Lecture 3 Protein Structure, Function and Translation PDF
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Summary
This document is a lecture about protein structure, function and translation. It covers topics such as amino acids, the genetic code, translation, and protein synthesis steps. The lecture also describes the players involved in protein synthesis, such as ribosomes, tRNA, and mRNA. It eventually describes post-translational modifications and regulates protein structure.
Full Transcript
Molecular Diagnostics Translation / Protein Synthesis Lecture 3 Building Blocks of Protein • Amino acids are the structural units (monomers) that make up proteins. • There are the 20 biologically active amino acids in humans. They are encoded directly by the codons of the universal genetic code ar...
Molecular Diagnostics Translation / Protein Synthesis Lecture 3 Building Blocks of Protein • Amino acids are the structural units (monomers) that make up proteins. • There are the 20 biologically active amino acids in humans. They are encoded directly by the codons of the universal genetic code are called standard or canonical amino acids • There are nine Essential amino acids (indispensable) amino acid , which cannot be synthesized de novo ), and have to get them from diet. – histidine, isoleucine, leucine, lysine, methionine, phenylalanine, threonine, tryptophan, and valine. • Amino Acids join together to form short polymer chains called peptides or longer chains called either polypeptides or proteins. • Basic Amino Acid Structure R Group Residues Peptide Bond Formation The Genetic Code • Codon – a sequence of three nucleotides that together form a unit of genetic code in a DNA or RNA molecule, and the genetic information is translated into proteins by living cells. • Nonoverlapping • Universal in plant and animal kingdoms (ex. Mitochondrial code) • Degenerate (wobble base codon) – The first two positions of the mRNA codon observe Watson-Crick base pairing rules (A-U, C-G) The third position exhibits wobble • Read by complementary tRNA linked to aa • Initiation codon = AUG (met) • Stop codons (UAA, UGA, UAG) The Genetic Code All 64 possible 3-letter combinations of the DNA coding units T, C, A and G (43) are used either to encode one of these amino acids or as one of the three stop codons that signals the end of a sequence. While DNA can be decoded unambiguously, it is not possible to predict a DNA sequence from its protein sequence. Because most amino acids have multiple codons, a number of possible DNA sequences might represent the same protein sequence. Translation • Information decoding • High energy consuming process – consumes 90% of cells energy – 4 ATP / aa Protein Synthesis Players • • • • Ribosome / rough ER / rER (rRNA + protein) tRNA = anticodon with aa mRNA = codon Ribosome has 2 sites which associate with mRNA – P site (initaition) – A site (elongation) Protein Synthesis Steps • Initiation – 1st aa always methionine (Met) at P site – Template = mRNA – mRNA moves down in register (A site) and codon is read by anticodon of tRNA • Elongation – new aa brought in to match new codons and peptide bonds formed • Termination – Stop codon (UGA,UAA,UAG) Massager RNA (mRNA) • Carries instructions from DNA to the rest of the ribosome. • Tells the ribosome what kind of protein to make Transfer RNA (tRNA) A go-getter. Gets the right parts to make the right protein according to mRNA instructions amino acid attachment site Methionine U A C Anticodon UAC Ribosomal RNA (rRNA) • Part of the structure of a ribosome • Helps in protein production • Ribosomes contain two major rRNAs and 50 or more proteins • rRNA sequences are widely used for working out evolutionary relationships among organisms Type Size Large subunit (rRNAs) Small subunit (rRNA) prokaryotic 70S 50S (5S : 120 nt, 23S : 2906 nt) 30S (16S : 1542 nt) eukaryotic 80S 60S (5S : 121 nt, 5.8S : 156 nt, 28S : 5070 nt) 40S (18S : 1869 nt[4]) Ribosomes 40s 30s PRO 70S 30S 16S EUK 80S 50s 50S 5S 23 60s 40S 18S 60S 5.8S 5S 28S Ribosomes in Endoplasmic Reticulum Ribosomes Large subunit P Site A Site mRNA A Small subunit U G C U A C U U C G Initiation aa2 aa1 2-tRNA 1-tRNA anticodon U A C hydrogen bonds A U G codon G C U A C U U A C U G mRNA A Elongation peptide bond aa3 aa1 aa2 3-tRNA 1-tRNA anticodon U A C hydrogen bonds A U G codon G 2-tRNA G C A U U A C U U A C mRNA G A A Elongation peptide bond aa1 aa2 1-tRNA anticodon hydrogen bonds U A A codon 3-tRNA 2-tRNA C U aa3 G G A U G A A C U A C U U C mRNA G A End Product • The end products of protein synthesis is a primary structure of a protein. • A sequence of amino acid bonded together by peptide bonds. aa5 aa2 aa1 aa3 aa4 aa199 aa200 Overview of Protein Synthesis Post Translational Modification and Regulation • Recognition of Signal Peptide • Glycosylation-addition of sugars to proteins destined to be membrane or secreted – “O” linked- serine/threonine in golgi – “N” linked - asparagine in ER • Proteolysis cleavage: Truncation • Disulfide bonds bridge • Attachment or binding of groups(NAD,Zn,Mg,FAD) • Folding • Assembly of multiple subunits • R -group modifications (see next slide) Modification of Protein Precursors R -Group Modifications • Phosphorylation (via kinase on -OH group of serine/threonine/ tyrosine) • Methylation • Acetylation (palmitylation C16 via thioester with cysteine, myristication C14 at amino-terminal glycine) • Isoprenation (farnesyl,guanosyl groups) • Hydroxylation Maturation of Human Pre-Pro-insulin • Pre-pro-protein – a protein precursor that contains a signal peptide sequence; it is a nonpolar sequence at the head of the growing polypeptide chain and contains many hydrophobic amino acids residues. – required for its transfer into the cistern of the endoplasmic reticulum; the signal sequence is then cleaved to form the protein or proprotein. Insulin Protein Precursors: Pro-Insulin • Pre-pro-sequence – About 30 non-polar aa guide the protein to be secreted out of cells or into different compartment of the cell sub-organells • Pro-sequences – areas in the protein that are essential for its correct folding – usually in the transition of a protein from an inactive to an active state. – Pro-sequences may also be involved in pro-protein transport and secretion Post Translational Modification of Insulin Clinical Usage of C peptide Measurement • Patients with diabetes may have their C-peptide levels measured as a means of distinguishing type 1 diabetes from type 2 diabetes or Maturity onset diabetes of the young (MODY). • Measuring C-peptide can help to determine how much of their own natural insulin a person is producing as C-peptide is secreted in equimolar amounts to insulin. • C-peptide levels are measured instead of insulin levels because C-peptide can assess a person's own insulin secretion even if they receive insulin injections, • Because the liver does not metabolize C-peptide, meaning blood C-peptide may be a better measure of portal insulin secretion than insulin itself. • A very low C-peptide confirms Type 1 diabetes and insulin dependence and is associated with high glucose variability, hyperglycaemia and increased complications. Genetic Codon Change Causes Mutation in Proteins • Point Mutations – No change-silent due to alteration in 3rd base of codon, wobble or degenerate base – Missense- change in base leads to change in aa – Nonsense-formation or modification of termination codon • Frameshift- insertion or deletion of a nucleotide Diseases Related to Mutations • a-thalassemia (Nonsense) – normally 142 aa long – If stop codon at 142 mutates get a 172 aa version including these variants: • • • • Constant Spring: glutamine @ 142 Icaria: lysine @ 142 Seal Roe: glutamate @ 142 Koya Dora: serine @ 142 • Thalassemia- Frameshift Mutation – Abnormal Hemoglobin Wayne- everything after 138 is incorrect (goes to 147 before stop) Inhibitors of Protein Synthesis • Streptomycin / Gentamycin: 30S prok. initiation • Erythromycin: Target 50S prok. Elongation, both Gram + and Gram bacteria • Chloramphenicol: 70S ribosomal subunit in prok, elongation, broad spectrum, bone marrow suppression • Cyclohexamide: 80S euk translocation step, and fungus etc • Tetracycline: Inhibits incoming tRNA to A site at 30S subunit in prokaryotes • Puromycin: Premature terminator both prok and euk, mimic tRNA binds at A site, resistant to hydrolysis • Diphtheria toxin: Euk elongation factor II inhibitor • Note: Use of prokaryotic antibiotics can effect mitochondrial eukaryotic RNA processes; may be dangerous Antibiotics Bind to Ribosome • The following antibiotics bind to the 30S subunit of the ribosome: – Aminoglycosides – Tetracyclines • The following antibiotics bind to the 50S ribosomal subunit: – Chloramphenicol – Erythromycin – Streptogramins- a group of cyclic peptide antibiotics that inhibit, like macrolides and lincosamides, the synthesis of bacterial proteins.
