Summary
The genetic code is evolving as shown by 9 departures from the universal code: 6 of them are in mitochondria and 3 are in nuclear codes. We propose that these changes are preceded by disappearance of a codon from coding sequences in mRNA of an organism or organelle. The function of the codon that disappears is taken by other, synonymous codons, so that there is no change in amino acid sequences of proteins. The deleted codon then reappears with a new function.
Wobble pairing between anticodons and codons has evolved, starting with a single UNN anticodon pairing with 4 codons. Directional mutation pressure affects codon usage and may produce codon reassignments, especially of stop codons. Selenocysteine is coded by UGA, which is also a stop codon, and this anomaly is discussed.
The outlook for discovery of more changes in the code is favorable, and open reading frames should be compared with actual sequential analyses of protein molecules in this search.
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References
Anfinsen, C. B., and Corley, L. G., An active variant of staphylococcal nuclease containing norleucine in place of methionine. J. biol. Chem.244 (1969) 5149–5152.
Attias, J., Schlesinger, J. J., and Schlesinger, S., The effect of amino acid analogues on alkaline phosphatase formation inEscherichia coli K-12. J. biol. Chem.244 (1969) 3810–3817.
Brown, C., Stockwell, P., Trotman, C., and Tate, W., The signal for the termination of protein synthesis in procaryotes. Nucleic Acids Res.18 (1990) 2079.
Cantatore, P., Roberti, M., Rainaldi, G., Gadaleta, M. N., and Saccone, C., The complete nucleotide sequence, gene organization, and genetic code of the mitochondrial genome ofParacentrotus lividus. J. biol. Chem.264 (1989) 10965–10975.
Covello, P. S., and Gray, M. W., RNA editing in plant mitochondria. Nature341 (1989) 662–666.
Crick, F. H. C., Codon-anticodon pairing: The wobble hypothesis. J. molec. Biol.19 (1966) 548–555.
Crick, F. H. C., The origin of the genetic code. J. molec. Biol.38 (1968) 367–379.
Dounce, A. L., Enzymologia15 (1952) 251.
Eck, R. V., Science140 (1963) 477.
Forchhammer, K., Leinfelder, W., and Böck, A., Identification of a novel translation factor necessary for the incorporation of selenocysteine into protein. Nature342 (1989) 453–456.
Ghersa, P., Shrivastava, I., Perrin, L., Dobeli, H., Becherer, D., Matile, H., Meier, B., and Certa, U., Initiation of translation at a UAG stop codon in the aldolase gene ofPlasmodium falciparum. EMBO J.9 (1990) 1645–1649.
Gualberto, J. M., Lamattina, L., Bonnard, G., Weil, J-H., and Grienenberger, J-M., RNA editing in wheat mitochondria results in the conservation of protein sequences. Nature341 (1989) 660–662.
Gualberto, J. M., Weil, J., and Grienenberger, J., Editing of the wheat COXIII transcript: evidence for twelve C to U and one U to C conversions and for sequence similarities around editing sites. Nucleic Acids Res.18 (1990) 3771–3773.
Hanyu, N., Kuchino, Y., Nishimura, S., and Beier, H., Dramatic events in ciliate evolution: Alteration of UAA and UAG termination codons to glutamine codons due to anticodon mutations in twoTetrahymea tRNAs Gln. EMBO J.5 (1986) 1307–1311.
Hartmanis, M. G. N., and Stadtman, T. C., Isolation of a selenium-containing thiolase fromClostridium kluyveri: identification of the selenium moiety as selenomethionine. Proc. natl Acad. Sci. USA79 (1982) 4912–4916.
Heckman, J. E., Sarnoff, J., Alzner-de Weerd, B., Yin, S., and Raj Bhandary, U. L., Novel features in the genetic code and codon reading patterns inNeurospora crassa mitochondria based on sequences of six mitochondrial tRNAs. Proc. natl Acad. Sci. USA77 (1980) 3159–3163.
Hiesel, R., Wissinger, B., Schuster, W., and Brennicke, A., RNA editing in plant mitochondria. Science246 (1989) 1632–1634.
Jacobs, H. T., Elliot, D., Math, V. V., and Farquharson, A., Nucleotide sequence and gene organization of sea urchin mitochondrial DNA. J. molec. Biol.202 (1988) 185–217.
Jukes, T. H., Coding triplets and their possible evolutionary implications. Biochem. biophys. Res. Commun.19 (1965) 391–396.
Jukes, T. H., Molecules and Evolution, p. 284. Columbia University Press, New York 1966.
Jukes, T. H., Possibilities for the evolution of the genetic code from a preceding form. Nature246 (1973) 22–26.
Jukes, T. H., Osawa, S., and Muto, A., Divergence and directional mutation pressures. Nature325 (1987) 668.
Jungck, J. R., The genetic code as a periodic table. J. molec. Evol.11 (1978) 211–224.
Kawaguchi, Y., Honda, H., Taniguchi-Morimura, J., and Iwasaki, S., The codon CUG is read as serine in an asporogenic yeastCandida cylindracea. Nature341 (1989) 164–166.
Kohno, T., Kohda, D., Haruki, M., Yokoyama, S., and Miyazawa, T., Nonprotein amino acid furanomycin, unlike isoleucine in chemical structure, is charged to isoleucine tRNA by isoleucyl-tRNA synthetase and incorporated into protein. J. biol. Chem.265 (1990) 6931–6935.
Koide, H., Yokoyama, S., Kawai, G., Ha, J-M., Oka, T., Kawai, S., Miyake, T., Fuwa, T., and Miyazawa, T., Biosynthesis of a protein containing a nonprotein amino acid byEscherichia coli: L-2-aminohexanoic acid at position 21 in human epidermal growth factor. Proc. natl Acad. Sci. USA85 (1988) 6237–6241.
Leinfelder, W., Zehelein, E., Mandrand-Berthelot, M-A., and Böck, A., Gene for a novel tRNA species that accepts L-serine and cotranslationally inserts selenocysteine. Nature331 (1988) 723–725.
Muramatsu, T., Yokoyama, S., Hirose, N., Matsuda, A., Ueda, T., Yamaizumi, Z., Kuchino, Y., Nishimura, S. and Miyazawa, T., A novel lysine-substituted nucleotide in the first position of the anticodon of amino isoleucine tRNA fromEscherichia coli. J. biol. Chem.263 (1988) 9261–9267.
National Research Council, Chapt. 5, Biological Effects, in: Selenium, pp. 51–133. National Academy of Sciences, 1976.
Ohama, T., Osawa, S., Watanabe, K., and Jukes, T. H., Evolution of the mitochondrial genetic code IV. AAA as an asparagine codon in some animal mitochondria. J. molec. Evol.30 (1990) 329–332.
Osawa, S., and Jukes, T. H., Evolution of the genetic code as affected by anticodon content. Trends Genet.4 (1988) 191–198.
Osawa, S., Ohama, T., Jukes, T. H., and Watanabe, K., Evolution of the mitochondrial genetic code I. Origin of AGR serine and stop codons in metazoan mitochondria. J. molec. Evol.29 (1989) 202–207.
Osawa, S., and Jukes, T. H., Codon reassignment (codon capture) in evolution. J. molec. Evol.28 (1989) 271–278.
Osawa, S., Collins, D., Ohama, T., Jukes, T. H., and Watanabe, K., Evolution of the mitochondrial genetic code III. Reassignment of CUN codons from leucine to threonine during evolution of yeast mitochondria. J. molec. Evol.30 (1990) 322–328.
Pines, M., Rosenthal, G. A., and Applebaum, S. W., In vitro incorporation of L-canavanine into vitellogenin of the fat body of the migratory locustLocusta migratoria migratorioides. Proc. natl Acad. Sci. USA78 (1981) 5480–5483.
Roberts, R. B., Further implications of the doublet code. Biochemistry48 (1962) 1245–1250.
Schneider, S. U., Leible, M. B., and Yang, X-P., Strong homology between the small subunit of ribulose-1,5-biphosphate carboxylase/oxygenase of two species ofAcetabularia and the occurrence of unusual codon usage. Molec. gen. Genet.218 (1989) 445–452.
Schuster, W., Unseld, M., Wissinger, B., and Brennicke, A., Ribosomal protein S14 transcripts are edited inOenothera mitochondria. Nucl. Acids Res.18 (1990).
Schuster, W., Wissinger, B., Unseld, M., and Brennicke, A., Transcripts of the NADH-dehydrogenase subunit 3 gene are differentially edited inOenothera mitochondria. EMBO J.9 (1990) 263–269.
Schuster, W., Hiesel, R., Wissinger, B., and Brennicke, A., RNA editing in the cytochromeb locus of the higher plantOenothera berteriana includes a U-to-C transition. Molec. cell. Biol.10 (1990) 2428–2431.
Smith, E. L., Nucleotide base coding and amino acid replacements in proteins. Biochemistry48 (1962) 677–684.
Söll, D., Enter a new amino acid. Nature331 (1988) 662–663.
Sprinzl, M., Hartmann, T., Weber, J., Blank, J., and Zeidler, R., Compilation of tRNA sequences and sequences of tRNA genes. Nucl. Acids Res., Suppl. to vol.17 (1989) 1–173.
Stadtman, T. C., Specific occurrence of selenium in enzymes and amino acid tRNAs. FASEB J.1 (1987) 375–379.
Varshney, U., and RajBhandary, U., Initiation of protein synthesis from a termination codon. Proc. natl Acad. Sci. USA87 (1990) 1586–1590.
Wong, J. T-F., The evolution of a universal genetic code. Proc. natl Acad. Sci. USA73 (1976) 2336–2340.
Wong, J. T-F., Evolution of the genetic code. Microbiol. Sci.5 (1988) 174–181.
Yamao, F., Iwagami, S., Azumi, Y., Muto, A., and Osawa, S., Evolutionary dynamics of tryptophan tRNAs inMycoplasma capricolum. Molec. gen. Genet.212 (1988) 364–369.
Yokoyama, S., Watanabe, T., Murao, K., Ishikura, H., Yamaizumi, Z., Nishimura, S., and Miyazawa, T., Molecular mechanism of codon recognition by tRNAs with modified uridine in the first position of the anticodon. Proc. natl Acad. Sci. USA82 (1985) 4905–4909.
Zinoni, F., Birkmann, A., Leinfelder, W., and Böck, A., Cotranslational insertion of selenocysteine into formate dehydrogenase fromEscherichia coli directed by a UGA codon. Proc. natl Acad. Sci. USA84 (1987) 3156–3160.
Zinoni, F., Heider, J., and Böck, A., Features of the formate-dehydrogenase mRNA necessary for decoding of the UGA codon as cysteine. Proc. natl Acad. Sci. USA87 (1990) 4660–4664.
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Jukes, T.H. Genetic code 1990. Outlook. Experientia 46, 1149–1157 (1990). https://doi.org/10.1007/BF01936925
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DOI: https://doi.org/10.1007/BF01936925