lecture 4
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Lecture 4
Differentiation and Reprogramming
Maintenance and stability of differentiated cell states
Reprogramming in normal development
Experimental Reprogramming
You should understand;
Reprogramming in the germ line and in early embyros
Experimental reprogramming approaches
Mechanisms that contribute to determination and maintenance of differentiated cell fates.
• As development proceeds cell fate becomes progressively restricted and there is a loss of plasticity.
• Adult stem cells retain some degree of plasticity.
• Cell identity is conferred by the transcriptional program, the sum of ‘on’ vs ‘off’ genes.
• Cell identity is generally stable, attributable to ‘memory’ mechanisms.
• Cells of the early embryo differentiate into many cell types – plasticity.
• The identity of differentiated cells can be reversed back to a more plastic embryonic state in certain circumstances - reprogramming.
Differentiation and reprogramming - overview
Stem cell; unlimited capacity to self-renew and produces differentiated derivatives
Progenitor cell; limited capacity to self-renew and can produce differentiated derivatives
Terminally differentiated/specialised cell
Memory mechanisms; master transcription factors define cell type specific transcription programs
Davis et al (1987) Cell 51, p987-1000
• MyoD, a muscle specific helix-loop-helix transcription factor converts fibroblast to myoblastswhen expressed from a heterologous promoter
• MyoD cooperates with three related transcription factors, myf5, mrf4 and myogenin to promotemuscle identity
• Myogenic transcription factors directly activate muscle specific genes, including themselvesand one another, forming an autoregulatory loop that stabilises muscle cell identity
• Participation of master transcription factors in autoregulatory loops facillitates stabilisation ofcell identify in other cell types, eg Sox2/Oct4/Nanog in ES cells and Cdx2/Gata3 in trophectoderm.
• MyoD can induce a muscle specific expression program in several but not all cell typesanalysed.
Chromatin modification contributes to maintenance of cell identity and ‘memory’ by creating
stable (epigenetic/heritable) on and off states.
• Histone tail modifications (acetylation, methylation, phosphorylation, ubiquitylation etc)
• DNA methylation• Histone variants (H1 types, H2AZ, H2AX, CENPA, H3.1/3.3 etc)
Lysine acetylationLysine methylationArginine methylationLysine ubiquitylationSer/Thr phosphorylationDNA (cytosine) methylation
+ Linker histone (H1)+ Histone variants (Cenp, H2AZ etc)
Modifications and variants
Open/accessible/permissive(active promoters, replication sites, repair sites)
Closed/inaccessible/non-permissive(centromeres/telomeres, inactive X, silent promoters)
Writers
HATs and HDACs
Chromodomain proteins
PHD, PWWP, ADD etc
Tudor domain proteins
MBD domain proteins
None of the above!
KHMTase and KDMase
PRMTs and demethylases
E3 ligases and DUBs
Kinases and phosphatases
Readers
Dnmts and demethylases
Bromodomain proteins
Memory mechanisms; chromatin effectsX inactivation and imprinting
Inactive Xchromosome
Repressivechromatin marks
Active Xchromosome
Imprinted genesilent on paternal chromosome
Imprinted geneactive on maternal chromosome
Transcription factors/master regulatorsNucleus
Heritable gene silencing by CpG DNA methylation
• Methylation patterns are established by Dnmt3a/b in early development.
• Faithfully maintained through DNA replication (Dnmt1).
• Repressive but limited role in gene regulation; imprintedgenes, inactive X chromosome, Nanog and otherpluripotency genes in early zygote and somatic cells. Oct4 in developing embryo.
CpGGpC
Me
Me
Polycomb and Trithorax proteins are ‘memory’ factors that stabilise cell identity
• Genetic studies in fly identify factors required to maintain ‘on’ state (trithorax group/TrxG) or ‘off’ state(Polycomb group/PcG) of hox cluster genes.
• Highly conserved and important for regulation of developmental genes in all multicellular organisms.
Simon and Kingston (2009) Nat Rev Mol Cell Biol 10, p697-708. Review
PcG and TrxG proteins participate in multiprotein complexes that modify chromatin.
Methylation of histoneH3 lysine 27
Ubiquitylation of histoneH2A lysine 119
ATP dependentchromatin remodelling
Methylation of histoneH3 lysine 4 or 36
Polycomb group Trithorax group
• Mechanism for stable propagation of histone marks not well understood
Reprogramming
• In mammals reprogramming is part of normal development, specifically in developing germ cells and in preimplantation embryos.
• Experimental reprogramming in mammalian cells achieved by cloning (Dolly) but also by cell fusion, and more recently using iPS technology.
• Nuclear transfer experiment suggested by Spemann in 1938, was performed for blastocyst cells by Briggs and King, 1952, and for tadpole and then adult cells by Gurdon, 1957.
Briggs and King (1952) Proc Natl Acad Sci U S A. 38, p55-63; Gurdon et al (1958) Nature 182, p64-5
Reprogramming during germ cell development
• De novo DNA methylation including imprinted loci (different for male and female germ cells).
Post-natal
• Repression of somatic program and reactivation pluripotency program
• Changes in global histone modification status
• Loss of DNA methylation (active/passive?) including erasure of parental imprints
Pre-natal
Reprogramming in preimplantation development
• Active (replication independent) and passive (replication linked) demethylation occur between 1-celland blastocyst stage.
• Methylation is re-established by de novo Dnmts from blastocyst through to egg-cylinder stages.
• Methylation of imprinting control regions is protected from genome wide demethylation.
TET proteins (TET1/2/3) are DNA hydroxylases that oxidise 5-methyl cytosine.
Wu and Zhang, (2011) Genes and Dev. 25, p2436-2452, Review.
• Reactivation of inactive X chromosome in ICM cells.
Cloning
• Many failed attempts to clone mammals led to the belief this wouldn’t be possible until Dolly
• Methodology now extended to mouse, cat, cow and many other mammalian species
• Briggs and King and then Gurdon experiments demonstrated amphibian oocytes can induce complete reprogramming of a somatic cell nucleus.
• Cloning of a mouse from a lymphocyte finally proves cloning of terminally differentiated cell is possible.
• Frequency of success (liveborn) remains poor, less than 1/100.
Campbell, Wilmut and colleagues, 1996
Campbell et al (1996) Nature 380, p64-6; Wakayama et al (1998), Nature 394, p369-74 ;Hochedlinger and Jaenisch (2002) Nature 415, p1035-8
Cloning
• Cloned female mouse embryos partly reprogram X inactivation but efficiency of cloning much improvedin Xist knockout, both in male and female, suggesting that donor cell Xist is often inappropriately activated
• Cloned animals often have serious health problems with fetal overgrowth being commonplace – attributable to misexpression of important genes
• Analysis of cloned mice indicate up to 4% of genes misexpressed
• Cell cycle stage of donor nucleus influences efficiency (G1 or G0 thought to be best) - mechanism unknown
• In cloned mouse blastocysts activation of pluripotency genes is often incomplete and highly variable
Factors influencing efficiency of cloning
Cell fusion of somatic and pluripotent cells
• Pioneering experiments by Henry Harris in 1969 demonstrated dominance - suppression of transformed phenotype following fusion of transformed cells and certain normal cells – posited tumour supressor loci
• Blau and colleagues demonstrated fibroblasts converted to myoblasts in myoblast/fibroblast fusion
• Ruddle, Takagi, Martin and others show EC cell hybrids with somatic cells have pluripotentdifferentiative capacity and reactivate inactive X chromosome.
Cell type A
Cell type B
Sendai virusPEGElectroshock
Heterokaryon 4N hybrid
Same or different species
Harris et al (1969) J. Cell Sci. 4, p449-525; Blau et al (1985) Science 230, p758-766; Miller and Ruddle (1976) Cell 9, p45-55;Takagi et al (1983) Cell 34, p1053-62; Martin et al (1978) Nature 271, p329-33
2N hybrid
Cell fusion of somatic and pluripotent cells
• Mouse ES cell rapidly activates ES cell program in human B-lymphocyte genome in transient heterokaryon.
• Precocious DNA synthesis induced in the somatic nucleus is required for reprorgramming.
Pereira et al (2008). PLoS Genet. 4, e1000170Tsubouchi et al (2013) Cell 152, p873–883.
Induced pluripotent stem (iPS) cells
• Mouse iPS cells contribute to chimeras and can be passed through the germline
Neomycin resistance ORF
Fbx15NanogetcX
Fibroblast cells
Neomycin resistance ORF
Fbx15Nanogetc
iPS cellsIntroduce genes for ES cell factorsX24 then narrowed down to;Oct4, Sox2, Klf4, c-myc
+ LIF + feeders + neomycinApprox 2 weeks…..
• Reactivation of somatic cell inactive X chromosome.
• iPS cells induce endogenous pluripotency genes and switch off fibroblast program.
Takahashi and Yamanaka (2006) Cell 126, p663-76
Induced pluripotent stem (iPS) cellsConversion to iPS cells is relatively inefficient – why?
• Requires sequential activation of different endogenous ES cell factors at different times –stepwise reversal of differentiation?
• Stochastic epigenetic changes
• Conversion occurs without c-myc but less efficiently – cell cycle effects?
Transdifferentiation by master transcription factors
• Forced MyoD expression can convert a variety of cell types into myoblasts
• B-cells to macrophage by addition of C/EBP
• Pancreatic exocrine to endocrine cells by Ngn3, Pdx1 and MafA cocktail.
• Fibroblasts to neuron like cells by Ascl1, Brn2, and Mytl1
Hanna et al (2010) Cell 143, p508-525. Review
Uniqueness of the pluripotent state
• Expression of factors required to erase epigenetic information in somatic cells e.g DNA and histone demethylases.
• Oct4/Nanog/Sox2 directly repress master regulators of many other lineages -associated with presence of repressive together with active histone modifications (bivalency), suggesting a poised state.
• Disengagement of epigenetic feedback loops?
Azuara et al (2006) Nat Cell Biol. 8, p532-8; Bernstein et al (2006) Cell 125, p315-26
• Human ES cell lines first isolated in 1998
• Derived from blastocyst stage embryos and grow indefinitely with stable karyotype.
• Not LIF/BMP dependent - require FGF2 and Activin instead.
• Have capacity to differentiate into cell types from all three germ layers (+ trophectoderm)– potential use in regenerative medicine.
• Express ES cell markers such as alkaline phosphatase and core transcription factors Nanog, Oct4 and Sox2’ in common with mouse ES cells.
Thomson et al (1998) Science 282, p1145-7
The application of reprogramming technology
• Human iPS cells derived from fibroblasts using Yamanaka factor cocktails.
The application of reprogramming technology
• Cell/tissue replacement
• Disease models (patient specific cell lines)
• Cell factories
• Drug testing
Challenges;
• Teratoma formation
• Heterogeneity in iPS lines/incomplete reprogramming
See Yamanaka and Blau review
End lecture 4
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