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2. 2 Discovering the codon bias

3. 3 Il codice genetico è DEGENERATO

4. 4 Because of the degeneracy of all genetic codes, 18-20 amino acids are encoded by more than one codon (2, 3, 4, or 6).

5. 5 If synonymous mutations are strictly neutral, they should be used randomly as dictated by genomic GC content.

6. 6 In the year 1980 Four researchers from Lyon analyzed ALL published mRNA sequences of more than about 50 codons. All together they analyzed 90 sequences…

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8. 8 In the paper they first list all the gene studied and they compute codon frequencies for various groups : Single strand RNA viruses Single strand DNA viruses Double strand DNA viruses Double strand (DS) bacteria DS mitochondria DS yeast DS animals IgG’s.

9. 9 They project each sequence on 2D, so that sequences with similar codon composition appear near each other. Correspondence analysis

10. 10 Mostly animals & bacteriaMostly viruses

11. 11 Papova virus genes cluster together

12. 12 Ig genes cluster together

13. 13 Mammals genes that are not Ig cluster together

14. The genome hypothesis - All genes in a genome tend to have the same coding strategy. - That is, they employ the codon catalog similarly and show similar choices between synonymous codons. - Different taxa have different coding strategies. Richard Grantham An example: 21 of the 23 leucine residues in the E. coli outer membrane protein II (ompA) are encoded by the codon CUG, although 5 other codons for leucine are available.

15. 15 Universal and species-specific patterns of codon usage Universal patterns: CGACGG Codons that contain the CG dinucleotide are universally avoided ( low- usage codons ). This phenomenon is particularly notable as far as the arginine codons CGA and CGG are concerned. Two selective factors have been convincingly invoked to explain codon usage bias. (1)translation optimization (2) folding stability of the mRNA

16. 16 The translation efficiency of a codon is related to the relative quantity of tRNA molecules that recognize the particular codon.

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18. 18 One can locate “optimal” codons which are expected to be translated more efficiently than others. Motivation: We now want to define the “codon bias” of a specific gene, relative to the optimal codons…

19. 19 RSCU is the number of times a codon appears in a gene divided by the number of expected occurrences under equal codon usage. n = number of synonymous codons (1  n  6) for the amino acid under study, X i = number of occurrences of codon i. Measures of codon-usage bias The relative synonymous codon usage ( RSCU ) was first suggested by Sharp et al. (1986). If the synonymous codons of an amino acid are used with equal frequencies, their RSCU values will equal 1.

20. 20 Gouy and Gautier (1982) and Bennetzen and Hall (1982) found positive correlation between degree of codon bias and level of gene expression.

21. 21 The CAI index ranges from zero to one being one if a gene always uses, for each encoded amino acid, the most frequently used synonymous codon in the reference set. Codon Adaptation Index (CAI) Codon Adaptation Index (CAI) Codon adaptation index is a measurement of the relative adaptiveness of the codon usage of a gene towards the codon usage of highly expressed genes The CAI index is defined as the geometric mean of these relative adaptiveness values.

22. 22 Toshimishi Ikemura Codon Usage is related to Translation Efficiency

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