The structural basis of molecular adaptation.

The study of molecular adaptation has long been fraught with difficulties, not the least of which is identifying out of hundreds of amino acid replacements those few directly responsible for major adaptations. Six studies are used to illustrate how phylogenies, site-directed mutagenesis, and a knowledge of protein structure combine to provide much deeper insights into the adaptive process than has hitherto been possible. Ancient genes can be reconstructed, and the phenotypes can be compared to modern proteins. Out of hundreds of amino acid replacements accumulated over billions of years those few responsible for discriminating between alternative substrates are identified. An amino acid replacement of modest effect at the molecular level causes a dramatic expansion in an ecological niche. These and other topics are creating the emerging field of "paleomolecular biochemistry."

[1]  T. Jukes,et al.  The neutral theory of molecular evolution. , 2000, Genetics.

[2]  J. Oakeshott,et al.  A single amino acid substitution converts a carboxylesterase to an organophosphorus hydrolase and confers insecticide resistance on a blowfly. , 1997, Proceedings of the National Academy of Sciences of the United States of America.

[3]  M. Nei,et al.  Color vision of ancestral organisms of higher primates. , 1997, Molecular biology and evolution.

[4]  A. Dean,et al.  Protein engineering reveals ancient adaptive replacements in isocitrate dehydrogenase. , 1997, Proceedings of the National Academy of Sciences of the United States of America.

[5]  S. Yokoyama,et al.  Molecular genetic basis of adaptive selection: examples from color vision in vertebrates. , 1997, Annual review of genetics.

[6]  A. Dean,et al.  Redesigning secondary structure to invert coenzyme specificity in isopropylmalate dehydrogenase. , 1996, Proceedings of the National Academy of Sciences of the United States of America.

[7]  Jay Neitz,et al.  Trichromatic colour vision in New World monkeys , 1996, Nature.

[8]  J. Hurley,et al.  Determinants of cofactor specificity in isocitrate dehydrogenase: structure of an engineered NADP+ --> NAD+ specificity-reversal mutant. , 1996, Biochemistry.

[9]  B. Synstad,et al.  Malate dehydrogenase from the green gliding bacterium Chloroflexus aurantiacus is phylogenetically related to lactic dehydrogenases , 1996, Archives of Microbiology.

[10]  S. Benner,et al.  Pseudogenes in ribonuclease evolution: a source of new biomacromolecular function? , 1996, FEBS letters.

[11]  S. Benner,et al.  Developing new synthetic catalysts. How nature does it. , 1996, Acta chemica Scandinavica.

[12]  S. Karnik,et al.  Angiotensin II-Forming Activity in a Reconstructed Ancestral Chymase , 1996, Science.

[13]  G. Lu,et al.  The crystal structure of a high oxygen affinity species of haemoglobin (bar-headed goose haemoglobin in the oxy form). , 1996, Journal of molecular biology.

[14]  B. Hall,et al.  Catalytic consequences of experimental evolution: catalysis by a 'third-generation' evolvant of the second beta-galactosidase of Escherichia coli, ebgabcde, and by ebgabcd, a 'second-generation' evolvant containing two supposedly 'kinetically silent' mutations. , 1995, The Biochemical journal.

[15]  A. Dean,et al.  A highly active decarboxylating dehydrogenase with rationally inverted coenzyme specificity. , 1995, Proceedings of the National Academy of Sciences of the United States of America.

[16]  C. S. Millard,et al.  Stringency of substrate specificity of Escherichia coli malate dehydrogenase. , 1995, Archives of biochemistry and biophysics.

[17]  J. Mollon,et al.  Adaptive evolution of color vision genes in higher primates , 1995, Science.

[18]  S. Yokoyama,et al.  Rhodopsin from the fish, Astyanax: role of tyrosine 261 in the red shift. , 1995, Investigative ophthalmology & visual science.

[19]  Steven A. Benner,et al.  Reconstructing the evolutionary history of the artiodactyl ribonuclease superfamily , 1995, Nature.

[20]  A. Dean A molecular investigation of genotype by environment interactions. , 1995, Genetics.

[21]  B. Golding Non-Neutral Evolution: Theories And Molecular Data , 1994 .

[22]  J. Thompson,et al.  CLUSTAL W: improving the sensitivity of progressive multiple sequence alignment through sequence weighting, position-specific gap penalties and weight matrix choice. , 1994, Nucleic acids research.

[23]  J. Hurley,et al.  Structure of 3-isopropylmalate dehydrogenase in complex with NAD+: ligand-induced loop closing and mechanism for cofactor specificity. , 1994, Structure.

[24]  R. Rosenzweig,et al.  Microbial evolution in a simple unstructured environment: genetic differentiation in Escherichia coli. , 1994, Genetics.

[25]  M. Castagnola,et al.  Hemoglobin function under extreme life conditions. , 1994, European journal of biochemistry.

[26]  D. Oprian,et al.  Molecular determinants of human red/green color discrimination , 1994, Neuron.

[27]  T. Atkinson,et al.  Substitution of the amino acid at position 102 with polar and aromatic residues influences substrate specificity of lactate dehydrogenase , 1994, Journal of protein chemistry.

[28]  J. Tame,et al.  Mutant hemoglobins (alpha 119-Ala and beta 55-Ser): functions related to high-altitude respiration in geese. , 1993, Journal of applied physiology.

[29]  H. Eisenberg,et al.  Cloning, sequencing, and expression in Escherichia coli of the gene coding for malate dehydrogenase of the extremely halophilic archaebacterium Haloarcula marismortui. , 1993, Biochemistry.

[30]  H. Wilks,et al.  Opportunities and limits in creating new enzymes. Experiences with the NAD-dependent lactate dehydrogenase frameworks of humans and bacteria. , 1992, Annals of the New York Academy of Sciences.

[31]  J. Holbrook,et al.  Opportunities and Limits in Creating New Enzymes , 1992 .

[32]  J. Mollon,et al.  Dichromats detect colour-camouflaged objects that are not detected by trichromats , 1992, Proceedings of the Royal Society of London. Series B: Biological Sciences.

[33]  T. Sakmar,et al.  Introduction of hydroxyl-bearing amino acids causes bathochromic spectral shifts in rhodopsin. Amino acid substitutions responsible for red-green color pigment spectral tuning. , 1992, The Journal of biological chemistry.

[34]  政美 長谷川,et al.  Molphy, programs for molecular phylogenetics, I : protml, maximum likelihood inference of protein phylogeny , 1992 .

[35]  J. Adachi,et al.  MOLPHY, programs for molecular phylogenetics , 1992 .

[36]  D. Koshland,et al.  Catalytic mechanism of NADP(+)-dependent isocitrate dehydrogenase: implications from the structures of magnesium-isocitrate and NADP+ complexes. , 1991, Biochemistry.

[37]  J. Tame,et al.  Adaptation of bird hemoglobins to high altitudes: demonstration of molecular mechanism by protein engineering. , 1991, Proceedings of the National Academy of Sciences of the United States of America.

[38]  G H Jacobs,et al.  Spectral tuning of pigments underlying red-green color vision. , 1991, Science.

[39]  W. B. Watt Biochemistry, Physiological Ecology, and Population Genetics-the Mechanistic Tools of Evolutionary Biology , 1991 .

[40]  D. Crawford,et al.  Genetic mechanisms for adapting to a changing environment. , 1991, Annual review of genetics.

[41]  S. Yokoyama,et al.  Convergent evolution of the red- and green-like visual pigment genes in fish, Astyanax fasciatus, and human. , 1990, Proceedings of the National Academy of Sciences of the United States of America.

[42]  R. Weber,et al.  High-altitude respiration of falconiformes. The primary structures and functional properties of the major and minor hemoglobin components of the adult White-Headed Vulture (Trigonoceps occipitalis, Aegypiinae). , 1989, Biological chemistry Hoppe-Seyler.

[43]  H. Muirhead,et al.  A specific, highly active malate dehydrogenase by redesign of a lactate dehydrogenase framework. , 1988, Science.

[44]  L. McAlister-Henn,et al.  Evolutionary relationships among the malate dehydrogenases. , 1988, Trends in biochemical sciences.

[45]  R. Weber,et al.  Structural Adaptations in the Major and Minor Hemoglobin Components of adult RiippeU's Griffon (Gyps rueppellii, Aegypiinae): a New Molecular Pattern for Hypoxic Tolerance* , 1988 .

[46]  N. Saitou,et al.  The neighbor-joining method: a new method for reconstructing phylogenetic trees. , 1987, Molecular biology and evolution.

[47]  R. K. Koehn,et al.  The Adaptive Importance of Genetic Variation , 1987 .

[48]  J. Nathans,et al.  Molecular biology of visual pigments. , 1987, Annual review of neuroscience.

[49]  G. Braunitzer,et al.  High altitude respiration of birds. The primary structures of the major and minor hemoglobin component of adult European black vulture (Aegypius monachus, Aegypiinae). , 1987, Biological chemistry Hoppe-Seyler.

[50]  G. Braunitzer,et al.  The primary structures of the major and minor hemoglobin-components of adult Andean goose (Chloephaga melanoptera, Anatidae): the mutation Leu----Ser in position 55 of the beta-chains. , 1987, Biological chemistry Hoppe-Seyler.

[51]  W. Fitch,et al.  Molecular evolution of pancreatic-type ribonucleases. , 1986, Molecular biology and evolution.

[52]  D. Koshland,et al.  Branch point control by the phosphorylation state of isocitrate dehydrogenase. A quantitative examination of fluxes during a regulatory transition. , 1985, The Journal of biological chemistry.

[53]  J. Mollon,et al.  Variations of colour vision in a New World primate can be explained by polymorphism of retinal photopigments , 1984, Proceedings of the Royal Society of London. Series B. Biological Sciences.

[54]  R. Mortlock Microorganisms as Model Systems for Studying Evolution , 1984, Monographs in Evolutionary Biology.

[55]  M. Perutz Species adaptation in a protein molecule. , 1983, Molecular biology and evolution.

[56]  M. Kimura,et al.  The neutral theory of molecular evolution. , 1983, Scientific American.

[57]  M. Perutz,et al.  Structure and function of haemoglobin philly (Tyr C1 (35) β→Phe) , 1976 .