the chemistry of the cell m. saifur rohman, md. phd. fiha. fica
TRANSCRIPT
The Chemistry of the cell
M. Saifur Rohman, MD. PhD. FIHA. FICA
Chemical Component of The Cell• Cell Chemistry Is based on Carbon Compounds .
• A living cell is composed of C, H, N, and O make up nearly 99% of its weight.
• The most abundant substance of the living cell is water. (70% of a cell's weight), and most intracellular reactions occur in an aqueous environment.
• All organisms have been designed around the special properties of water, such as its polar character, its ability to form hydrogen bonds, and its high surface tension.
Percentage Component of The Cell
The Carbon• If we disregard water, nearly all of the molecules in a cell are
carbon compounds
• The carbon atom, because of its small size and four outer-shell electrons, can form four strong covalent bonds with other atoms.
• Most important, it can join to other carbon atoms to form chains and rings and thereby generate large and complex molecules with no obvious upper limit to their size.
• The other abundant atoms in the cell (H, N, and O) are also small and able to make very strong covalent bonds
Covalent bond
Covalent bonds - form when atoms share electron pairs.– strongest type of bond– tend to form when atoms have 3, 4 or 5
valence electrons– can be nonpolar or polar
Cells Use Four Basic Types of Small Molecules • Certain simple combinations of atoms - such as the methyl (-
CH3), hydroxyl (-OH), carboxyl (-COOH), and amino (-NH2) groups - recur repeatedly in biological molecules.
• The small organic molecules of the cell have molecular weights in the range 100 to 1000 and contain up to 30 or so carbon atoms.
• They are usually found free in solution, where some of them form a pool of intermediates from which large polymers, called macromolecules, are made.
• They are also essential intermediates in the chemical reactions that transform energy derived from food into usable forms
Sugars, Fatty Acid, Amino Acid and Nucleotide
• All biological molecules are synthesized from and broken down to the same simple compounds.
• Biochemical Energetics for cellular reaction and function
• Broadly speaking, cells contain just four major families of small organic molecules: the simple sugars, the fatty acids, the amino acids, and the nucleotides.
• Although some cellular compounds do not fit into these categories, the four families, and especially the macromolecules made from them, account for a surprisingly large fraction of the mass of every cell
Suggested reading topics
• Lodish et al. Chemical foundations in 4th edition Molecular Cell Biology. WH Freeman and Company 2000. Pp 14-49.
• Cooper GM. The chemistry of the cell in The cell: A molecular Approach. ASM PRESS. 1997. pp. 39-85.
Amino Acid
M. Saifur Rohman, MD. PhD. FIHA
• Structure• Classification• Peptide Bond• Force
Amino Acid
• Amino acids are molecules containing an amine group, a carboxylic acid group and a side chain that varies between different amino acids.
• These molecules contain the key elements of carbon, hydrogen, oxygen, and nitrogen.
• Particularly important in biochemistry, where this term usually refers to alpha-amino acids with the general formula H2NCHRCOOH, where R is an organic substituent.
Amino Acid
Lecture 6.3 13
H3N+
O
O
RH
Amino Acids
• The general formula for an amino acid
• R is commonly one of 20 different side chains
• At pH 7 both the amino and carboxyl groups are ionized
aminogroup
alphacarbon
carboxylgroup
side chaingroup
Families of Amino Acids
• The common amino acids are grouped according to whether their side chains are:– acidic D, E– basic K, R, H– uncharged polar N, Q, S, T, Y– nonpolar G, A, V, L, I, P, F, M, W, C
• Hydrophilic amino acids (uncharged polar) are usually on the outside of a protein whereas nonpolar residues cluster on the inside of protein
• Basic or acidic amino acids are very polar and are generally found on the outside of protein molecules
Protein AA : Polymerization
• As both the amine and carboxylic acid groups of amino acids can react to form amide bonds, one amino acid molecule can react with another and become joined through an amide linkage.
• This polymerization of amino acids is what creates proteins. This condensation reaction yields the newly formed peptide bond and a molecule of water.
An illustration of Polymerization
O
R3HNH
O
R4HH3N+
O
R1HNH
O
R2HNH
O
Peptide Bonds
• Amino acids are joined together by an amide linkage called a peptide bond.
• The two bonds on either side of the rigid planar peptide unit exhibit a high degree rotation
peptidebonds
rotation occurs here
Peptide bond
• Protein is a chain of amino acids linked by peptide bonds
• Peptide bond– Type of covalent bond
– Links amino group of one amino acid with carboxyl group of next
– Forms through condensation reaction
Protein Sequence Features
• Proteins exhibit far more sequence and chemical complexity than DNA or RNA
• Properties and structure are defined by the sequence and side chains of their constituent amino acids
• The “engines” of life• >95% of all drugs target proteins• Favorite topic of post-genomic era
Protein Sequence Databases
• Where does protein sequence information reside? – Entrez Cross Database Search
• http://www.ncbi.nlm.nih.gov/gquery/gquery.fcgi
– Swissprot & TrEMBL• http://ca.expasy.org/sprot/
– PIR• http://pir.georgetown.edu/
• As of December 2003, all of this information is integrated into unified protein database called Uniprot.– Uniprot
• http://www.pir.uniprot.org/
D Dobbs ISU - BCB 444/544X: Protein Structure & Function 22
Protein Structure & Function
• Protein structure - primarily determined by sequence
• Protein function - primarily determined by structure
• Globular proteins: compact hydrophobic core & hydrophilic surface
• Membrane proteins: special hydrophobic surfaces• Folded proteins are only marginally stable• Some proteins do not assume a stable "fold" until they bind to
something = Intrinsically disordered Predicting protein structure and function can be very hard -- &
fun!
D Dobbs ISU - BCB 444/544X: Protein Structure & Function
4 Basic Levels of Protein Structure
• Primary• Secondary• Tertiary
Basics of Protein Structure
ACDEFGHIKLMNPQRSTVWY
primary structure
Primary structure
• Sequence of amino acids
• Unique for each protein
• Two linked amino acids = dipeptide
• Three or more = polypeptide
• Backbone of polypeptide has N atoms:
-N-C-C-N-C-C-N-C-C-N-
• Primary structure influences shape in two main ways:– Allows hydrogen bonds to form between
different amino acids along length of chain– Puts R groups in positions that allow them to
interact
Primary Structure & Protein Shape
D Dobbs ISU - BCB 444/544X: Protein Structure & Function
Secondary Structure
– Local spatial arrangement of amino acids– Description of short-range non-covalent
interactions– Hydrogen bonds form between different parts of
polypeptide chain– These bonds give rise to coiled or extended pattern– Periodic structural patterns: -helix, b-sheet
Common Secondary Structure Elements
• The Alpha Helix
The -helix is a common secondary structure element
• A helical wheel is a representation of the 3D structure of the -helix.
• Projection of aa side chains onto a plane perpendicular to axis of helix
• Hydrophobic arcs stabilize helical interactions
• Amphipathic helices are commonnonpolar
acidic
Common Secondary Structure Elements
• The Beta Sheet
Secondary Structure & Protein Folding
• Understanding the forces of hydrophobicity:
nonpolarside chains
polar side chains
unfolded or partially folded polypeptide
folded conformation
Hydrogen bonds can form with polar side chainson outside of the protein
hydrophobic core containsnonpolar side chains
D Dobbs ISU - BCB 444/544X: Protein Structure & Function 32
Tertiary & Quaternary Structure
• Tertiary – Overall 3-D "fold" of a single polypeptide chain– Spatial arrangement of 2’ structural elements;
packing of these into compact "domains"– Description of long-range non-covalent
interactions (plus disulfide bonds)
• Quaternary– In proteins with > 1 polypeptide chain, spatial
arrangement of subunits
Tertiary Structure
Lactate Dehydrogenase: Mixed /
Immunoglobulin Fold:
Hemoglobin B Chain:
Tertiary Structure
Folding as a result of interactions between R groups
heme group
coiled and twisted polypeptide chain of one globin molecule
Quaternary Structure
Some proteins are
made up of more
than one
polypeptide chain
Hemoglobin
Force important for protein structure
• Ionic bonds• Covalent bonds• Van der waals forces• Hydrogen bonds
Folding of a polypeptide chainFolding of a polypeptide chain
Non-covalent amino acid interactions
• Hydrogen bonds C=O …. HN
• C=O : Glu, Asp, Gln, Asn
• NH : Lys, Arg, Gln, Asn, His
• OH : Ser, Thr, Glu, Asp, Tyr
Folding of a polypeptide chainFolding of a polypeptide chain
Non-covalent amino acid interactions
• Ionic bonds COO- …. +H3N
• COO- : Glu, Asp pKa < 5
• NH3 + : Lys, Arg pKa > 10
Folding of a polypeptide chainFolding of a polypeptide chain
Non-covalent amino acid interactions
• Van der Waals forces
• electrostatic in nature, short ranges
• dipole-dipole, ion-dipole etc.
Folding of a polypeptide chainFolding of a polypeptide chain
Levels of protein folding
• Primary structure (unfolded state)
• Secondary structure (-helix, -sheet)
• Tertiary structure (domains, subunit)
• Quaternary structure (several pp chains)
• Intra- and intermolecular disulfide bonds
Suggested reading topics
• Lodish et al. Protein structure and function in 4th edition Molecular Cell Biology. WH Freeman and Company 2000. Pp 50-99.
Protein Synthesis, Processing and Regulation
M. Saifur Rohman, MD. PhD. FIHA
Protein Synthesis Intracellular
• In cells, this reaction does not occur directly; instead the amino acid is first activated by attachment to a transfer RNA molecule through an ester bond.
• This aminoacyl-tRNA is then a substrate for the ribosome which catalyzes the attack of the amino group of the elongating protein chain on the ester bond.
• All proteins made by ribosomes are synthesized starting at their N-terminus and moving towards their C-terminus
Protein synthesis
• DNA• mRNA (transcription)• Protein (translation)
From DNA to Protein
Mutation consequence on Protein seq
Post-Translational Modification• New polypeptides usually fold themselves spontaneously into
their active conformation. However, some proteins are helped and guided in the folding process by chaperone proteins
• Many proteins have sugars, phosphate groups, fatty acids, and other molecules covalently attached to certain amino acids. Most of this is done in the endoplasmic reticulum.
• Many proteins are targeted to specific organelles within the cell. Targeting is accomplished through “signal sequences” on the polypeptide. In the case of proteins that go into the endoplasmic reticulum, the signal seqeunce is a group of amino acids at the N terminal of the polypeptide, which are removed from the final protein after translation.
Posttranslational modifications Posttranslational modifications
Chemical alterations after protein synthesis
• May alter activity, life span or cellular location
• Chemical modification• Acetylation, phosphorylation, glycosylation
• Processing• Proteolytic (in)activation, selfsplicing
Protein processing and regulation
Protein modification : becoming a functional protein• Folding• Proteolysis• Glycosylation• Signal sequence
Protein synthesis on the ER
Protein folding by chaperonin
Signal peptidase
Signal peptide
AAAAAAAAAA
AAAAAAAAAA
HSP40BiP
(HSP70)
Membrane proteins• Complications: proteins embedded in membranes• protein contains a stop-transfer sequence which is too hydrophobic
to emerge into aqueous environment of ER lumen• stop-transfer sequence therefore gets stuck in membrane• ribosome lets go of translocon, finishes job in cytoplasm • translocon dissociates, leaves protein embedded in membrane • example = LDL receptor
Suggested reading topics
• Cooper GM. Protein synthesis, processing and regulation in The cell: A molecular Approach. ASM PRESS. 1997. pp. 273-311.
Thank You