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Literature cited Accetturo, M., T. M. Creanza, C. Santoro, G. Tria, A. Giordano, S. Battagliero, A. Vaccina et al. 2010. Finding new genes for non-syndromic hearing loss through an in silico prioritization study. PLoS ONE 5:e12742. Adzhubei, I. A., S. Schmidt, L. Peshkin, V. E. Ramensky, A. Gerasimova, P. Bork, A. S. Kondrashov et al. 2010. A method and server for predicting damaging missense mutations. Nature Methods 7:248–249. Altschul, S. F., T. L. Madden, A. A. Schaffer, J. Zhang, Z. Zhang, W. Miller, and D. J. Lipman 1997. Gapped BLAST and PSI-BLAST: a new generation of protein database search programs. Nucleic Acids Research 25:3389–3402. Anisimova, M., and Z. H. Yang 2007. Multiple hypothesis testing to detect lineages under positive selection that affects only a few sites. Molecular Biology and Evolution 24:1219–1228. Bekaert, M., and E. C. Teeling 2008. UniPrime: a workflow-based platform for improved universal primer design. Nucleic Acids Research 36:e56. Belyantseva, I. A., E. T. Boger, S. Naz, G. I. Frolenkov, J. R. Sellers, Z. M. Ahmed, A. J. Griffith et al. 2005. Myosin-XVa is required for tip localization of whirlin and differential elongation of hair-cell stereocilia. Nature Cell Biology 7:148–156. Benjamini, Y., and Y. Hochberg 1995. Controlling the false discovery rate – a practical and powerful approach to multiple testing. Journal of the Royal Statistical Society Series B- Methodological 57:289–300. Brown, S. D. M., R. E. Hardisty-Hughes, and P. Mburu 2008. Quiet as a mouse: dissecting the molecular and genetic basis of hearing. Nature Reviews Genetics 9:277–290. Burk-Herrick, A., M. Scally, H. Amrine-Madsen, M. J. Stanhope, and M. S. Springer 2006. Natural selection and mammalian BRCA1 sequences: elucidating functionally important sites relevant to breast cancer susceptibility in humans. Mammalian Genome 17:257–270. Cooper, G. M., and J. Shendure 2011. Needles in stacks of needles: finding disease-causal variants in a wealth of genomic data. Nature Reviews Genetics 12:628–640. Davies, K. T., J. A. Cotton, J. D. Kirwan, E. C. Teeling, and S. J. Rossiter 2011. Parallel signatures of sequence evolution among hearing genes in echolocating mammals: an emerging model of genetic convergence. Heredity (Edinb) 108:480–489. Delprat, B., V. Michel, R. Goodyear, Y. Yamasaki, N. Michalski, A. El-Amraoui, I. Perfettini et al. 2005. Myosin XVa and whirlin, two deafness gene products required for hair bundle growth, are located at the stereocilia tips and interact directly. Human Molecular Genetics 14:401–410. Dror, A. A., and K. B. Avraham 2010. Hearing impairment: a panoply of genes and functions. Neuron 68:293–308. Dudley, J. T., Y. Kim, L. Liu, G. J. Markov, K. Gerold, R. Chen, A. J. Butte et al. 2012. Human genomic disease variants: a neutral evolutionary explanation. Genome Research 22:1383–1394. Fettiplace, R., and C. M. Hackney 2006. The sensory and motor roles of auditory hair cells. Nature Reviews Neuroscience 7:19–29. Genome 10K Community of Scientists 2009. Genome 10K: a proposal to obtain whole-genome sequence for 10 000 vertebrate species. Journal of Heredity 100:659–674. Horowitz, S 2012. The Universal Sense: How Hearing Shapes the Mind. Bloomsbury Publishing, Bloomsbury, USA. Hubbard, T. J. P., B. L. Aken, S. Ayling, B. Ballester, K. Beal, E. Bragin, S. Brent et al. 2009. Ensembl 2009. Nucleic Acids Research 37:D690–D697. Kumar, S., M. Nei, J. Dudley, and K. Tamura 2008. MEGA: a biologist-centric software for evolutionary analysis of DNA and protein sequences. Briefings in Bioinformatics 9:299–306. Kumar, P., S. Henikoff, and P. C. Ng 2009. Predicting the effects of coding non-synonymous variants on protein function using the SIFT algorithm. Nature Protocols 4:1073–1082. Kumar, S., J. T. Dudley, A. Filipski, and L. Liu 2011. Phylomedicine: an evolutionary telescope to explore and diagnose the universe of disease mutations. Trends in Genetics 27:377–386. Kumar, S., M. Sanderford, V. E. Gray, J. P. Ye, and L. Liu 2012. Evolutionary diagnosis method for variants in personal exomes. Nature Methods 9:855–856. Larkin, M. A., G. Blackshields, N. P. Brown, R. Chenna, P. A. McGettigan, H. McWilliam, F. Valentin et al. 2007. Clustal W and Clustal X version 2.0. Bioinformatics 23:2947–2948. Lenz, D. R., and K. B. Avraham 2011. Hereditary hearing loss: from human mutation to mechanism. Hearing Research 281:3–10. Li, G., J. Wang, S. J. Rossiter, G. Jones, J. A. Cotton, and S. Zhang 2008. The hearing gene Prestin reunites echolocating bats. Proceedings of the National Academy of Sciences of the United States of America 105:13959–13964. Li, Y., Z. Liu, P. Shi, and J. Zhang. 2010. The hearing gene Prestin unites echolocating bats and whales. Current Biology 20:R55–R56. Liu, Y., J. A. Cotton, B. Shen, X. Han, S. J. Rossiter, and S. Zhang. 2010a. Convergent sequence evolution between echolocating bats and dolphins. Current Biology 20:R53–R54. Liu, Y., S. J. Rossiter, X. Han, J. A. Cotton, and S. Zhang. 2010b. Cetaceans on a molecular fast track to ultrasonic hearing. Current Biology 20:1834–1839. Liu, Z., S. Li, W. Wang, D. Xu, R. W. Murphy, and P. Shi 2011. Parallel evolution of KCNQ4 in echolocating bats. PLoS ONE 6:e26618. Liu, Y., N. Han, L. F. Franchini, H. Xu, F. Pisciottano, A. B. Elgoyhen, K. E. Rajan et al. 2012. The voltage-gated potassium channel subfamily KQT member 4 (KCNQ4) displays parallel evolution in echolocating bats. Molecular Biology and Evolution 29:1441–1450. MacDonald, D. 2009. The Encyclopedia of Mammals, 2nd ed. Oxford: Oxford University Press, England, UK. Magrane, M., and U. Consortium 2011. UniProt Knowledgebase: a hub of integrated protein data. Database (Oxford) 2011:bar009. Meredith, R. W., J. E. Janecka, J. Gatesy, O. A. Ryder, C. A. Fisher, E. C. Teeling, A. Goodbla et al. 2011. Impacts of the cretaceous terrestrial revolution and KPg extinction on mammal diversification. Science 334:521–524. Murrell, B., J. O. Wertheim, S. Moola, T. Weighill, K. Scheffler, and S.L.K. Pond 2012. Detecting individual sites subject to episodic diversifying selection. PLoS Genetics 8:e1002764. Nal, N., Z. M. Ahmed, E. Erkal, O. M. Alper, G. Luleci, O. Dinc, A. M. Waryah et al. 2007. Mutational spectrum of MYO15A: the large N-terminal extension of myosin XVA is required for hearing. Human Mutation 28:1014–1019. Raviv, D., A. A. Dror, and K. B. Avraham 2010. Hearing loss: a common disorder caused by many rare alleles. Annals of the New York Academy of Sciences 1214:168–179. Reva, B., Y. Antipin, and C. Sander 2011. Predicting the functional impact of protein mutations: application to cancer genomics. Nucleic Acids Research 39:e118. Rozen, S., and H. Skaletsky 2000. Primer3 on the WWW for general users and for biologist programmers. Methods in Molecular Biology 132:365–386. Shen, Y. Y., L. Liang, G. S. Li, R. W. Murphy, and Y. P. Zhang 2012. Parallel evolution of auditory genes for echolocation in bats and toothed whales. PLoS Genetics 8:e1002788. Simmler, M. C., M. Cohen-Salmon, A. El-Amraoui, L. Guillaud, J. C. Benichou, C. Petit, and J. J. Panthier 2000. Targeted disruption of otog results in deafness and severe imbalance. Nature Genetics 24:139–143. Stamatakis, A. 2006. RAxML-VI-HPC: maximum likelihood-based phylogenetic analyses with thousands of taxa and mixed models. Bioinformatics 22:2688–2690. Stamatakis, A., P. Hoover, and J. Rougemont 2008. A rapid bootstrap algorithm for the RAxML Web servers. Systematic Biology 57:758–771. Steel, K. P. 2000. A take on the tectorial membrane. Nature Genetics 24:104. Swanson, W. J., R. Nielsen, and Q. F. Yang 2003. Pervasive adaptive evolution in mammalian fertilization proteins. Molecular Biology and Evolution 20:18–20. Teeling, E. C., M. S. Springer, O. Madsen, P. Bates, S. J. O'Brien, and W. J. Murphy 2005. A molecular phylogeny for bats illuminates biogeography and the fossil record. Science 307:580–584. Teeling, E. C. 2009. Hear, hear: the convergent evolution of echolocation in bats? Trends in Ecology & Evolution 24:351–354. Teeling, E. C., S. Dool, and M. S. Springer. 2012. Phylogenies, fossils and functional genes: The evolution of echolocation in bats. In G. F. Gunnell, and N. B. Simmons, eds. Evolutionary History of Bats: Fossils, Molecules, and Morphology, pp. 1–21, Cambridge University Press, Cambridge. Yan, D., and X. Z. Liu 2010. Genetics and pathological mechanisms of Usher syndrome. Journal of Human Genetics 55:327–335. Yang, Z. H. 1998. Likelihood ratio tests for detecting positive selection and application to primate lysozyme evolution. Molecular Biology and Evolution 15:568–573. Yang, Z. H. 2007. PAML 4: phylogenetic analysis by maximum likelihood. Molecular Biology and Evolution 24:1586–1591. Yang, Z. H., W. S. W. Wong, and R. Nielsen 2005. Bayes empirical Bayes inference of amino acid sites under positive selection. Molecular Biology and Evolution 22:1107–1118. Zhang, J. Z., R. Nielsen, and Z. H. Yang 2005. Evaluation of an improved branch-site likelihood method for detecting positive selection at the molecular level. Molecular Biology and Evolution 22:2472–2479.

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Abstract

Hereditary deafness affects 0.1% of individuals globally and is considered as one of the most debilitating diseases of man. Despite recent advances, the molecular basis of normal auditory function is not fully understood and little is known about the contribution of single-nucleotide variations to the disease. Using cross-species comparisons of 11 ‘deafness’ genes (Myo15, Ush1 g, Strc, Tecta, Tectb, Otog, Col11a2, Gjb2, Cldn14, Kcnq4, Pou3f4) across 69 evolutionary and ecologically divergent mammals, we elucidated whether there was evidence for: (i) adaptive evolution acting on these genes across mammals with similar hearing capabilities; and, (ii) regions of long-term evolutionary conservation within which we predict disease-associated mutations should occur. We find evidence of adaptive evolution acting on the eutherian mammals in Myo15, Otog and Tecta. Examination of selection pressures in Tecta and Pou3f4 across a taxonomic sample that included a wide representation of auditory specialists, the bats, did not uncover any evidence for a role in echolocation. We generated ‘conservation indices’ based on selection estimates at nucleotide sites and found that known disease mutations fall within sites of high evolutionary conservation. We suggest that methods such as this, derived from estimates of evolutionary conservation using phylogenetically divergent taxa, will help to differentiate between deleterious and benign mutations.

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Title

A phylomedicine approach to understanding the evolution of auditory sensory perception and disease in mammals

Author

Kirwan, John D¹; Bekaert, Michaël²; Commins, Jennifer M¹; Davies, Kalina T J³; Rossiter, Stephen J³; Teeling, Emma C¹

¹ UCD School of Biology and Environmental Science & UCD Conway Institute of Biomolecular and Biomedical Research, University College Dublin, Dublin, Ireland
² Institute of Aquaculture, University of Stirling, Scotland, UK
³ School of Biological and Chemical Sciences, Queen Mary University of London, London, UK

Pages

412-422

Section

Phylomedicine

Publication year

2013

Publication date

Apr 2013

Publisher

John Wiley & Sons, Inc.

e-ISSN

17524571

Source type

Scholarly Journal

Language of publication

English

DOI

https://doi.org/10.1111/eva.12047

ProQuest document ID

2290361555

A phylomedicine approach to understanding the evolution of auditory sensory perception and disease in mammals

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