRF ribosome recycling factor SGs Stress Granules SH3 Hepatocyte nuclear factor SMAD small ‘mothers against’ decapentaplegic SV40 Simian vacuolating virus 40 TG Triglyceride TGF-β Transforming growth factor beta
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Acronym Definition TNF tumor necrosis factor tRNA transfer RNA UBC ubiquitin C UTR untranslated regions UTRs untranslated regions VLDL very low density lipoprotein YWHAZ tyrosine 3-monooxygenase/tryptophan 5-monooxygenase activation protein
zeta polypeptide β2M Beta-2-microglobulin
1
I. Introduction
1.1 Introduction to Lipoproteins
Lipoproteins are macromolecular complexes composed of proteins and lipids. They
transport insoluble lipids, such as cholesterol, steroid hormones, bile, and triglycerides
between tissues. These sphere-shaped particles contain a core of insoluble cholesteryl ester
and triglyceride encircled by apoproteins (protein component), amphipathic phospholipids,
and cholesterol (1). The interactions of lipoproteins with cell surface receptors are mediated
by the apolipoproteins. Lipoproteins are synthesized by the liver and intestine and based on
their sizes and densities are classified into five major groups: chylomicrons (CM), very low
density lipoproteins (VLDL), intermediate density lipoproteins (IDL), low density
lipoproteins (LDL), and high density lipoproteins (HDL) (Table 1) (2). The focus of this
thesis project was on apolipoprotein B (apoB) which is the major protein component of the
atherogenic LDL particle (2).
1.2 Apolipoprotein B
Apolipoprotein B is a large amphipathic protein that is synthesized by the liver and
the intestine. In humans full-length apolipoprotein B (apoB100) is expressed by the liver and
is the main scaffold protein constituent of cholesterol rich VLDL, and LDL. A truncated
form of apoB containing 48% of the full length (apoB48) is expressed by the small intestine
and is crucial for absorption of dietary fat and chylomicron formation (3). ApoB plays an
essential role in synthesis, secretion and trafficking of lipoproteins (4). Moreover, ApoB100
2
mediates the binding of LDL to LDL receptor (LDLR) and facilitates the plasma clearance of
LDL (5-7).
1.2.1 The Importance of Studying ApoB
Atherosclerosis is the major cause of cardiovascular disease world-wide, and there is
a positive correlation between the augmented levels of LDL and VLDL in the circulation and
the development of coronary heart disease. Accumulation of cholesterol-rich LDL particles
in the intima of arterial vessels is a critical underlying mechanism that occurs during early
stage of plaque formation in atherosclerosis (8). Since apoB is the essential structural protein
component of the atherogenic LDL and VLDL, overproduction of apoB containing
lipoproteins causes dyslipidemia followed by the development of atherosclerosis and
coronary artery heart disease (9). Therefore, studying the regulation of synthesis and
secretion of apoB has been of significant interest for many years.
3
Table 1 Characteristics of Plasma Lipoproteins [Adapted from reference (2)]. TG: Triglyceride; CE: Cholesteryl Ester.
Lipoprotein
Calss
Density (g/mL) Size (nm)
Major lipids Major
Apoproteins
CM <0.93 100-500 Dietary TGs B48, C-II, E
VLDL 0.93-1.006 30-80 Endogenous
TGs
B100, CII, E
IDL 1.006-1.019 25-50 CEs and TGs B100, E
LDL 1.019-1.063 18-28 CEs B100
HDL 1.063-1.210 5-15 CEs A, C-II, E
1.2.2 Structural Features of Human ApoB Gene, mRNA, and
Protein
The human apoB gene is located on chromosome 2 and spans over 43 kb (10;11). It
consists of 29 exons and 28 introns (12), and is transcribed to a 14.121 kb mRNA. The
5’untraslated region (UTR) and the 3’UTR of the mRNA are composed of 128 nucleotides
and 304 nucleotides, respectively (13;14). The 5’UTR region has 76% GC content and is
predicted to be able to make stable secondary structure (15). ApoB is mostly expressed in the
liver and intestine although a low level expression has been detected in the heart (16-18).
Translation of apoB mRNA is very tissue specific: human liver generates a full length form
of apoB called apoB100 that contains 4536 amino acids including a 27 residue signal peptide
(19), whereas human enterocytes produce apoB48. ApoB48 consists of 48% of the full
4
length apoB from the N-terminus (20). This truncated form of apoB is generated due to a
posttranscriptional editing process that converts a glutamine codon at amino acid 2153
(CAA) to a stop codon (UAA) as a result of a deamination reaction at nucleotide 6666
(21;22). The expected molecular mass of full length apoB is 514 kDa while its real molecular
weight is around 550 kD caused by posttranslational modifications such as glycosylation,
phosphorylation, and acylation (19;23-26).
ApoB is capable of recruiting lipids and functions as a lipid transporter vehicle in the
plasma; this is mainly due to its amphipathic polypeptide structure. Despite several attempts,
scientists have not been able to obtain a high resolution apoB structure. This is mostly
because of its hydrophobic makeup and large size (27-30). On the other hand, computational
studies, circular dichroism and infrared spectroscopy propose a pentapartite domain structure
(31). This model predicts a globular βα1 domain at the very N-terminus that extends the first
15-20% of the polypeptide. This domain plays a very important role in lipid acquisition
during the lipid assembly process and is followed by amphipathic β1 domain. This domain
spans over 20%-40% of the length of the protein. α2 domain is next which is an amphipathic
helix, continued by a β2 domain that has the LDLR binding affinity. α3 domain is located at
the very C-terminus end of the polypeptide (Figure1) (3;31;32).
5
A
B
Figure 1 Schematic diagram of the pentapartite structural model of apoB and a three-dimensional consensus model for LDL. A: Illustrates the pentapartite structural model of apoB100: NH2-βα1-β1-α2-β2-α3-COOH composed of alternating α helices and β sheets. B: Left figure demonstrates the anticipated distribution of lipids in an LDL particle. Surface phospholipids are shown in yellow, whereas, core lipid is in red. Green represents phospholipids, and amphipathic β sheets are in blue. Right figure represents the proposed organization of apoB100 on an LDL particle surface. β sheets and α helices are in blue and red, respectively [Adapted from reference (31)].
6
1.2.3 ApoB Protein Function and Importance
The most important function of apoB is to transport lipids and lipid soluble vitamins
from dietary fat and lipid storage tissues to tissues in demand. ApoB100 is also capable of
binding to LDL receptor (LDLR) and mediates endocytosis and plasma clearance of LDL.
Regulation of apoB synthesis is very crucial and both increased and reduced circulating
levels of apoB are known as risk factors for life threatening complications. For example, a
high plasma level of apoB is highly associated with dyslipidemia and increased risk of
cardiovascular disease. On the other hand, having too little apoB, observed in
hypobetalipoproteinemic patients, is linked to hepatic steatosis (33). In addition, apoB
knockdown is embryonic lethal (34;35).
1.2.4 Hepatic Regulation of ApoB Gene Expression
ApoB is constitutively expressed in the liver and shows relatively constant levels of
transcript under most metabolic stimuli (36-41). There is often more apoB protein
synthesized than secreted, signifying the importance of posttranslational degradative
mechanisms in regulating the secretion of this protein (42). Nonetheless, there is evidence
showing that apoB synthesis is regulated at the levels of transcription, translation, co-
translational proteasomal degradation and post-translational proteolysis.
7
1.2.4.1 Transcriptional Regulation of ApoB
Cell culture experiments using promoter reporter constructs revealed many cis-acting
sequences that play an important role in the regulation of apoB gene expression. For
example, the sequence spanning -150 and +124 of apoB promoter moderates gene expression
of the reporter in hepatic and intestinal cell lines (43-45). Some transcription factors that are
abundantly found in the liver such as, hepatic nuclear factor-3, -4 (HNF-3 and HNF-4) have
been found to bind to this region. In a study in HepG2 cells, Human hepatoma cell line, it
was shown that the region between +43 and +53 particularly up-regulated apoB gene
transcription (46;47) with a G nucleotide at +51 playing a crucial role (47). On the other
hand, the sequence extending between +20 and +40 appears to be important for down-
regulation of gene expression (46). In addition, it has been shown that some intronic regions,
such as a 443 bp segment within intron 2 and a 155 bp segment within intron 3 improve
apoB promoter activity in HepG2 and CaCo2, heterogeneous human epithelial colorectal
adenocarcinoma cells, cell lines (43-45).
Comparison of apoB gene expression data obtained from in vivo models to that
obtained from cell culture has shown some differences. For example, studies in transgenic
mice showed that the apoB promoter alone is inadequate to control apoB gene transcription
and that a 443 bp enhancer sequence within the second intron and also a fragment upstream
of the apoB promoter (-899 to -5262) are both essential for a high level of apoB expression
in the liver (48). Interestingly, the cis regulatory elements that modulate transcription of
apoB in the intestine are entirely different from their counterparts in the liver. For instant, the
second intron enhancer and the -899 to -5262 region are not important for human apoB gene
transcription in the liver (49). However, the 54-62 kb region upstream of the apoB gene plays
8
an important role (50). There is a 315 bp sequence located 56 kb upstream of the apoB gene
that enhances apoB gene transcription in the intestine. Some intestinal transcription factors,
such as HNF-4, HNF-3β, and CCAAT/enhancer binding protein (C/EBPβ) interact with this
region (51). Moreover, in a study that involved transient transfection experiments and
transgenic mice models a 485 bp fragment was identified upstream of the 315 bp region that
improves intestinal apoB promoter activity. This region contains an HNF-4/ARP-1 binding
site (52). In addition, another transcription factor, SMAD, that mediates TGF-β signaling
likely binds to this region in CaCo2 cells, heterogeneous human epithelial colorectal
adenocarcinoma cells (53). Finally, a 1031 bp sequence located 1.2 kb downstream of the
315 bp fragment enhanced apoB gene expression in transgenic intestine models but not in
cell culture experiments (49).
As pointed out above, under different metabolic stimuli apoB transcript level remains
realitively constant in cell culture experiments (40). Nevertheless, new data suggests that
under certain circumstances apoB gene transcription and apoB mRNA levels may change.
For example, when HepG2, Human hepatoma cell line, and Huh cells, hepatocyte derived
cellular carcinoma cell line, were incubated with palmitate (a free fatty acid) for 48 hours
apoB mRNA levels were up-regulated (54). Conversely in another study treatment with a
combination of interlukin (IL)-1, IL-6, and tumor necrosis factor alpha (TNFα) reduced apoB
mRNA levels (55). Moreover, TNF β has been shown to modulate apoB transcript level in
HepG2 and CaCo-2 cells (56). These factors activate intracellular signaling cascades that
modify gene expression and affect transcription of many genes including apoB.
9
1.2.4.2 Post Transcriptional Regulation of ApoB
ApoB mRNA undergoes an editing process in the small intestine of all mammals and
in the liver of rats, mice, dogs, and horses (57). Editing is performed by a 27 kDa enzyme
called apoB mRNA editing complex-1 (apobec-1). Apobec-1 binds to a 11 nucleotide long
AU-rich mooring sequence 5 base pair downstream of cytidine 6666 in apoB mRNA.
Apobec-1 then deaminase this cytidine and converts it to uridine. As a result, a Glutamine
codon (CAA) is converted to a stop codon (UAA) and a truncated form of apoB protein
containing 48% of the full length is produced (20;58-62).
1.2.4.3 Translational Regulation of ApoB
There is ample evidence demonstrating that apoB synthesis could be regulated at the
translational level; for example, under some metabolic stimuli such as carbohydrate overload
or a fasting state apoB secretion changed with no change at the mRNA level (63). In another
study, primary hepatocytes of streptozotocin-induced diabetic rats showed a dramatic
reduction of apoB synthesis while mRNA levels remained constant (41). In addition, in vitro
translation of the 14 kb apoB mRNA showed a reduction in translational efficiency by 52.6%
in response to insulin while the mRNA level remained stable (64).
It is well known that apoB synthesis is regulated by insulin (64;65). Although insulin
is believed to promote global mRNA translation in the cell, it has a unique inhibitory effect
on apoB mRNA translation. This unusual response of apoB mRNA to insulin has recently
been linked to its 5’UTR sequence (15;66). Computational analysis predicted the formation
of highly structured secondary hairpin structures at the 5’UTR of apoB mRNA that are
essential for optimal translation of this protein (66). An insulin sensitive protein factor with a
10
molecular weight of 110 kD (p110) has been detected that interacts with the 5’UTR of apoB
mRNA (15). It has also been shown that insulin inhibits the interaction of p110 with the
5’UTR region. This suppression was later shown to be mediated by the phosphotidylinositol
3-kinase (PI3-K)-mTOR pathway (67;68). In constrast, binding of p110 to the 5’UTR is
promoted by the protein kinase C (PKC) activation (68). PKC activation is also associated
with the development of insulin resistant state. Increased apoB mRNA translation could thus
be one contributing factor in apoB overproduction that associates with insulin resistance.
1.2.4.4 Co-Translational Proteasomal Degradation of ApoB
ApoB is synthesized on rough endoplasmic reticulum (ER) membrane bound
ribosomes. Due to the existence of a signal peptide at the N-terminus of apoB, the nascent
polypeptide chain is directly translocated into the ER. With the help of microsomal
triglyceride transfer protein (MTP) newly synthesized apoB associates with lipids co-
translationally and primordial dense lipoprotein particles are formed (69). The availability of
lipids regulates apoB assembly and secretion while it is being translocated into the ER
(9;70). When there are adequate amounts of phospholipids, cholesterol, cholesteryl ester and
triglyceride, apoB is properly assembled into VLDL particles. However, if there is
insufficient supply of lipids, the translation is paused and a large amount of newly
synthesized apoB proteins are targeted for degradation before secretion (32;71). As opposed
to many secretory proteins apoB levels are mainly regulated by means of degradation
(72;73). Insufficient lipid availability targets apoB for ER-associated degradation (ERAD)
mediated by the cytosolic ubiquitin-proteasome apparatus. In this system, misfolded proteins
are tagged by a poly-ubiquitin chain that is recognizable by the ERAD machinery (74).
11
Tagged proteins interact with proteasomes and are targeted for degradation (75). Available
evidence suggests that the C-terminus of apoB is exposed to the cytosol during translocation
into the ER. If needed, this region is ubiquitinated by gp78, an E3 ubiquitin ligase (76). Other
factors that play important roles in recognition, tagging and degradation of the misfolded
apoB protein include cytosolic heat shock proteins 70 and 90 (Hsp70 and Hsp90) (77-79),
and binding immunoglobulin protein (Bip), an ER luminal chaperone (80).
1.2.4.5 Post-Translational non-Proteasomal Degradation of ApoB
In addition to ER- associated proteosomal degradation of apoB which takes place
when lipids are limiting, intracellular degradation of misfolded apoB is also carried out by
post-ER pre-secretory proteolysis (PERPP). Abundant evidence shows that apoB undergoes
non-proteasomal proteolysis once it is safely translocated into the ER (81-85). Degradation
of apoB through PERPP takes place when TG availability is normal. PERPP targets large
aggregates of apoB that are formed as a result of extensive damage by oxidative stress after
translation, perhaps upon its exit from the ER. PERPP prevents secretion of misfolded apoB
that forms late in the secretory pathway, whereas proteosomal degradation would be a
response to co-translational misfolding of apoB.
It has recently been shown that dietary polyunsaturated fatty acids (PUFAs) reduced
VLDL secretion when the lipid supply was abundant (thus the process was not through
ERAD that typically occurs when lipid supply is inadequate). In fact ω-3 polyunsatuarated
fatty acids which are susceptible to oxidative stress owing to their double bounds induce
PERPP (84;85). PUFAs are not the only factors that trigger PERPP of apoB, an acute rise in
insulin both in vivo and in cell culture diminished apoB secretion and VLDL production
12
through a post-ER but non-proteasomal pathway (65;86). This process is probably mediated
by PERPP since insulin sensitivity could be improved by PUFA rich diets (87;88).
Autophagy has been shown to be involved in PERPP. Autophagy typically involves
formation of an autophagosome around damaged material such as, cytosolic proteins,
organelles, organell fragments, and aggregated proteins and happens under normal condition.
Autophagosomes later fuse with lysosomes to form autophagolysosomes in which apoB or
other material would be degraded. Therefore, autophagy prevents oxidized apoB and lipid
peroxides exiting from the cell where they could have toxic consequences. Although
autophagy is a normal process within cells, it can be stimulated under pathological conditions
such as starvation or oxidative stress.
Both proteasome-mediated ERAD and autophagy pathways are capable of degrading
misfolded proteins; however, the proteasome appears to prefer monomeric substrates while
autophagosomes are generally involved in the degradation of protein aggregates. ER stress
could provoke both pathways (89-91).
1.3 Role of Insulin in Metabolic Regulation of ApoB
Insulin is a metabolic hormone produced by pancreatic β-cells. Its main target tissues
are: liver, adipose tissue, and muscle. Insulin is known to inhibit gluconeogenesis, reduce
glycogen hydrolysis in the liver and increase glucose uptake in the adipose tissue and
muscle. It also suppresses TG breakdown in adipose tissue, and increases lipid synthesis in
liver and adipose tissue (3). Hepatic apoB and TG secretions have been shown to be inhibited
by insulin in rat hepatocytes, human hepatocytes and HepG2 cells, Human hepatoma cell
13
line, (65;92-96). Insulin stimulates TG synthesis (96) and does not limit lipid availability,
therefore, the inhibitory effect of insulin on TG secretion could be due to a reduction in
VLDL assembly and decreased intracellular association of apoB with lipids (93;97). Insulin
has also been shown to directly regulate apoB synthesis by reducing its translation and
increasing the degradation of newly synthesized apoB (65). Recent studies also show that
insulin could inhibit the fusion of microsomal lipid droplets with apoB and promote apoB
proteolysis which leads to a reduction in VLDL-apoB secretion (93;97).
1.3.1 Insulin Signaling Pathways Involved in ApoB Biosynthesis
and Regulation
Insulin controls apoB secretion via the insulin receptor (IR), which is a tyrosine
kinase (94;98;99). Upon insulin binding the receptor is activated through
autophosphorylation. Activated IR then phosphorylates insulin receptor substrate (IRS)
protein, and consequently phosphatidylinositol 3-kinase (PI3K) is activated (100). Cell
culture studies showed that acute insulin treatment directly suppressed apoB secretion and
this effect was not reliant on exogenous fatty acid supply (93;101). PI3K activation has been
shown to be involved in this process (86;97;99;102) but this is not via activation of Akt1
pathway (103). In fact, the mitogen-activated protein kinase/extracellular signal regulated
kinase (MAPK/ERK) pathway has been implicated in this process (104).
Insulin also regulates apoB degradation indirectly through mitogen activated protein
(MTP). Insulin inhibits MTP transcription (partly through the MAPK/ERK signaling
pathway) (105) and also through inhibition of forkhead box protein A2 (Foxa2) (106). If
14
apoB is not properly lipidated due to the lack of MTP it undergoes co-translational
degradation.
Chronic hyperinsulinemia, on the other hand, decreases apoB protein degradation
resulting in increased levels of apoB protein and increased VLDL production (107;108).
Reduction in apoB degradation could be due to an increased MTP level that is observed in
insulin resistance states (107;109).
1.3.2 ApoB Overproduction in Insulin Resistance States (Type 2
Diabetes and Obesity)
Insulin resistance occurs when cells become hyposensitive to insulin, predominantly
in liver, muscle, and adipose tissues (100). Insulin stimulated glucose uptake is the most
important pathway that is defective in this state. Insulin receptor activity, PI3-K activity and
insulin stimulated glucose uptake are decreased in the muscle and adipose tissues of obese
humans (110). Once insulin is not able to clear postprandial glucose efficiently, the pancreas
produces more insulin to compensate for the ineffective insulin. This consequently results in
hyperinsulinemia which is a hallmark of insulin resistance state where hepatic
gluconeogenesis and glucose production are also promoted. Besides glucose metabolism,
insulin contributes to lipid metabolism. Chronic hyperinsulinemia increases free fatty acid
flux (reducing the inhibition of lipolysis in adipose tissue) resulting in an increase in VLDL
production and consequent hypertriglyceridemia (111-114). Hyperinsulinemia, thus, leads to
overproduction of apoB containing lipoproteins, metabolic dyslipidemia
(hypertriglyceridemia, high plasma VLDL, low amount of HDL cholesterol (115), small
dense LDL (116), and ultimately the development of cardiovascular disease (117).
15
1.4 The Process of mRNA Translation
Since the focus of this thesis project was to study the translational control of apoB
mRNA, here, we describe the mechanisms of translation and translational regulation in
eukaryotic cells.
The process of decoding messenger RNA (mRNA) into protein is called translation.
Translation involves three key steps: initiation, elongation, and termination. Regulation at
three different levels of translation results in production of various amounts of different
proteins under diverse physiological states (118).
1.4.1 Translation Initiation
The very early event in eukaryotic translation initiation is the formation of a ternary
complex composed of methionine transfer RNA (Met-tRNAiMet), guanosine 5'-triphosphate
(GTP), and eukaryotic initiation factor 2 (eIF2) (118). This primary complex then recruits
other initiation factors, eIF1, eIF1A, eIF3, eIF5, and 40S ribosomal subunit, and together
they form the 43S pre initiation complex (119). In mammalian cells 48S pre-initiation
complex is then formed through the interaction of eIF3 with eIF4G which is in association
with the 5’ end of the mRNA (120). Presence of m7G-cap-binding complex, composed of
eIF4A, eIF4G, eIF4E, is essential for proper loading of the 48S on the 5’ end of the mRNA
(121). After recruitment to the 5’ end of the mRNA, the 48S complex scans the mRNA
towards the 3’ end in order to find the AUG start codon with the help of helicase. Once the
AUG is recognized, the 60S ribosomal subunit joins with the 40S subunit forming the 80S
ribosome, after which elongation starts.
16
1.4.2 Translation Elongation
Polypeptide elongation involves retaining the reading frame, recruiting the correct
aminoacyl tRNAs to the 80S ribosome with the assistance of eEF1A (eukaryotic elongation
factor 1A), forming peptide bounds, and translocating the ribosome which is facilitated by
eEF2 (118).
1.4.3 Translation Termination
Termination is triggered with the recognition of one of the stop codons: UAA, UAG,
or UGA with the help of a protein known as class I release factor (RF) (122;123). In
eukaryotes a unique releasing factor (eRF1) identifies all the three stop codons. eRF1
catalyzes the hydrolysis of the ester bound between the newly synthesized polypeptide and
the tRNA in the P site, and releases the peptide. Class II releasing factor (eRF3 in
eukaryotes) then remove the class 1 RF from the ribosome with the help of GTP hydrolysis
(124). The two ribosomal subunits become dissociated and recycled afterwards with the help
of ribosome recycling factor (RRF) and elongation factor G (eFG) (125).
1.5 Translational Control
Translation can be regulated at all three described levels although most of the
translational control mechanisms known so far function at the level of initiation. A general
regulatory mechanism that shuts down most cap-dependent translations is the binding of the
4E binding protein (4E-BP) family members to eIF4E. Once 4E-BP binds to 4E, 4E-4G
interaction is blocked and translation cannot be initiated (126-128). This way of translation
17
inhibition is independent of the RNA sequence; however, some specific mechanisms can
repress the translation of mRNAs in a manner that is dependent upon the sequence of the
mRNA. In some of these cases, 4E binding proteins are involved; however, these proteins are
recruited to specific mRNAs through their interations with sequence-specific RNA binding
proteins (129-132). In addition, a protein called eIF4E-homologous protein (4E-HP) was
discovered recently that interacts directly with the 5’ cap of the mRNA and does not allow
the binding of the eIF4F complex (133). 4E-HP does not interact with eIF4G and as such
these proteins repress translation by blocking recruitment of the 40S ribosome to the mRNA
(134).
There is another form of translation control that is independent of cap structure and
cap-binding factors. This prevents the binding of 60S subunit to the 40S at AUG codon
(135;136). The exact mechanism of this process is not clear; nonetheless, eIF6 might be
involved (137;138). In addition to translational regulation at the initiation level, there are a few examples
of translational control at the elongation step. It has been shown that elongation factor 2
(eEF2) which is responsible for ribosomal translocation plays an important role in the
suppression of translation (139;140). Once phosphorylated, eEF2 is unable to catalyze
translocation and elongation is repressed (118). When cells start dividing, protein synthesis is
decreased through reduction in elongation rates. Once cells enter G1 they continue rapid
protein synthesis (141), phosphorylation of eEF2 by eEF2 kinase might be involved in this
process (141). In neurons translational control at the elongation level forms the cellular basis
of learning and memory (142).
18
Translation can also be regulated at the termination stage; mRNAs that do not have
an in frame stop codon (nonstop mRNAs) are identified and degraded. In eubacteria, a signal
is sent to a specific tRNA when a ribosome reaches the 3’end of an mRNA lacking proper
stop codon. This tRNA acts as both tRNA and mRNA, and binds to the ribosome. A protein
is synthesized using tmRNA’s open reading frame, and this short newly synthesized peptide
then signals the degradation of this truncated protein (143);(144). In a study involved using
reporter constructs, Akimitsu et al. were able to show that when nonstop mRNAs are present
in mammalian cells, protein production was reduced; however, a decrease in the amount of
the aberrant mRNA or an increase in the degradation of the protein was not observed (145).
Using [14C]-leucine incorporation, different sized short polypeptides were found suggesting
premature ribosome termination (145).
1.6 The RNA Journey in the Cytosol
Cap binding protein 20 (CBP20)-CBP80 complex binds to the mRNA cap while the
mRNA is in the nucleus. Once it enters the cytoplasm this complex is replaced by eukaryotic
translation initiation factor 4E (eIF4E) which is a cytoplasmic cap binding protein. In
somatic cells, newly synthesized mRNAs are assembled into transport RNA granules in the
cytoplasm (146). The RNA binding proteins that present in RNA granules can determine the
fate of mRNAs. For example, recruitment of translation initiation complex followed by
polysomal assembly results in protein synthesis (147), and association of carbon catabolite
repression 4- Negative on TATA (CCR4-NOT1) complex and the consequential
deadenylation leads to mRNA degradation (148). Some mRNAs are destined to be stored for
19
a certain time in the cytoplasm and association of a specific set of RNA binding proteins with
these mRNAs bring about the formation of RNA granules for example, Processing Bodies
(PBs) or Stress Granules (SGs). Depending on future cellular requirements, these stored
mRNAs are targeted for translation or degradation (149). Microtubule motor proteins like
kinesin, dynein, and myosin provide a vehicle to transport RNA granules on actin filaments
within the cytoplasm (150).
1.7 Localization of RNA in the Cytoplasm
Localization of an mRNA in the cytoplasm is one form of controlling gene
expression. This kind of regulation enhances cell’s ability to direct protein synthesis under
certain stimuli without participation of the nucleus (150). Localization of some mRNAs to a
specific cytoplasmic site involves the presence of cis-acting elements within the transcript,
known as zipcodes. Zipcodes are usually located at the 3’UTR although they have been
found at 5’UTR or coding regions in some mRNAs. They vary in length from five
nucleotides to some hundreds. These sequences are often redundant and capable of forming
stem loop secondary structures. Trans-acting RNA binding proteins identify zipcodes and are
involved in localization and translational control of zipcode mRNAs (150).
1.7.1 Cytoplasmic RNA Granules
Cytoplasmic RNA granules have been proposed as the main controllers of post-
transcriptional gene regulation process and epigenetic changes (151). They are classically
divided into 4 groups: germinal granules, stress granules (SGs), processing bodies (PBs), and
neural granules, although other forms of RNA granules have recently been identified. The
20
first is found in germ cells and the latter three exist in somatic cells. They are composed of
various RNAs and proteins. The role of RNA granules is to determine the localization,
stability, and translation of the associated mRNAs (149).
1.7.2 Stress Granules (SGs)
Stress granules are dynamic cytoplasmic foci that form when translation initiation is
impaired under certain conditions such as, decreased translation initiation rates upon stress,
addition of inhibitors of translation initiaton, knockdown of some initiation factors, and
overexpression of translation repressors. Puromycin causes ribosome-mRNA dissociation
and stimulates SG formation, whereas cyclohexamide that stalls ribosome elongation inhibits
SG formation. SGs have mostly been observed in the cytoplasm of plant and mammalian
cells (150), and are mainly composed of mRNAs stalled in the process of translation
initiation. SGs typically contain poly (A)+ ,mRNAs (150), 40S ribosomal subunits, eIF4E,
eIF4G, eIF4A, eIF4B, poly (A) binding protein (PABP), eIF3, and eIF2 (148;156;157;158).
SG composition can vary depending on the cell type and conditions under which they are
formed though. These granules have been predicted to act as a “triage” spot for mRNA
storage, degradation, and translation re-initiation (157).
Similar structures have also been found in yeast cells and are called EGP bodies
(eIF4E, eIF4G, PABP concentration sites). EGP bodies lack eIF3 and small ribosomal
subunits that are present in SGs (148;151-153).
1.7.3 Processing Bodies (PBs)
P bodies are dynamic cytoplasmic RNA-protein structures visible by light
microscopy. They have been observed in vertebrate, invertebrate, yeast, plants and
21
trypanosomes (159). P bodies have at least two functions: first, they host translationally
silenced mRNAs that are capable of re-entering the translation (150;160-162). Second,
mRNAs that are destined for deadenylation and degradation are recruited by P bodies (159).
PBs hold the components of mRNA decay machinery pathway, and are mainly composed of
Dcp1/Dcp2 (decapping enzymes), Dhh1/ RCK/p54, Pat1, Scd6/RAP55, Edc3, the Lsm1-7
complex (activators of decapping), Xrn1 (5’-3’ exonuclease) (149;154), nonsense mediated
decay machinery, miRNA repression system (148;155), staufen, and FMRP (RNA binding
proteins mediating mRNA transport) (150).
1.8 Rationale for the Current Studies
ApoB synthesis is known to be metabolically regulated at multiple levels through
post-transcriptional, co-translational, and post-translational mechanisms (32). Kinetic
analysis of the decay of [3H] uridine-labeled apoB mRNA demonstrated that the half-life of
apoB mRNA was 16 h (Pullinger et al., 1989) in HepG2, Human hepatoma cell line, (40).
ApoB mRNA levels remain stable over a wide variety of conditions that considerably alter
apoB protein levels, suggesting control at the level of translation and posttranslational
mechanisms (Dashti et al., 1989 (163); Pullinger et al., 1989 (40); Adeli et al., 1990 (92);
Theriault et al., 1992 (164); Adeli et al., 1992 (64); Mohammadi et al., 1996 (165); Levy et
al., 1996 (166); Pan et al., 2000 (167)). Early studies demonstrated that insulin-mediated
inhibition of apoB synthesis is at least partially mediated by translational control (Sparks and
Sparks, 1990 (65); Adeli and Theriault, 1992 (64)).
22
A number of other studies have since confirmed translational regulation of apoB
synthesis by insulin and other metabolic regulators (Levy et al., 1996; Pan et al., 2000).
However, the molecular mechanism(s) governing this inhibitory effect at the translational
level have remained largely unknown. Recent studies in our laboratory have revealed
important translational mechanisms of apoB mRNA involving the 5’ untranslated region
(5’UTR). ApoB mRNA has a 5’UTR of 128 nucleotides and a 3’UTR of 304 nucleotides.
Several structural features of apoB mRNA UTR sequences suggest the presence of potential
cis-elements that may interact with putative trans-acting protein factors. A graduate student
in our laboratory recently analyzed the apoB UTR sequences using Mfold, to predict RNA
secondary structure, which revealed elements within the 5' and 3'UTR’s of apoB mRNA with
potential to form secondary structure (66). We assessed the biological activity of the putative
RNA motifs within the UTR sequences and found that 5'UTR motifs are important for
optimal translation of the apoB message. Deletion constructs of the UTR regions of apoB
revealed that the 5'UTR was necessary and sufficient for insulin to inhibit apoB synthesis
(66). Interestingly, although insulin normally activates global translation of cellular protein
synthesis, it has a specific inhibitory effect on apoB mRNA translation. This suggests that
insulin induces a unique signaling cascade that leads to specific inhibition of apoB mRNA
translation despite global translational stimulation. He also demonstrated that insulin may
modulate apoB mRNA translation via changes in the binding of a trans-acting 110-kDa
protein factor to the 5’UTR (15). This putative RNA-binding protein (referred to as p110)
was found to specifically bind the 5’UTR of apoB mRNA, with its binding reduced in the
presence of insulin (15). Interestingly, translational control of apoB mRNA via the 5’UTR
and the binding of the 110 kDa protein factor was found to be regulated by protein kinase C
23
(PKC) signaling cascade (68). Using dual (bicistronic) luciferase constructs, he also
examined the role of internal ribosomal entry (IRES) with respect to the 5'UTR of the apoB
mRNA and found that the apoB 5’UTR possesses IRES activity and basal translational
activity of the apoB mRNA may be partly cap independent (67).
The focus of the current study was to investigate the potential role of cytoplasmic
RNA granules (P bodies) in insulin mediated translational regulation of apoB. P bodies
control the translation of many mRNAs in eukaryotic cells and we postulated that apoB
mRNA is subcellularly compartmentalized in the form of ribonucleoprotein complexes in
RNA granules, which act as a reservoir for translatable mRNA, a process potentially
inhibitable by insulin.
Mature mRNAs in the cytoplasm of eukaryotic cells are associated with a complex
network of ribonucleoprotein particles (mRNPs) (168;169). Early studies of mRNPs showed
the presence of two major proteins (170), a 70-kDa poly(A) binding protein (PABP) (171)
and a 50-kDa protein (p50) responsible for the repressed, nonactive state of mRNAs, such as
globin mRNA within free mRNP particles (172). Recent studies have identified a large
number of other protein components of mRNPs including RNA binding proteins, RNA
helicases, and translational factors (173). Importantly, RNA granules have been identified in
both germ cells and somatic cells that appear to play important roles in mRNA storage,
stability, and translational control. Processing Bodies (PB) are cytoplasmic RNA granules
containing mRNA decay machinery and the RNA-induced silencing complex (149). All
RNA granules contain translationally silenced mRNAs. New evidence suggests a dynamic
interaction between these RNA granules and translationally-active polysomal mRNAs (174),
suggesting that the availability of some mRNAs could be regulated by the rate of release
24
from translationally-silenced mRNAs within RNA granules. It is currently unknown whether
apoB mRNA translation can be controlled by the release of translatable apoB mRNA
transcripts from cytoplasmic stores of mRNPs that are translationally repressed. However,
the long half life of apoB mRNA (16 h) clearly suggests that a significant proportion of the
message may be stored in the cell prior to translation. Interestingly, apoB mRNA polysome
complexes have been reported to show unusual physical properties and exhibit unique
sedimentation behaviors more characteristic of nonpolysomal mRNPs (175) further
suggesting the existence of apoB mRNA in RNA granules.
1.8.1 Objective
The major objective of the present study was to visualize apoB mRNA traffic in
HepG2 cells, human cultured hepatocytes, to test for its localization in cytoplasmic P bodies,
and the potential role of these RNA granules in translational control of the apoB message by
insulin. We further examined the effect of insulin on the distribution of apoB mRNA
between translationally-competent polysomal and non-polysomal pools.
1.8.2 Hypothesis
We postulated that long-term insulin treatment down-regulates apoB mRNA
association with translationally active polysomes and shifts this mRNA pool towards
translationally inactive monosomes. We also hypothesized that apoB mRNA is subcellularly
compartmentalized in the form of ribonucleoprotein complexes in RNA granules/ P bodies,
which act as a reservoir for translatable mRNA, certain stimuli such as insulin may inhibit
25
apoB mRNA translation by reducing the release of translatable mRNA transcripts from
stored mRNPs.
1.8.3 Specific Aims
1. To determine the effect of insulin on the polysomal distribution of apoB mRNA. This
involved investigating whether insulin results in the dissociation of apoB from
translationally active polysomes by performing polysomal profiling and real time
PCR analysis in HepG2.
2. To determine if apoB mRNA is localized within cytoplasmic RNA granules and to
examine if insulin silences apoB mRNA translation by localizing the message into
these granules.
26
II. Materials and Methods
2.1 Polysomal Profiling
2.1.1 Cell Culture
HepG2, Human hepatoma cell line, was obtained from American Type Culture
Collection (ATCC, Manassas, VA), and maintained in complete alpha modification of eagles
medium (AMEM) (Wisent, Inc. Montreal, QC) supplemented with 10% fetal bovine serum
(FBS) (Wisent, Inc. Montreal, QC). Cells were seeded into T-75 flasks, and kept in a Nuaire
incubator at 37°C under 95% air/ 5% CO2. Media was replenished every 3 days, and cells
were sub-cultured on a weekly basis usually after reaching 90% confluency.
2.1.2 Insulin Treatment and Cell lysis
To investigate the effect of insulin on the translational control of apoB mRNA,
HepG2 cells were subjected to short-term and long-term insulin treatments. Cells were sub-
cultured into T75 flasks (3.5×106 cells/ flask) two days prior to treatment. Cells were then
serum starved briefly and treated with 100 nM insulin (Eli Lilly, Canada Inc. Toronto, ON)
for 15 minutes, 1 hour, 4 hours, or 16 hours. Cyclohexamide (CHX) (Sigma Aldrich, St.
Louis, MO) was added to the media at a final concentration of 100 μg/ mL half an hour
before harvesting to stabilize the polysome structures. Media containing CHX was discarded,
and cells were transferred on ice. After three washes (7 mL ice cold 1× PBS +100 μg/ mL
CHX), 750 μL lysis buffer was added to each flask. Lysis buffer contained: 0.015M Tris-HCl
pH 8.0; 0.3 M NaCl ; 0.005 M MgCl2; 1% Triton-X100; 0.0005 M Dithiothreitol (DTT); 1
27
mg/ mL Heparin sodium salt; 0.1 mg/ mL CHX. All lysis buffer components were obtained
from Sigma Aldrich (St. Louis, MO). Cells were scraped off the flask surface with a rubber
scrapper, transferred into a pre-chilled 1.5 ml tube, and kept on ice for 10 minutes to be
lysed. Cell lysates were subjected to 10 minute centrifugation at 12,000 rpm at 4°C.
Supernatant containing the cytoplasmic extract was transferred to a pre-chilled 1.5 mL tube
and kept on ice for subsequent ultracentrifugation on a sucrose gradient.
2.1.3 Sucrose Gradient and Ultracentrifugation
Two mL of the cytoplasmic extracts from insulin treated and non-treated cells were carefully
layered over 12 to 55% linear sucrose (Sigma Aldrich, St. Louis, MO) gradients separately.
Sucrose gradients were made freshly in polysome buffer containing: 0.02 M Tris-HCl pH
8.0; 0.14 M KCl; 0.005 M MgCl2; 0.0005 M DTT; 0.5 mg/ mL heparin sodium salt; 0.1 mg/
mL CHX. Gradients were subjected to ultracentrifugation for 2.5 h at 40,000 rpm at 4°C in a
Beckman SW41 Ti rotor.
The linear sucrose gradient was prepared using a sucrose gradient maker (BioComp
Gradient Mate Model 117, BioComp Instruments, Inc., Canada) (angle: 82.5°, speed: 25,
time: 4 minutes). To verify the linearity of the gradients, 70 μl trypan blue 0.4% from
GIBCO (Invitrogen, Carlsbad, CA) was added to the more concentrated sucrose, and the
gradient was constructed. Twelve 1 ml fractions were then collected from the top;
absorbance at 584 nm was determined for each fraction, and graphed versus sample numbers.
2.1.4 Sucrose Gradient Fractionation
Several fractions from each sucrose gradient were obtained either by a fractionation
device or manually. In the automated process, gradients were fractionated using an ISCO
28
gradient fractionation system equipped with a UA-6 detector following an upward
displacement method. For each fraction, absorbance at 254 nm was continuously monitored
and recorded. Twelve 1 mL tubes were collected from the top. Fractions collected in the first
four tubes assumed to represented light RNPs and free ribosomes based on the shape of the
graphs (http://www.nature.com/protocolexchange/protocols/67 ). This portion corresponds to
the translationally inactive pool of mRNAs whereas lower fractions (numbered 5 to 12)
contained polysomes, representing a source of translationally active mRNAs. When
fractionation was performed manually, four 3 mL fractions were carefully attained from each
gradient using a pipette. The top fraction was rich in light RNPs and free ribosomes.
Acquired fractions were kept at -80°C.
2.1.5 Total RNA Extraction, cDNA Synthesis, and Real-Time
PCR
Total RNA was isolated from each fraction using Trizol (Invitrogen, Carsbad, CA)
and RNeasy minikit (Qiagen, Hilden, Germany) reagents following the manufacturer's
suggested procedure. RNA was then quantified by a NanoDrop Spectrophotometer ND-1000
(Nanodrop Technologies, Wilmington, USA). Two μg of total RNA from each fraction was
reverse transcribed using a High capacity cDNA Reverse transcription kit with RNase
Inhibitor (Applied Biosystems, CA, USA) and random hexamer primers according to the
manufacturer’s protocol.
Real-time PCR analysis was performed on an ABI Prism 7700 (Applied Biosystems,
Carlsbad, CA) machine using Power SYBR Green reagent (Applied Biosystems, Carlsbad,
CA) and apoB primers. In addition to apoB, several other genes including glyceraldehyde 3-
29
phosphate dehydrogenase (GAPDH), β-Actin, β2 microglobulin (β2M), hydroxymethyl-
bilane synthase (HMBS), Hypoxanthine phosphoribosyltransferase 1 (HPRT1), ubiquitin C
(UBC), and tyrosine 3-monooxygenase/tryptophan 5-monooxygenase activation protein zeta
polypeptide (YWHAZ) were quantified and tested as putative internal and/or positive
controls. An internal control gene is a genetic material that its expression does not change
significantly in the presence of experimental variable(s), presence of insulin in our case.
Primers’ names and sequences are listed in Table 2. All primers were synthesized by the
DNA Synthesis Facility, The Centre for Applied Genomics, at the Hospital for Sick
Children. Threshold cycle (Ct) values were obtained in duplicates for each sample. Means of
four experiments in duplicate were assessed for statistical analysis. For each primer set in the
real-time PCR, melting curves were analyzed to ensure that fluorescence signals solely
reflected specific amplicons.
2.1.6 Statistic Analysis
We first looked at the distribution of apoB mRNA in different fractions without
normalization to the internal control genes. For each primer set (either apoB or positive/
internal controls) the Ct value (threshold cycle) of each fraction was subtracted from the
maximum Ct value of four fractions. This was called ΔCt. Since DNA amplification is an
exponential process, and theoretically after each cycle the amount of DNA is doubled to
measure the relative mRNA changes 2ΔCt was calculated. The distribution of mRNA in each
fraction across the entire fractions was then graphed as the percentage of mRNA in each
fraction divided by the total mRNA (the sum of all 4 fractions) (176). Mean and standard
deviations (SD) of data were calculated and shown in graphs.
30
Table 2 Primers used in Real Time PCR reactions
Primer Name Primer Sequence
ApoB-Forw AGACAGCATCTTCGTGTTTCAA
ApoB-Rev ATCATTTAGTTTCAGCCCAGGA
β2 Microglobulin-Forw TGCTGTCTCCATGTTTGATGTATCT
β2 Microglobulin-Rev TCTCTGCTCCCCACCTCTAAGT
β-Actin-Forw ATCTGGCACCACACCTTC
β-Actin-Rev AGCCAGGTCCAGACGCA
YWHAZ-Forw ACTTTTGGTACATTGTGGCTTCAA
YWHAZ-Rev CCGCCAGGACAAACCAGTAT
UBC-Forw ATTTGGGTCGCGGTTCTTG
UBC-Rev TGCCTTGACATTCTCGATGGT
HRTP1-Forw TGACACTGGCAAAACAATGCA
HRTP1-Rev GGTCCTTTTCACCAGCAAGCT
Second, we normalized the apoB mRNA amount to the quantities of internal control
genes (a different internal control gene was selected for each time point). In order to
normalize, the Ct value of the internal control gene in each fraction was subtracted from the
Ct value of the experimental gene (either apoB or the positive control). This was called ΔCt.
Then ΔΔCt values were calculated by subtracting each fraction’s ΔCt from the highest ΔCt
of all fractions. 2ΔΔCt value was determined for each fraction and the percentage of mRNA in
31
each fraction was estimated by dividing the 2ΔΔCt amount from each fraction by the sum of
all four 2ΔΔCt values.
2.2 Cytoplasmic RNA Granules
2.2.1 Preparation of LB Media and LB Plates
25 g of LB Broth Miller powder (EMD Chemicals Inc., North America) was dissolved in 1 L
Millipore-purified water and autoclaved. 37 g of LB Agar Miller (EMD, North America) was
dissolved in 1 L Millipore-purified water, mixed, and autoclaved. When agar cooled down to
about 50°C, ampicilin sodium salt (Sigma Aldrich, St. Louis, MO) was added (0.1 mg/mL
final concentration), and the solution was distributed into Petri dishes (Fisher Scientific
Nepean, ON). After polymerization, plates were kept at 4°C for up to one month.
2.2.2 Plasmids
To study the co-localization of apoB mRNA with P body markers, a well established
method was applied to image exogenous apoB mRNA. In this system, we made use of a
strong interaction between bacteriophage capsid protein MS2 and a sequence specific RNA
stem-loops structure. This method was first developed by Dr. Robert Singer (Department of
Anatomy and Structural Biology, Albert Einstein College of Medicine, Bronx, NY) to image
mRNA molecules in living cells (177). Six different plasmids were used in this project.
First, a modified version of pGL3-Control Vector (Promega corporation, Madison,
WI) was constructed by a previous graduate student in our laboratory (66); the 5.2 kb pGL3-
Control Vector contains the firefly luciferase reporter gene (LUC) under the control of an
32
SV40 promoter. This construct was created by removing the LUC gene and inserting the a
sequence encoding 15% of the full length apoB from N-terminus enclosed by 5’UTR and
3’UTR using Hind III and XbaI restriction sites.
Second, pSL-MS2bs-24X vector received as a gift from Dr. Singer’s laboratory
(www.singerlab.or) (Albert Einstein College of Medicine, Yeshiva University, Bronx NY).
This vector contains a gene sequence that transcribes to 24 tandemly repeated MS2 binding
sites (177). MS2 binding site is an RNA sequence part of a stem-loop structure that is
naturally found in bacteriophage MS2. This RNA structure is recognizable by the
bacteriophage capsid protein called MS2. MS2 protein is capable of binding to MS2 binding
site on the RNA (177).
Third, pMS2-GFP-NLS plasmid which is a mammalian expression vector expressing
MS2 protein fused to GFP under DNA polymerase II promoter. This plasmid was designed
so that the encoded MS2-GFP protein contains a nuclear localization signal (NLS) at its C
terminus. This ensures the localization of free MS2-GFP proteins in the nucleus of
eukaryotic cells (177). pMS2-GFP-NLS plasmid was also generously provided by Dr.
Singer.
The forth plasmid was pCMV-myc-cyto (Invitrogen, Carlsbad, CA). This mammalian
expression vector was used as a mother plasmid to construct our desired plasmid which
contained the 5’URT-apoB15%-3’UTR sequence from the first plasmid followed by the
MS2-24X sequence from the second vector.
The fifth plasmid was EF1a-β-globin mRNA-MS2-bs. We used this plasmid as a
positive control. It has been previously shown that β-globin mRNA localizes into
33
cytoplasmic P bodies (178). This plasmid was purchased from Dr. Nancy Kedersha’s
laboratory (Harvard Medical School, Brigham and Women’s Hospital, Boston, MA).
Finally, pEGFP-N1 plasmid (Clontech, Mountain View, CA). As opposed to pMS2-
GFP-NLS plasmid (third plasmid), this plasmid expresses GFP protein lacking nuclear
localization signal and was used as a control.
2.2.3 Transformation and Plasmid DNA Amplification
Subcloning efficiency DH5α competent cells (Invitrogen, Carlsbad, CA) were used to
amplify all plasmids. 50-100 μL of DH5α aliquots were thawed on wet ice. One μg of
plasmid DNA in water was then taken for transformation and added to the cells. PUC 19
plasmid (Invitrogen, Carlsbad, CA) was used as a positive control for transformation
reaction. Cells were mixed briefly with gentle tabbing on the tube and incubated on ice for
30 minutes. The heat shock reaction was performed by transferring cells to a 42°C water bath
for 30 seconds. Cells were then returned on ice. After 2 minutes, 900 μL of room
temperature LB Broth media without antibiotic was added, mixed, and incubated in a 37°C
incubator shaker (New Brunswick Scientific, Edison, NJ.), shaking at 250 rpm for 1 hour
(enough time for three growth cycles). After incubation, tubes were centrifuged for 5 minutes
at 5000 rpm at room temperature. All but 100 μL of the supernatant was discarded; pellet
was resuspended in the remaining of the supernatant and poured onto an LB-ampicillin agar
plate. A “hockey puck” spreader was used to spread the cells evenly over the plate. Plates
were placed in a 37°C incubator with the agar side up and the lid side down overnight.
Several colonies were picked off the plates using sterile pipettes and were individually
transferred to a 14 ml polypropylene falcon tubes (Becton Dickinson labware, NJ) containing
34
3 mL LB Broth media and ampicilin (0.1 mg/ mL). Bacteria grew at 37°C for 8 hours in a
bacterial incubator shaker. After 8 hours, they were transferred to a new 250 mL LB broth
media containing the antibiotic, and grew overnight at 37°C in the bacterial shaker incubator.
To prepare a stock of bacteria, 850 µL of the growing bacteria was placed in a 1.5 mL
freezing tube (Sarstedt, Montreal, Quebec), and 150 µL of autoclaved glycerol (Sigma
Aldrich, St. Louis, MO) was added, vortexed, and kept on ice for 1 hour. Cells were then
stored at -80°C.
Midiprep plasmid isolation was conducted using the Endotoxin Free Plasmid
Isolation Kit (Qiagen, Hilden, Germany) according to the manufacturer’s instructions.
Plasmids were eluted using purified autoclaved water, and their concentrations were
determined by Nanodrop. The purity of the plasmid DNA was assessed by calculating the
ratio of optical density units at A260/A280, which was mostly around 1.8.
2.2.4 Restriction Enzyme Digestion
All restriction enzymes were purchased from New England Biolabs, Inc. (Ipswich,
MA). One unit of each enzyme was used to digest 1 μg of DNA for 3 hours at 37°C
according to the manufacturer’s protocols.
2.2.5 Gel extraction
Digested products were run on a 0.8% agarose gel (Invitrogen Life Technologies,
Grand Island, NY) at 50 V. Desired DNA bands were then cut and gel purified using
QIAquick Gel Extraction Kit (Qiagen, Hilden, Germany) according to the manufacturer’s
protocol.
35
2.2.6 Ligation Reaction
Purified digested plasmids and insert fragments were mixed and incubated at 56°C
for 10 minutes to anneal. T4 DNA ligase reaction mixture (Invitrogen, Carlsbad, CA) was
then prepared according to the manufacturer’s protocol and added. Ligation reaction was
performed for 4 hours at 25οC and for some plasmids continued for another 48 hours at 16ο
C. T4 DNA Ligase enzyme was heat inactivated for 10 minutes at 65ο C. Half of the total
reaction (5 μL) was used to transform DH5α competent cells.
2.2.7 Construction of pCMV-MS2bs-24X-cyto Plasmid
The gene transcribing 24 tandem repeats of MS2bs from pSL-MS2bs-24X vector was
inserted into pCMV-myc-cyto plasmid using NcoI and NotI restriction enzymes and T4
DNA ligase (New England Biolabs).
2.2.8 Construction of pCMV-5’URT-apoB15%-3’UTR-MS2-24X-
cyto Chimeric Plasmid
To construct this plasmid, the 5’UTR-apoB15%-3’UTR sequence was obtained from
the modified pGL3 vector. In order to create proper restriction sites, 18 mer PCR primers
were designed (Table 3) to create an ApaI restriction site before the 5’UTR end and a BamHI
site after the 3’UTR end. A clamp of 3 random bases was added at both extreme ends of the
oligonucleotide primers to provide a sufficient grip for the restriction enzyme. PfuUltra II
fusion HS DNA polymerase enzyme (Stratagene, La Jolla, CA) was used to amplify the
sequence according to the manufacturer’s protocol (95°C, 2 minutes; 40 cycles (95°C 25
36
seconds; 62°C 25 seconds; 72°C 3 minutes); 72°C 15 minutes. This fragment was then
inserted in place on pCMV-MS2bs-24X-cyto plasmid.
Table 3 List of primers used in PCR reaction to generate proper restriction sites at both ends of the 5’UTR-apoB15%-3’UTR fragment. Primer Name Primer Sequence
5’ApaI-Forw AGAGGGCCCTTATTCCCACCGGGACCT
BamH13’-Rev AGAGGATCCCCGCCCCGACTCTAGATA
2.2.9 Direct DNA Sequencing
Direct DNA sequencing method was used to validate the sequence of constructed
plasmids (DNA sequencing facility, The Hospital for Sick Children, Toronto, ON)
(http://www.tcag.ca/dnaSequencingSynthesis.html). Table 4 represent a list of primers that
have been designed and used to sequence different constructs.
2.2.10 Transient Transfection Experiments
HepG2 cells were transiently co-transfected with 5.5 µg of pMS2-GFP-SV40 NLS
plasmid and 14.5 µg of either pCMV-5’URT-apoB15%-3’UTR-MS2-24X-cyto (reporter
plasmid) or EF1a-β-globin mRNA-MS2bs plasmid (control) using Lipofectamine 2000
reagent (Invitrogen, Carlsbad, CA) and reverse transfection method according to the
manufacturer’s recommendations; at about 50%- 60% confluency in a T75 flask HepG2 cells
were trypsinized, and mixed with the transfection complexes. Transfected HepG2 cells were
seeded on collagen-coated cover slips into six-well plates (8×105 cells/ well). Cells were
37
incubated at 37°C for 5 hours. Lipofectamin reagent was then replaced with fresh AMEM
containing 10% FBS. Cells were kept at 37°C incubator for about 16 hours prior to insulin
treatment.
Table 4 Primers used for direct sequencing
Construct Primer
Name
Primer Sequence
pGL-5’UTR-apoB15%-3’UTR pGL3-5’end CTCGGCCTCTGAGCTATTCC
pGL-5’UTR-apoB15%-3’UTR pGL3-3’end TCCCCCTGAACCTGAAACAT
pCMV-MS2-24X-cyto CMV-fwd CGCAAATGGGCGGTAGGCGTG
pCMV-MS2-24X-cyto BGH-rev TAGAAGGCACAGTCGAGG
pCMV-5’URT-apoB15%-
3’UTR-MS2-24X-cyto
R-final CAACACTTGCTTGGCTTCTTC
pCMV-5’URT-apoB15%-
3’UTR-MS2-24X-cyto
L-final AGCCTCAGCCAAAATAGAAGG
2.2.11 Preparation of Collagen Coated plates
To make 100 collagen coated cover slips in a 6 well plate (100 μg/ well), 10 mg type
I collagen (MP Biomedicals, Solon, OH) was weighed and dissolved in 100 mL 0.05 M HCl
(0.1 mg/ mL collagen solution). The solution was then filtered using 0.45 μm filters (Sarstedt
Inc., Montreal, Quebec). One autoclaved cover slip (VWR, Mississauga, ON) was inserted
38
into each well and 1 mL of the solution was layerd on top. Collagen surface was air dried in a
cell culture hood overnight. Wells were washed twice with autoclaved H2O. Plates were air
dried in the hood, repacked, and stored at 4°C for up to 3 months.
2.2.12 GFP Expression and Insulin Treatment
Sixteen hours post transfection, GFP signal was detected under an Epifluorescence
Microscope (Zeis). At this time, cells were serum starved for half an hour and treated with
100 nM insulin (Eli Lilly, Canada Inc. Toronto, ON) for 1 h, 4 h, 8 h, or 16 h.
2.2.13 Immunostaining Experiments
To detect P bodies in HepG2 cells, human hepatoma cell line, that express exogenous
GFP, and to investigate the co-localization of P bodies with apoB mRNA, after proper
insulin treatments cells were fixed and stained for human enhancer of decapping large
subunit (hedls), a protein marker of P bodies. Cells were rinsed twice with PBS and fixed
immediately using 4% paraformaldehyde in 1XPBS solution for 15 minutes.
Paraformaldehyde was then aspirated and -20° C methanol was added for 10 minutes. Cells
were washed with 1XPBS, and blocked in 1X PBS containing 5% fetal bovine serum (FBS)
and 0.02% sodium azide (Sigma Aldrich, St. Louis, MO) for 1 hour. Mouse-anti-human GE-
1/hedls antibody (P70 S60 kinase α) (Santacruz Biotechnology, Inc., Santa Cruz, CA) was
diluted 1:1000 in the blocking solution and added to the fixed cells for 1 hour. After two
washes with 1XPBS (10 minutes each) Donkey-anti-mouse Rhodamine Red secondary
antibody (Jackson ImmunoResearch Laboratories, Inc., West Grove, PA) was diluted 1000
times in the blocking solution and added for one hour. Three washes with 1X PBS were
performed (10 minutes each), and cells were incubated with DAPI (4′6 -diamidino-2-
39
phenylindole·2HCl) (1 mg/ mL stock, 1:1000 dilution) (Santa Cruz Biotechnology, Inc.) for
15 minutes to stain the nucleus. After 3 washes with 1XPBS (10 minutes each) cells were
mounted in Dako flurescent mounting media (Dako North America, Inc., Carpinteria, CA),
slides were protected from light and kept at 4°C (179). All staining steps were performed on
a gentle shaker at room temperature.
2.2.14 Confocal Microscopy Imaging
Images were acquired from fixed cells using spinning disk confocal microscopy
(Zeiss) and velocity software. DAPI confocal, GFP confocal and Cy3 confocal laser channels
were used to detect the nucleus, GFP signal, and P bodies, respectively, with sensitivities
around 200 and exposures not longer that 1 second. Images were then deconvolved to
remove the out of focus light (90% similarity between the deconvolved image and the
original; 20 rounds of deconvolution).
2.2.15 Using hDCP1a, a Second Primary Antibody, to Detect P
bodies
To confirm the detection of P bodies another primary antibody, hDCP1a (human
decapping protein 1) (Santacruz Biotechnology, Inc., Santa Cruz, CA), was utilized in the
imaging experiments. This antibody targets, Dcp1a, another protein component of P bodies
(179).
2.2.16 Puromycin Treatment
Puromycin is known to disrupt the translational machinery and increase the size and
number of P bodies (180). To further validate the detection of P bodies, HepG2 cells were
40
treated with 1 mM puromycin dihydrochloride (Sigma Aldrich, St. Louis, MO) for 30
minutes to disrupt the translational machinery and promote P body formation. Cells were
then fixed and stained for P bodies.
2.2.17 Statistical Analysis of Imaging Data
Pearson correlation coefficient is a measure of the correlation (linear dependence)
between two variables X and Y, giving a value between 0 and 1. It is widely used as a
measure of the strength of linear dependence between two variables. We used this measure to
evaluate the strength of the co-localization of P bodies and apoB mRNA at different time
points. Velocity software version 5 was used to quantify the co-localization data and the
significance of the findings was validated by the Pearson’s correlation coefficient. Mean and
standard deviations (SD) of data were calculated and shown in graphs.
41
III. Results
3.1 Polysome Profiling
3.1.1 Results of Constructing a Linear Sucrose Gradient
In order to assess the insulin effect on the association of apoB mRNA with polysomes
cytoplasmic extracts of HepG2 cells were first subjected to sucrose gradient sedimentation.
To verify the linearity of the sucrose gradient Trypan Blue was premixed with the heavier
sucrose (55%) and the gradient was generated. The gradient was then fractionated and the
distribution of Trypan Blue was assessed by spectrophotometry. Absorbances of Trypan Blue
at 584 nm indicated a constant decrease in the concentration of Trypan Blur towards the top
of the gradient (Figure 2).
42
Figure 2 Synthesis of a linear sucrose gradient.A continuous sucrose gradient was generated using a 55% sucrose solution containing Trypan Blue and 12% sucrose solution lacking Trypan Blue. Eleven 1mL fractions were collected and spectrophotometry analysis was performed to verify the linearity of the sucrose gradient.
3.1.2 Effect of Insulin on apoB mRNA Translation
In order to investigate the effect of insulin on the translation of apoB mRNA,
polysomal and non polysomal pools were obtained using the sucrose fractionation method.
Real Time PCR was conducted to analyse the relative percentage of apoB mRNA in each
pool. HepG2 cells subjected to short-term and long-term insulin treatments were lysed and
fractionated on continuous sucrose gradients (12%-55%). Four 3 mL fractions were obtained
from each gradient. While the fraction on top contained monosomes and ribosomal subunits,
polysomes were found in the bottom layers. The forth fraction contained the heaviest
polysomes. Total RNA was then extracted from each fraction and subjected to Real Time
PCR analysis. The relative percentage of apoB mRNA in each fraction was calculated and
graphed. Data from four independent experiments suggested that very short term insulin
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treatments (15 minutes and 1 hour) increased apoB mRNA association with polysomes
(Figure 3), while long term insulin exposure (4 hours and 16 hours) showed an inhibitory
effect on the translation of apoB and shifted the mRNA towards the lighter polysomes and
monosome rich fractions (Figure 4).
44
Figure 3 Effect of short-term insulin treatment on apoB mRNA association with polysomes. HepG2 cells were treated with insulin for 15 minutes (on top) and 1 hour (on bottom). Cytoplasmic extracts were then subjected to density fractionation at 40000 rpm for 2.5 hours, and Real Time PCR was performed to measure the relative percentage of apoB mRNA in each fraction. (Fraction 1 was the lightest top fraction and fraction 4 contained the heaviest polysomes at the bottom of the gradient. Data shown is mean +/- SD. *= p< 0.05
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45
Figure 4 Effect of long-term insulin treatment on apoB mRNA association with polysomes. HepG2 cells were treated with insulin for 4 hours (on top) and 16 hours (on bottom). Cytoplasmic extracts were then subjected to density fractionation at 40000 rpm for 2.5 hours, and Real Time PCR was performed to measure the relative percentage of apoB mRNA in each fraction. (Fraction 1 was the lightest top fraction and fraction 4 contained the heaviest polysomes at the bottom of the gradient. Data shown is mean +/- SD. *= p< 0.05
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46
3.1.3 Under conditions that inhibit apoB mRNA polysomal
association, insulin acutely stimulates global translation
As a control, we also examined the insulin effect on global translation in HepG2 cells
by assaying the absorbance of fractions at 254 nm. As shown in Figure 5, short term insulin
treatment (15 minutes) promoted global translation, as depicted by the rightward shift of the
polysomal profile (indicating the formation of heavy polysomes), similar to its effect on
apoB mRNA. However, following 4 hours of insulin treatment, although apoB mRNA
association with polysomes was inhibited, global translation was noticeably increased as
indicated by the presence of heavy polysomes. After 16 hours, the effect of insulin on global
translation was lost, while its inhibition of apoB mRNA translation persisted (Figure 5).
47
Figure 5 Insulin acutely stimulates global mRNA translation in HepG2 cells. In order to assess the general effect of insulin on the cellular protein translation, HepG2 cells were serum starved briefly and insulin treated for 15 minutes, 1 h, 4 h, and 16 hours. Cytoplasmic extracts were then analyzed using polysome gradients. Gradients were then fractionated using the upward displacement method and the absorbance at 254 nm was continuously monitoried.
3.1.4 Effect of Insulin on Beta-2-microglobulin mRNA
Distribution (as a control)
We were able to show that long-term insulin treatments (4 hour and 16 hour)
decreased the association of apoB mRNA with polysomes and therefore has a negative effect
Control
48
on the translation of this mRNA. In order to confirm that this is not a universal response to
insulin, we examined the effect of long term insulin exposure on beta-2-microglobulin
mRNA translation, and observed an increased association of this mRNA with the heaviest
polysomal fractions 16 hours post insulin treatment (Figure 6).
Figure 6 Effect of long-term insulin treatment on Beta-2-microglobulin mRNA (positive control) association with polysomes. HepG2 cells were insulin treated for 16 hours and the cytoplasmic extracts were analyzed using polysome gradients. Relative percentage of Beta-2-microglobulin mRNA in each fraction was then measured by Real Time PCR. (Fraction 1 was the lightest top fraction and fraction 4 contained the heaviest polysomes at the bottom of the gradient. Data shown is mean +/- SD. *= p< 0.05
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3.1.5 Determination of ApoB mRNA Abundance and
Optimization of Real Time PCR Experiments using Internal
Controls
Usually all Real Time PCR data are normalized to one or more internal control
gene(s). The mRNA level(s) of internal control gene(s) stay(s) constant under the
experimental procedure. In order to normalize apoB mRNA to an internal control gene under
the insulin stimuli, several genes that are commonly used as endogenous controls in Real
Time PCR analysis were used. For example, GAPDH (glyceraldehyde 3-phosphate
dehydrogenase), 18SrRNA gene, YWHAZ (tyrosine 3-monooxygenase/tryptophan 5-
monooxygenase activation protein zeta polypeptide), B2M (Beta-2-microglobulin), HMBS
(Hydroxymethyl-bilane synthase), HPRT1 (Hypoxanthine phosphoribosyl-transferase1),
UBC (Ubiquitin C). This was a challenging step because insulin augments the translation of
most mRNAs in HepG2 cells. Therefore, different internal control genes were found for
different time points; for example, HMBS mRNA remained constant at 15 minutes and 1
hour post insulin treatment; however, at longer insulin exposure times, HMBS mRNA level
altered significantly compare to the control. Although B2M mRNA level stayed steady 4
hours after insulin treatment, it changed significantly at other times. Finally, UBC mRNA
level remained stable only at 16 hours after insulin treatment (Figure 7).
50
A
B
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51
C
D
Figure 7 Validation of potential internal control genes. HepG2 cells were insulin treated for 15 minutes (A), 1 hour (B), 4hours (C), and 16 hours (D). Cytoplasmic extracts were then analyzed using polysome gradients. Relative percentage of HMBS mRNA (A and B), B2M (C), and UBC (D) in each fraction was then measured by Real Time PCR. (Fraction 1 was the lightest top fraction and fraction 4 contained the heaviest polysomes at the bottom of the gradient. Data shown is mean +/- SD.
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52
3.1.6 Effect of Acute Insulin Treatments on ApoB mRNA
Translation (Data Normalized to Internal Control Gene)
The threshold cycle numbers obtained from Real Time PCR experiments in section
3.1.2 correspond to relative percentage of apoB mRNA in each fraction was then normalized
to the relative amounts of HMBS mRNAs. Results from four independent experiments were
analyzed and presented in Figure 8. Fifteen minutes after insulin treatment, similar to
unnormalized data, a significant amount of apoB mRNA bound to the heaviest polysome
fraction was observed which indicates an increase in apoB mRNA translation. Conversely, 1
hour insulin treatment shifted this mRNA towards the lighter fractions.
53
Figure 8 Effect of short-term insulin treatment on apoB mRNA association with polysomes (data normalized to internal control genes). HepG2 cells were treated with insulin for 15 minutes (on top) and 1 hour (on bottom). Cytoplasmic extracts were then analyzed using polysome gradients and Real Time PCR was performed to measure the relative percentage of apoB mRNA in each fraction. Relative percentages of apoB mRNA were normalized to HMBS mRNA amount (Fraction 1 was the lightest top fraction and fraction 4 contained the heaviest polysomes at the bottom of the gradient). Data shown is mean +/- SD. *= p< 0.05
0
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to H
MBS
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54
3.1.7 Effect of Chronic Insulin Treatments on ApoB mRNA
Translation (Data Normalized to Internal Control Genes)
As was explained in section 3.1.5 the amounts of B2M and UBC mRNAs remained
constant in the presence and absence of insulin 4h and 16h post treatment, respectively.
ApoB mRNA levels were normalized to these genes and the average results of four
independent experiments were analyzed (Figure 9). 4 hours post insulin treatment apoB
mRNA made a significant shift from translationally active mode to translationally inactive
form. Likewise more apoB mRNA was associated with lighter polysomes and monosome
rich fractions 16 hour post insulin treatment compared to the control.
55
Figure 9 Effect of long-term insulin treatment on apoB mRNA association with polysomes (data normalized to internal control genes). HepG2 cells were treated with insulin for 4 hours (on top) and 16 hour (on bottom). Cytoplasmic extracts were then analyzed using polysome gradients and Real Time PCR was performed to measure the relative percentage of apoB mRNA in each fraction. Relative percentages of apoB mRNA were normalized to B2M (top) and UBC (bottom) mRNA amounts (Fraction 1 was the lightest top fraction and fraction 4 contained the heaviest polysomes at the bottom of the gradient). Data shown is mean +/- SD. *= p< 0.05
0
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56
3.1.8 Effect of Insulin on Polysomal Distribution of Beta-2-
microglobulin mRNA
We were able to show that long-term insulin treatments shifted apoB mRNA towards
lighter polysomes or monosomal fractions. In order to confirm that this is not a global effect
of insulin on translation, the association of B2M mRNA with polysomes was evaluated in the
presence of insulin. Relative percentage of B2M mRNA level in each fraction was
normalized to UBC mRNA. UBC mRNA level remained constant in each fraction in the
presence and absence of insulin (Figure 10). B2M mRNA showed a significantly higher
association with the heaviest polysomal fraction in the presence of insulin compared to the
serum starved sample.
Figure 10 Effect of long-term insulin treatment on B2M mRNA (positive control) association with polysomes (Data normalized to internal control genes). HepG2 cells were treated with insulin for 16 hours. Cytoplasmic extracts were then analyzed using polysome gradients and Real Time PCR was performed to measure the relative percentage of apoB mRNA in each fraction. Relative percentages of apoB mRNA were normalized to UBC mRNA amount (Fraction 1 was the lightest top fraction and fraction 4 contained the heaviest polysomes at the bottom of the gradient). Data shown is mean +/- SD. *= p< 0.05
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3.2 Translational Control of ApoB mRNA: Role of
Cytoplasmic Ribonucleoproteins
The role of P bodies was examined by applying a recently-established method that
has been successfully employed to visualize exogenously expressed mRNAs in mammalian
cells. We made use of a strong interaction between bacteriophage capsid MS2 protein and a
sequence specific RNA stem-loops structure. In this technique a fluorescent protein, for
example, GPF is fused to RNA phage MS2 coat protein with a nuclear localization signal at
the C terminus. The RNA of interest is constructed to contain tandem repeats of the specific
phage RNA sequence that binds MS2 coat protein. The strong interaction between the
bacteriophage capsid protein MS2 and the sequence specific RNA stem-loops structure helps
visualize the RNA
In order to visualize apoB mRNA with PBs, we constructed a chimeric plasmid
containing 15% of apoB gene with 5’ and 3’UTRs at both ends followed by 24 tandem
repeats of MS2 binding sites. HepG2 cells were then transiently co-transfected with this
chimeric plasmid and a plasmid expressing MS2 protein fused to GFP.
3.2.1 Construction of pCMV-MS2bs-24X-cyto Plasmid
In order to construct pCMV-MS2bs-24X-cyto plasmid, eukaryotic expression vector
pCMV-myc-cyto (Figure 11 A) and pSL-MS2bs-24X plasmid containing 24 tandem repeats
of MS2 binding sites (Figure 11 C) were double digested with NcoI and NotI enzymes. A
sequence containing 24 repeats of MS2 binding site (1482 bps) was then gel purified and
inserted into pCMV-myc-cyto plasmid (4855 bps) (Figure 11 B and 11 D). The sequence of
58
this newly synthesized plasmid named pCMV-MS2bs-24X-cyto was validated by direct
DNA sequencing.
59
C D
Figure 11 Construction of pCMV-MS2bs-24X-cyto plasmid. Both pCMV-myc-cyto (A) and pSL-MS2bs-24X vectors (C) were double digested with NcoI and NotI restriction enzymes (B and D). 24 repeats of MS2 binding site was then inserted into pCMV-myc-cyto vector with the help of T4 DNA ligase.
1Kb
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60
3.2.2 Construction of pCMV-5’UTR-ApoB15%-3’UTR-MS2bs-
24X-cyto Chimeric Plasmid
A graduate student in our laboratory had previously inserted a fragment of DNA
containing 5’untranslated region of apoB gene followed by a sequence encoding 15% of the
full length apoB from N-terminus and 3’untranslated region of apoB in a pGL3-Control
Vector (66) (Figure 12 A). In order to create pCMV-5’UTR-ApoB15%-3’UTR-MS2bs-24X-
cyto chimeric plasmid first PCR primers were designed to create new restriction sites at both
ends of the sequence (15% of the full length apoB enclosed by its UTRs). This fragment was
amplified (Figure 12 B) and ApaI and BamH1 restriction sites were added to the 5’ and 3’
end of the fragment, respectively. ApaI and BamH1 restriction enzymes were used to clone
this fragment into the previously synthesized pCMV-MS2bs-24X-cyto plasmid upstream of
the MS2 gene. The sequence of this plasmid was verified by direct DNA sequencing.
61
A
B
Figure 12 Construction of pCMV-5’UTR-ApoB15%-3’UTR-MS2bs-24X-cyto plasmid. A sequence containing 15% of the full length apoB enclosed by its UTRs was amplified (B) from a modified version of pGL3-Control Vector template (A) and positioned upstream of the MS2 gene using Apa1 and BamH1 restriction sites created by PCR (B).
5’UTR
3’UTR ApoB15%
2546 bps
62
3.2.3 Detection of P Bodies (PBs) in HepG2 Cells and the
Influence of Puromycin on PB formation
We used mouse-anti-human GE-1/hedls primary antibody to detect P bodies in
HepG2 cells. This antibody identifies a major protein component of P bodies called human
enhancer of decapping larger subunit. Donkey-anti-mouse Rhodamine Red conjugated
antibody was used to visualize the signal (Figure 13A). Immunostaining with GE-1/hedls
revealed ~60 foci per cell. A similar pattern was observed using an antibody against a second
P body protein, hDcp1a (human decapping protein 1) (Figure 13B). To further validate that
these are in fact P bodies, cells were subjected to 1 mM puromycin for 30 minutes (Figure
13C). Puromycin is known to promote the formation of P bodies by disrupting the
translational machinery. Results from 8 different slides indicated that puromycin
significantly increased P body count and size by 99% and 25%, respectively, (Figure 14) (P
< 0.005)
63
Figure 13 Detection of P bodies in the cytoplasm of HepG2 cells. HepG2 cells were fixed and immunostained for two protein components of P bodies, hedls (A), and hDcp1a (B), shown in red. DAPI was used to stain the nucleus, shown in blue. Puromycin was used to further verify the detection of P bodies (C), HepG2 cells were treated with 1 mM puromycin for half an hour, fixed and immunostained for hDCP1 (C). DIC (differential interference contrast) images of the same fields are represented on the right hand panel.
64
A
B
Figure 14 Effect of puromycin on P body formation. HepG2 cells were exposed to 1 mM puromycin for half an hour, then fixed and immunostained for hDCP1, one of the protein components of P bodies. The average size and number of P bodies were determined. Data shown is mean +/- SD. *= p < 0.005.
0
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65
3.2.4 Employing the MS2 Tagging System to Visualize ApoB
mRNA in HepG2 Cells
To use the MS2 tagging system to visualize apoB mRNA HepG2 cells were
transiently co-transfected with two plasmids (Figure 15): First, a chimeric DNA construct
that would transcribed to a reporter mRNA containing 15% of the full length apoB linked to
its UTRs (5’UTR-apoB15%-3’UTR) which was fused to MS2 binding site. The MS2 binding
site included 24 tandem repeats of 19 nucleotide RNA stem loop structures. This RNA is
recognizable by phage capsid MS2 protein which was encoded by the second plasmid. The
second plasmid made a MS2 protein fused to GFP with a nuclear localization signal at the C-
terminus end. Upon expression the GFP-MS2 coat protein binds the stem loop structure as a
dimer (183), This allows the detection of a specific RNA that is bound to the stem loop. The
presence of nuclear localization signal at the 3’ end of the MS2 protein helped the
elimination of false positive signals in the cytoplasm by sequestering any unbound MS2-GFP
in the nucleus.
66
Pol II promoter MS2 eGFP SV40 NLS
MS2-GFP Protein
PCMV promoter 5 ’UTR-apoB15-3’UTR PolyA signal
Repeats of MS2 binding sites
Reporter mRNA
Figure 15 Construction map of MS2-GFP and apoB mRNA reporter plasmids. A system composed of two plasmids enabled us to detect apoB mRNA in HepG2 cells. In this system one plasmid encoded a MS2 binding protein fused to GFP (top) and the other one was transcribed to a reporter mRNA containing part of apoB mRNA sequence followed by MS2 binding sites (bottom).
3.2.5 Transfection of HepG2 Cells with pMS2-GFP-SV40 NLS
Plasmid
In order to ensure that the green florescent in the cytoplasm only reflects the MS2-
GFP spicies that are associated with the reporter mRNAs via MS2 recognition sites and not
67
the free MS2 proteins, a nuclear localization signal (NLS) was positioned at the 3’ terminus
of this plasmid. HepG2 cells were transiently transfected with pMS2-GFP-SV40 NLS
plasmid. This plasmid encoded a green fluorescent protein that upon expression concentrated
in the nucleus due to the presence of a nuclear localization signal (Figure 16A).
As a control experiment, HepG2 cells were transfected with pEGFP-N1 plasmid that
expressed green florescent protein lacking the nuclear localization signal. In this case all GFP
signal was detected in the cytoplasm (Figure 16B).
68
A
B
Figure 16 Expression of pMS2-GFP-SV40 NLS vector and the effect of NLS. HepG2 cells were transfected with either pMS2-GFP-SV40 NLS (A) or pEGFP-N1 plasmids (B). 16 hours post transfection cells were fixed and immunostained for Dapi and imaged. In the presence of nuclear localization signal the GFP signal was sequestered in the nucleus (A), whereas, in the absence of a nuclear localization signal the GFP signal was dispersed in the cytoplasm (B).
69
3.2.6 Insulin Induces Co-localization of ApoB mRNA with P
Bodies
We transiently co-transfected HepG2 cells with pCMV-5’URT-ApoB15%-3’UTR-
MS2bs-24X-cyto and MS2-GFP-NLS constructs. Transfected cells were then treated with
insulin at different time points, fixed and immunostained for P body marker, GE-1/hedls.
Upon expression, MS2 binding proteins recognized their binding sites on the reporter
mRNAs as illustrated in Figure 16. Due to the presence of a nuclear localization signal
downstream of the MS2 protein any unbound MS2-GFP protein was sequestered in the
nucleus. We used spinning disk confocal microscopy to image the co-localization of apoB
mRNA with P bodies. Long-term insulin treatments (4 h, 8 h, and 16 h) (Figure 17)
significantly increased the co-localization of apoB mRNA with P bodies. On the other hand,
acute insulin treatment (1 h) (Figure 18) did not have any significant effect on the
localization of apoB mRNA with P bodies.
70
Figure 17 Visualizing apoB mRNA traffic in HepG2 Cells: Long-term exposure to insulin induced co-localization of apoB mRNA with P bodies. HepG2 cells were transiently contransfected with pCMV-5’URT-ApoB15%-3’UTR-MS2bs-24X-cyto and MS2-GFP-NLS plasmids. 16 hours post transfection cells were serum sratved briefly and treated with insulin for 4 h (A), 8 h (B), and 16 h (C). Green represents apoB mRNA, P bodies are in red and DAPI was used to stain the nucleus (blue). Please see Appendix, figures 23-25 for full size confocal images.
71
Figure 18 Visualizing apoB mRNA traffic in HepG2 Cells: Short term exposure to insulin did not induce co-localization of apoB mRNA with P bodies. HepG2 cells were transiently contransfected with pCMV-5’URT-ApoB15%-3’UTR-MS2bs-24X-cyto and MS2-GFP-NLS plasmids. 16 hours post transfection cells were serum sratved briefly (B) and treated with insulin for 1 h (A). Cells were then fixed and immunostained for hedls, one of the main protein components of P Bodies. Green represents apoB mRNA, P bodies are in red and DAPI was used to stain the nucleus (blue). Please see Appendix, figures 26-27 for full size confocal images.
3.2.7 Insulin does not affect the Co-localization of Beta-Globin
mRNA with P Bodies
We were able to show that co-localization of apoB mRNA with P bodies increased at
4 hours, 8 hours and 16 hours post insulin treatment. To verify this is not the case for all
mRNAs we tested the influence of insulin on the co-localization of Beta-globin mRNA with
P bodies.
72
Beta-globin mRNA has already been shown to localize in P bodies (178). A plasmid
containing beta-globin mRNA fused to MS2 binding site and the MS2-GFP-NLS construct
were co-expressed in HepG2 cells. As shown in Figure 19, although there was marked co-
localization of beta-globin mRNA with the P body marker, no significant change was
observed following insulin treatment. Thus, in contrast to apoB mRNA, beta-globin mRNA
showed a high degree of co-localization with P bodies independent of insulin (Figure 19).
73
74
Figure 19 Effect of insulin on the co-localization of beta-globin mRNA with P bodies. HepG2 cells were co-transfected with EF1a-β-globin mRNA-MS2-bs and MS2-GFP-NLS plasmids, cells were then serum starved briefly (A) and treated with insulin for 1 hour (B), 4 hours (C), 8 hours (D), and 16 hours (E). Cells were then fixed and immunostained for hedls, one of the protein components of P bodies. Green represents beta-globin mRNA, P bodies are in red and DAPI was used to stain the nucleus (blue). Please see Appendix, figures 28-32 for full size confocal images.
75
3.2.8 Statistical Analysis
Pearson correlation coefficient is a measure of the correlation (linear dependence)
between two variables and is widely used as a measure of the strength of linear dependence
between two variables. This measure was utilized in order to validate the strength of the co-
localization of P bodies and apoB mRNA under insulin stimuli.
In order to compare the co-localization of apoB mRNA with P bodies at different
time points of insulin treatment, Velocity software version 5 was used. Pearson’s correlation
coefficients were assessed based on the intensity of green and red pixels that overlapped as
an indication of the co-localization. A number between zero to one was assigned to each cell
with zero indicating no co-localization and one representing complete co-localization.
Numbers obtained from 8 different slides were averaged and graphed as represented in
Figure 20. These co-localization experiments allowed a qualitative assessment of the
association of intracellular apoB mRNA with P body granules. Our data suggestes that
insulin promotes apoB mRNA colocalization with P bodies after 4, 8, and 16 hours (Figure
20). Conversely, ß-globin mRNA shows a relatively high co-localization with P bodies at all
the experimental time points regardless of the presence and absence of insulin (Figure 21).
76
Figure 20 Quantification of apoB mRNA co-localization with P bodies. In order to evaluate the colocalization of apoB mRNA with P bodies Velocity software version 5 was used to measure the Pearson’s correlation coefficients. A number between zero and one was alloted to each cell with zero indicating no colocalization and one specifying perfect colocalization. Data shown is mean +/- SD. *= p< 0.05.
Figure 21 Quantification of beta-globin mRNA co-localization with P bodies.Velocity software version 5 was used to calculate Pearson’s correlation coefficients. A number between zero and one was given to each cell. Number one represents complete colocalization and zero shows no colocalization at all. Data shown is mean +/- SD.
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77
IV. Discussion
Hepatic apoB synthesis is known to be regulated at multiple levels including
translation (40;41;63-65;164;182). Under different stimuli apoB mRNA levels stay relatively
constant while apoB protein synthesis and secretion varies greatly, thereby indicating the
importance of translational and posttranslational control mechanisms. Several studies from
our laboratory and others have shown that insulin reduces hepatic apoB protein synthesis and
secretion while mRNA levels remain stable (40;64;92;163;165). However, the molecular
mechanism(s) governing this inhibitory effect at the translational level have remained largely
unknown. Recent studies in our laboratory have revealed important translational mechanisms
of apoB mRNA involving the 5’ untranslated region (5’UTR). ApoB mRNA has a 5’UTR of
128 nucleotides and a 3’UTR of 304 nucleotides. Several structural features of apoB mRNA
UTR sequences suggest the presence of potential cis-elements that may interact with putative
trans-acting protein factors. A previous graduate student in our laboratory recently analyzed
the apoB UTR sequences using Mfold program, to predict RNA secondary structure, which
revealed elements within the 5' and 3'UTR’s of apoB mRNA with potential to form
secondary structure (66). They also assessed the biological activity of the putative RNA
motifs within the UTR sequences and found that 5'UTR motifs are important for optimal
translation of the apoB message. Deletion constructs of the UTR regions of apoB showed
that the 5'UTR was necessary and sufficient for insulin to inhibit apoB synthesis (66).
Interestingly, although insulin normally activates global translation of cellular protein
synthesis, it has a specific inhibitory effect on apoB mRNA translation. This suggests that
insulin induces a unique signaling cascade that leads to specific inhibition of apoB mRNA
78
translation despite global translational stimulation. Our laboratory has now demonstrated that
insulin may modulate apoB mRNA translation via changes in the binding of a trans-acting
110-kDa protein factor to the 5’UTR (15). This putative RNA-binding protein (referred to as
p110) was found to specifically bind the 5’UTR of apoB mRNA, with its binding reduced in
the presence of insulin (15). Moreover, absence of insulin increased binding of this trans-
acting factor to the 5' UTR by 2-fold. Interestingly, translational control of apoB mRNA via
the 5’UTR and the binding of the 110 kDa protein factor was found to be regulated by
protein kinase C (PKC) signaling cascade (68). Using dual (bicistronic) luciferase constructs,
our laboratory also examined the role of internal ribosomal entry (IRES) with respect to the
5'UTR of the apoB mRNA and found that the apoB 5’UTR possesses IRES activity and basal
translational activity of the apoB mRNA may be partly cap independent (67). Presence of the
p110 protein highlights the importance of RNA-protein interactions that regulate the fate and
activity of apoB mRNA intracellularly.
There is now increasing evidence that eukaryotic mRNAs (particularly those with
longer half lives) exist in association with protein complexes in the form of RNA granules
which can govern both mRNA decay and translational activity. We thus investigated the
potential role of RNA granules in modulating apoB mRNA and its translational efficiency.
4.1 Polysome Profiling
In order to study the effect of insulin on apoB translation polysome gradient
sedimentation fractionation method was applied. This method is commonly used to study
translation under different physiological and experimental states. Our model system was
79
HepG2 cells because they are hepatocellular carcinoma derived cell lines that constitutively
express apoB. We measured apoB mRNA levels associated with translationally-active
polysomes using Real-Time PCR. Our results suggested that insulin initially increases apoB
mRNA translation at 15 minutes and 1 hour, very similar to its effect observed on global
translation. Interestingly however, following longer insulin exposure (4 h), apoB mRNA
shifted towards lighter polysomes and monosome fractions, suggesting inhibition of
translational activity. At the same time point, global mRNA translation was still stimulated
by insulin treatment. With even longer insulin treatment (16 h), both apoB mRNA
association with heavy polysomes and total global polysomal activity were reduced. These
data suggest that apoB mRNA translation is uniquely inhibited by insulin under conditions
that stimulate global mRNA translation.
One of the challenges we were facing in this part of the project was to obtain enough
mRNA from each fraction to perform both the spectroscopic quantitation and Real Time
PCR. We first acquired twelve 1 mL fractions from each sucrose gradient, and used phenol
chloroform extraction method followed by lithium chloride (LiCl) precipitation to remove
the heparin which is a PCR inhibitor reagent. In order to eliminate the genomic DNA we
then performed DNase treatment. Finally in order to measure total mRNA in each fraction
we used 200 µL spectroscopy cuvettes. These steps resulted in significant loss of mRNA. In
order to address this problem, we fractionated the sucrose gradients to four 3 mL fractions,
and used a commercially available kit to extract higher amounts of RNA. We also made use
of a nanodrop spectrophotometer to measure the total RNA. In this type of
spectrophotometery one micro liter of the sample is sufficient to quantify RNA
concentration.
80
4.2 Storage of ApoB mRNA in Cytoplasmic RNA
Granules
Mature mRNAs in the cytoplasm of eukaryotic cells are associated with a complex
network of ribonucleoprotein particles (mRNPs) (168;169). Early studies of mRNPs showed
the presence of two major proteins (170), a 70-kDa poly(A) binding protein (PABP) (171)
and a 50-kDa protein (p50) responsible for the repressed, nonactive state of mRNAs, such as
globin mRNA within free mRNP particles (172). Recent studies have identified a large
number of other protein components of mRNPs including RNA binding proteins, RNA
helicases, and translational factors (173). Importantly, RNA granules have been identified in
both germ cells and somatic cells that appear to play important roles in mRNA storage,
stability, and translational control. All RNA granules contain translationally silenced
mRNAs. New evidence suggests a dynamic interaction between these RNA granules and
translationally-active polysomal mRNAs (174), suggesting that the availability of some
mRNAs could be regulated by the rate of release from translationally-silenced mRNAs
within RNA granules. Stress granules (SG) contain mRNAs encoding most cellular proteins
and appear when translation initiation is impaired; for example, following exposure to
environmental stress (157). Another type of cytoplasmic RNA granule, called Processing
Bodies (PBs) are composed of RNA and proteins and translationally inactive mRNAs (149).
The protein components of P bodies are involved in RNA stability, storage, translation and
decay (183). P bodies are mainly composed of mRNAs, the 5’ to 3’ mRNA decay machinery,
the nonsense-mediated decay pathway proteins and the RNA- induced silencing complex
(183).
81
It was initially unknown whether apoB mRNA translation can be controlled by the
release of translatable apoB mRNA transcripts from cytoplasmic stores of mRNPs that are
translationally repressed. However, the long half-life of apoB mRNA (16 h) suggests that a
significant proportion of the message may be stored in the cell prior to translation.
Interestingly, apoB mRNA polysome complexes have been reported to show unusual
physical properties and exhibit unique sedimentation behaviors more characteristic of
nonpolysomal mRNPs (175) further suggesting the existence of apoB mRNA in RNA
granules. We thus hypothesized that certain stimuli such as insulin may inhibit apoB mRNA
translation by reducing the release of translatable mRNA transcripts from stored mRNPs. In
order to test this hypothesis we investigated the colocalization of apoB mRNA with P bodies
under insulin stimuli.
The role of P bodies was examined by applying a recently-established method that
has been successfully employed to visualize exogenously expressed mRNAs in mammalian
cells (177). We made use of a strong interaction between bacteriophage capsid MS2 protein
and a sequence specific RNA stem-loops structure. Several studies have utilized this system
in order to track mRNA traffic in living cells. Bertrand et al., monitored the asymmetrical
movement of ASH1 mRNA in dividing yeast cells (184). Rook et al. and Fusco et al.
examined the movements of cytoplasmic RNA particles in neurons and COS cells (177;185).
Forrest and Gavis investigated the dynamic co-localization of endogenous nanos RNA in
Drosophila oocytes (186), and Kedersha et al. monitored the presence of single species of
mRNA transcripts in both SGs and PBs. This method has also been applied to study the RNA
trafficking in retroviruses (187;188). In this technique a fluorescent protein, for example,
GPF is fused to RNA phage MS2 coat protein with a nuclear localization signal at the C
82
terminus (184). The RNA of interest is constructed to contain tandem repeats of the specific
phage RNA sequence that binds MS2 coat protein. The strong interaction between the
bacteriophage capsid protein MS2 and the sequence specific RNA stem-loops structure helps
visualize the RNA.
In order to visualize apoB mRNA with PBs, we constructed a chimeric plasmid
containing 15% of apoB gene with 5’ and 3’UTRs at both ends followed by 24 tandem
repeats of MS2 binding sites. HepG2 cells were then transiently co-transfected with this
chimeric plasmid and a plasmid expressing MS2 protein fused to GFP. The latter plasmid
contains a nuclear localization signal (NLS) at its C-terminus. Upon expression MS2 protein
finds its binding site on the reporter mRNA and any unbound MS2-GFP protein sequesters in
the nucleus due to the presence of the NLS.
Spinning disk confocal microscopy technique enabled us to visualize apoB mRNA in
fixed HepG2 cells. We then investigated the co-localization of exogenous apoB mRNA with
P bodies in the presence or absence of insulin at different time points. Confocal studies
revealed that long term insulin exposure promotes the co-localization of apoB mRNA with P
bodies with increases of 72% (after 4 h), 85% (after 8 h), and 89% (after 16 h) in PB co-
localization compared to respective non-insulin treated controls. However, a shorter (1 hour)
insulin treatment did not appear to induce observable changes in PB co-localization. As a
control, when HepG2 cells were transfected with pMS2-GFP-NLS plasmid alone, the entire
GFP signal was confined to the nucleus due to the presence of a nuclear localization signal at
the C-terminus of the protein.
It is important to note that although the above mentioned Singer’s method is a very
useful tool in imaging an exogenous mRNA in living cells it has some limitations. For
83
example to get a strong GFP signal presence of 24 repeats of MS2-binding sites is mandatory
(177) and it is not possible to get a good signal using fewer repeats of MS2 binding sites.
Since two molecules of GFP interact with each one of the stem-loop structures, a large
amount of GFP accumulates in a small area. This in fact increases the intensity of the signal
at the expense of lowering sensitivity.
Another alternative for us was to use in situ hybridization method in which the
presence of an mRNA could be assessed by designing probes that target specific sequences
on the mRNA of interest, apoB in our case. The in situ hybridization technique is more direct
and has a higher specificity compared to the method we used; however, it is not applicable to
live cells. Since we were planning to perform some live cell imaging analysis eventually and
look at the apoB mRNA movements under different experimental stimuli we chose to use the
former method.
Nancy Kedersha et al. had previously investigated the colocalization of β-globin
mRNA with P bodies and Stress Granules (178), and we thus used the same β-globin plasmid
as a control and examined the effect of insulin on the co-locolization of β-globin mRNA with
P bodies. HepG2 cells were transiently co-transfected with a plasmid containing β-globin
mRNA followed by the MS2-binding site and a plasmid expressing MS2 coat protein fused
to GFP followed by a nuclear localization signal. We observed clear co-localization of β-
globin mRNA with P bodies under normal cell culture condition. However, as opposed to
apoB mRNA, colocalization of β-globin mRNA with P bodies was insensitive to insulin in
HepG2 cells.
As can be observed from confocal images, apoB mRNA and PB marker did not co-
localize in all PBs. This is expected since each eukaryotic cell holds many P bodies
84
containing a variety of different kinds of mRNAs. A single PB does not contain all mRNAs,
and also a single species of mRNA does not exist in all P bodies. Also, in some of the images
we obtained, the GFP signal was observed in both the nucleus and the cytoplasm. This was
due to the large amount of MS2-GFP protein expression. Owing to the presence of the NLS,
the surplus GFP which was not bound to the mRNA sequestered in the nucleus. This in fact
was predictable from the onset and did not interfere with the interpretation of the imaging
data.
The monoclonal antibody used to recognize cytoplasmic P bodies showed some
nuclear staining in addition to the cytoplasm. This is due to the reactivity of this antibody
with p70 S6 kinase protein. The double specificity of this antibody was confirmed using
recombinant hedls, and this antibody was used to visualize PBs in p70 S6 kinases knockout
cells (179). The anti-hedls antibody readily detects cytoplasmic P bodies, and most of the
non-hedls signal is nuclear and did not impede the recognition of cytoplasmic P bodies (179).
We were able to show that puromycin, an aminonucleoside antibiotic derived from
the Streptomyces alboniger bacterium that causes premature chain termination during
translation, promoted the assembly of P bodies in HepG2 cells. Similar effect has been
reported by Nancy Kedersha et.al working on yeast, HeLa, and U2OS mammalian cell lines
(178).
In some of the images we acquired, GFP signal was detected in both the nucleus and
the cytoplasm. This was due to the presence of a large amount of MS2-GFP protein
expression. Owing to the existence of nuclear localization at the C termini of this protein the
surplus GFP which was not bound to the mRNA sequestered in the nucleus. This was in fact
predictable from the beginning and did not interfere with the accuracy of data interpretations.
85
In conclusion, our data suggest that long-term insulin treatment may decrease apoB
mRNA translation by promoting the localization of the mRNA into P bodies. The time
course of insulin-mediated co-localization of apoB mRNA with P bodies coincides with
alterations in translational activity of the message. Cellular response to hormonal stimuli is
normally rapid, and like other hormonal responses, hepatocytes respond to insulin promptly
by decreasing apoB protein secretion via changes in protein stability/degradation. With
longer insulin exposure, hepatocytes reduce apoB synthesis by reprogramming apoB mRNA
and forcing the translationally-competent apoB mRNA towards P bodies for storage.
4.3 Postulated Mechanism of Insulin Modulation of ApoB
mRNA Traffic into P bodies
The present study shows that insulin silences apoB mRNA translation by localizing it
into P bodies and that this coincides with apoB mRNA run off from the translationally active
polysomes. However, the exact mechanism(s) that control apoB mRNA translational control
and the key molecule(s) that trigger apoB mRNA traffic into P bodies remain to be
elucidated. One possible mechanism may be through activation of an apoB mRNA binding
protein under insulin stimuli via protein modification(s), such as phosphorylation/
dephosphorylation. This activated RNA binding molecule will then interact with its proper
binding site on apoB mRNA, perhaps in the 5’UTR region that has been shown to play an
important role in regulating apoB mRNA translation in response to insulin. Such a cis-trans
interaction might result in the recruitment of P body factors to the mRNA through the
interaction of protein components of P bodies with the RNA binding protein(s) or directly
86
with apoB mRNA through new binding sites that appear after structural changes induced
following binding of the activated RNA binding factor. The newly formed small P Bodies
will then interact with each other through protein-protein interactions leading to the assembly
of larger P body aggregates. The translationally repressed apoB mRNA in P bodies could
have two faiths: it may either be degraded or reenter the translational machinery by
dissociating from P body granules, interacting with 40S ribosomal subunit and initiation
factors and assembeling into translationally active polysomes. Figure 22 depicts a proposed
model for insulin modulation of apoB mRNA localization in P bodies and the role of this
process in apoB mRNA translational control.
87
Figure 22. A proposed model for insulin modulation of apoB mRNA traffic into P bodies. Recent evidence suggest that insulin suppresses apoB mRNA translation through cis-transacting interactions with 5’UTR regions of apoB mRNA. Activation of RNA binding factor(s) by insulin facilitates their interaction with apoB mRNA and recruitment of P body components which nucleate the formation of larger P body aggregates. This results in translational suppression of apoB mRNA. Translationally repressed apoB mRNA could then either be degraded or disassembled from P bodies, re-associate with the translational machinery and be translated.
88
V. Conclusions
Although insulin normally activates global translation of cellular protein synthesis, it
has a specific inhibitory effect on apoB mRNA translation. This suggests that insulin induces
a unique signaling cascade that leads to specific inhibition of apoB mRNA translation despite
global translational stimulation. The mechanisms involved are post-transcriptional events
since apoB mRNA levels remained stable. In our investigation, we studied the potential role
of cytoplasmic RNA granules (P bodies) in insulin mediated translational regulation of apoB.
There is now increasing evidence that eukaryotic mRNAs (particularly those with longer half
lives) exist in association with protein complexes in the form of RNA granules which can
govern both mRNA decay and translational activity. P bodies control the translation of many
mRNAs in eukaryotic cells and we postulated that apoB mRNA is subcellularly
compartmentalized in the form of ribonucleoprotein complexes in RNA granules, which act
as a reservoir for translatable mRNA, a process potentially inhibitable by insulin.
In the current study we made use of a strong interaction between bacteriophage MS2
capsid protein and MS2 binding site to visualize apoB mRNA and to examine the influence
of insulin on the co-localization of apoB mRNA with P bodies. Spining disk confocal
imaging revealed that long-term insulin exposure promotes significant co-localization of
apoB mRNA with P bodies compared to non-insulin treated controls. Our data suggested that
insulin highly promotes apoB mRNA localization with P bodies after long-term insulin
treatment. Importantly, insulin-mediated co-localization of apoB mRNA with P bodies
coincided with alterations in translational activity of the message, based on polysomal
profiling experiments. Under these conditions, global mRNA translation was still stimulated
89
by insulin treatment. These data suggest that apoB mRNA translation is uniquely inhibited
by insulin under conditions that stimulate global mRNA translation. The time-course of
translational inhibition correlates with movement of apoB mRNA into cytoplasmic P bodies.
90
VI. Future Directions
ApoB mRNA translation is likely controlled by a complex network of RNA binding
proteins that interact with its 5’UTR and or 3’UTR regions. Insulin is a putative modulator of
some of these interactions. Therefore, it is important to investigate the effect of known RNA
binding proteins on apoB mRNA translation, and also to identify and characterize the novel
RNA binding proteins that regulate apoB mRNA translation. An important next step is to
study the regulatory effect of insulin on the cis-trans interactions on the apoB mRNA 5’UTR.
It will also be important to identify the RNA binding proteins involved in translational
repression of the apoB message and formation of RNA granules. Finally, considering the
exploration of interest in the role of miRNAs in regulating translation and mRNA decay, it
would be interesting to determine whether specific miRNAs are involved in translational
control of apoB mRNA. Recent bioinformatics analysis of the apoB mRNA sequence has
identified at least two miRNAs (miR-1202 and miR-544) that appear to interact with apoB
UTRs, supporting a possible role for miRNAs in regulation of apoB mRNA translation.
91
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Appendix
ApoB, Nucleus, P bodies
Figure 23 Visualizing apoB mRNA traffic in HepG2 Cells: 4 hour exposure to insulin induced co-localization of apoB mRNA with P bodies. HepG2 cells were transiently contransfected with pCMV-5’URT-ApoB15%-3’UTR-MS2bs-24X-cyto and MS2-GFP-NLS plasmids. 16 hours post transfection cells were serum sratved briefly and treated with insulin for 4 h. Green represents apoB mRNA, P bodies are in red and DAPI was used to stain the nucleus (blue).
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ApoB, Nucleus, P bodies
Figure 24 Visualizing apoB mRNA traffic in HepG2 Cells: 8 hour exposure to insulin induced co-localization of apoB mRNA with P bodies. HepG2 cells were transiently contransfected with pCMV-5’URT-ApoB15%-3’UTR-MS2bs-24X-cyto and MS2-GFP-NLS plasmids. 16 hours post transfection cells were serum sratved briefly and treated with insulin for 8 h. Green represents apoB mRNA, P bodies are in red and DAPI was used to stain the nucleus (blue).
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ApoB, Nucleus, P bodies
Figure 25 Visualizing apoB mRNA traffic in HepG2 Cells: 16 hour exposure to insulin induced co-localization of apoB mRNA with P bodies. HepG2 cells were transiently contransfected with pCMV-5’URT-ApoB15%-3’UTR-MS2bs-24X-cyto and MS2-GFP-NLS plasmids. 16 hours post transfection cells were serum sratved briefly and treated with insulin for 16 h. Green represents apoB mRNA, P bodies are in red and DAPI was used to stain the nucleus (blue).
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ApoB, Nucleus, P bodies
Figure 26 Visualizing apoB mRNA traffic in HepG2 Cells: 1 hour exposure to insulin din not induce co-localization of apoB mRNA with P bodies. HepG2 cells were transiently contransfected with pCMV-5’URT-ApoB15%-3’UTR-MS2bs-24X-cyto and MS2-GFP-NLS plasmids. 16 hours post transfection cells were serum sratved briefly and treated with insulin for 1 h. Cells were then fixed and immunostained for hedls, one of the main protein components of P Bodies. Green represents apoB mRNA, P bodies are in red and DAPI was used to stain the nucleus (blue).
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ApoB, Nucleus, P bodies
Figure 27 Effect of serum starvation on the co-localization of apoB mRNA with P bodies. HepG2 cells were transiently contransfected with pCMV-5’URT-ApoB15%-3’UTR-MS2bs-24X-cyto and MS2-GFP-NLS plasmids. 16 hours post transfection cells were serum sratved briefly. Cells were then fixed and immunostained for hedls, one of the main protein components of P Bodies. Green represents apoB mRNA, P bodies are in red and DAPI was used to stain the nucleus (blue).
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Beta-globin, Nucleus, P bodies
Figure 28 Effect of serum starvation on the co-localization of beta-globin mRNA with P bodies. HepG2 cells were co-transfected with EF1a-β-globin mRNA-MS2-bs and MS2-GFP-NLS plasmids, cells were then serum starved briefly. Cells were then fixed and immunostained for hedls, one of the protein components of P bodies. Green represents beta-globin mRNA, P bodies are in red and DAPI was used to stain the nucleus (blue).
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Beta-globin, Nucleus, P bodies
Figure 29 Effect of 1hour insulin exposure on the co-localization of beta-globin mRNA with P bodies. HepG2 cells were co-transfected with EF1a-β-globin mRNA-MS2-bs and MS2-GFP-NLS plasmids, cells were then serum starved briefly and treated with insulin for 1 hour. Cells were then fixed and immunostained for hedls, one of the protein components of P bodies. Green represents beta-globin mRNA, P bodies are in red and DAPI was used to stain the nucleus (blue).
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Beta-globin, Nucleus, P bodies
Figure 30 Effect of 4 hour insulin exposure on the co-localization of beta-globin mRNA with P bodies. HepG2 cells were co-transfected with EF1a-β-globin mRNA-MS2-bs and MS2-GFP-NLS plasmids, cells were then serum starved briefly and treated with insulin for 4 hours. Cells were then fixed and immunostained for hedls, one of the protein components of P bodies. Green represents beta-globin mRNA, P bodies are in red and DAPI was used to stain the nucleus (blue).
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Beta-globin, Nucleus, P bodies
Figure 31 Effect of 8 hour insulin exposure on the co-localization of beta-globin mRNA with P bodies. HepG2 cells were co-transfected with EF1a-β-globin mRNA-MS2-bs and MS2-GFP-NLS plasmids, cells were then serum starved briefly and treated with insulin for 8 hours. Cells were then fixed and immunostained for hedls, one of the protein components of P bodies. Green represents beta-globin mRNA, P bodies are in red and DAPI was used to stain the nucleus (blue).
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Beta-globin, Nucleus, P bodies
Figure 32 Effect of 16 hour insulin exposure on the co-localization of beta-globin mRNA with P bodies. HepG2 cells were co-transfected with EF1a-β-globin mRNA-MS2-bs and MS2-GFP-NLS plasmids, cells were then serum starved briefly and treated with insulin for 16 hours. Cells were then fixed and immunostained for hedls, one of the protein components of P bodies. Green represents beta-globin mRNA, P bodies are in red and DAPI was used to stain the nucleus (blue).