Toward reconstructing the evolution of advanced moths and butterflies (Lepidoptera: Ditrysia): An initial molecular study

Jerome C. Regier; Andreas Zwick; Michael P. Cummings; Akito Y. Kawahara; Soowon Cho; Susan Weller; Amanda Roe; Joaquin Baixeras; John W. Brown; Cynthia Parr; Donald R. Davis; Marc Epstein; Winifred Hallwachs; Axel Hausmann; Daniel H. Janzen; Ian J. Kitching; M. Alma Solis; Shen Horn Yen; Adam L. Bazinet; Charles Mitter

doi:10.1186/1471-2148-9-280

Toward reconstructing the evolution of advanced moths and butterflies (Lepidoptera: Ditrysia): An initial molecular study

Jerome C. Regier, Andreas Zwick, Michael P. Cummings, Akito Y. Kawahara, Soowon Cho, Susan Weller, Amanda Roe, Joaquin Baixeras, John W. Brown, Cynthia Parr, Donald R. Davis, Marc Epstein, Winifred Hallwachs, Axel Hausmann, Daniel H. Janzen, Ian J. Kitching, M. Alma Solis, Shen Horn Yen, Adam L. Bazinet, Charles Mitter

Bell Museum of Natural History

Research output: Contribution to journal › Article › peer-review

211 Scopus citations

Abstract

Abstract. Background. In the mega-diverse insect order Lepidoptera (butterflies and moths; 165,000 described species), deeper relationships are little understood within the clade Ditrysia, to which 98% of the species belong. To begin addressing this problem, we tested the ability of five protein-coding nuclear genes (6.7 kb total), and character subsets therein, to resolve relationships among 123 species representing 27 (of 33) superfamilies and 55 (of 100) families of Ditrysia under maximum likelihood analysis. Results. Our trees show broad concordance with previous morphological hypotheses of ditrysian phylogeny, although most relationships among superfamilies are weakly supported. There are also notable surprises, such as a consistently closer relationship of Pyraloidea than of butterflies to most Macrolepidoptera. Monophyly is significantly rejected by one or more character sets for the putative clades Macrolepidoptera as currently defined (P < 0.05) and Macrolepidoptera excluding Noctuoidea and Bombycoidea sensu lato (P 0.005), and nearly so for the superfamily Drepanoidea as currently defined (P < 0.08). Superfamilies are typically recovered or nearly so, but usually without strong support. Relationships within superfamilies and families, however, are often robustly resolved. We provide some of the first strong molecular evidence on deeper splits within Pyraloidea, Tortricoidea, Geometroidea, Noctuoidea and others. Separate analyses of mostly synonymous versus non-synonymous character sets revealed notable differences (though not strong conflict), including a marked influence of compositional heterogeneity on apparent signal in the third codon position (nt3). As available model partitioning methods cannot correct for this variation, we assessed overall phylogeny resolution through separate examination of trees from each character set. Exploration of "tree space" with GARLI, using grid computing, showed that hundreds of searches are typically needed to find the best-feasible phylogeny estimate for these data. Conclusion. Our results (a) corroborate the broad outlines of the current working phylogenetic hypothesis for Ditrysia, (b) demonstrate that some prominent features of that hypothesis, including the position of the butterflies, need revision, and (c) resolve the majority of family and subfamily relationships within superfamilies as thus far sampled. Much further gene and taxon sampling will be needed, however, to strongly resolve individual deeper nodes.

Original language	English (US)
Article number	280
Journal	BMC evolutionary biology
Volume	9
Issue number	1
DOIs	https://doi.org/10.1186/1471-2148-9-280
State	Published - 2009

Bibliographical note

Funding Information:
We are greatly indebted to generous colleagues for supplying specimens for this study, including J. K. Adams, D. Adamski, K. Nishida, V. Becker, N. Bloomfield, T. Burbidge, J. Farr, G. Clarke, R. F. Denno, E. Edwards, M. Fibiger, T. Friedlander, J. Giebultowicz, R.J.B. Hoare, K. R. Horst, R. Hutch-ings, N. Hyde'n, W. Kelly, R. LeClerc, M. J. Matthews, N. McFarland, D. Messersmith, A. Mitchell, R. Poole, K.-T. Park, J. O. Nelson, E. S. Nielsen, R.S. Peigler, K. Pullen, R. Robertson, G. Tremewan, A. Venables, A. Willis, and K. Wolfe. Suwei Zhao and Kongyi Jiang provided technical assistance, and K. Mitter made essential contributions as specimen collection and database manager. We are grateful to M. Mutanen, L. Kaila, N. Wahlberg for permission to cite their work in progress. We thank D. Sean Brady, Sonja Scheffer and the five anonymous reviewers for helpful comments on the manuscript. Financial support was provided by the U.S. National Science Foundation's Assembling the Tree of Life program, award numbers 0531626 and 0531769, and by NSF grants BSR 9024770 and DEB 9306296, 9400829, 9705072, 0072730, and 0515699 to DHJ.

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Regier, J. C., Zwick, A., Cummings, M. P., Kawahara, A. Y., Cho, S., Weller, S., Roe, A., Baixeras, J., Brown, J. W., Parr, C., Davis, D. R., Epstein, M., Hallwachs, W., Hausmann, A., Janzen, D. H., Kitching, I. J., Solis, M. A., Yen, S. H., Bazinet, A. L., & Mitter, C. (2009). Toward reconstructing the evolution of advanced moths and butterflies (Lepidoptera: Ditrysia): An initial molecular study. BMC evolutionary biology, 9(1), Article 280. https://doi.org/10.1186/1471-2148-9-280

Regier, JC, Zwick, A, Cummings, MP, Kawahara, AY, Cho, S, Weller, S, Roe, A, Baixeras, J, Brown, JW, Parr, C, Davis, DR, Epstein, M, Hallwachs, W, Hausmann, A, Janzen, DH, Kitching, IJ, Solis, MA, Yen, SH, Bazinet, AL & Mitter, C 2009, 'Toward reconstructing the evolution of advanced moths and butterflies (Lepidoptera: Ditrysia): An initial molecular study', BMC evolutionary biology, vol. 9, no. 1, 280. https://doi.org/10.1186/1471-2148-9-280

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abstract = "Abstract. Background. In the mega-diverse insect order Lepidoptera (butterflies and moths; 165,000 described species), deeper relationships are little understood within the clade Ditrysia, to which 98% of the species belong. To begin addressing this problem, we tested the ability of five protein-coding nuclear genes (6.7 kb total), and character subsets therein, to resolve relationships among 123 species representing 27 (of 33) superfamilies and 55 (of 100) families of Ditrysia under maximum likelihood analysis. Results. Our trees show broad concordance with previous morphological hypotheses of ditrysian phylogeny, although most relationships among superfamilies are weakly supported. There are also notable surprises, such as a consistently closer relationship of Pyraloidea than of butterflies to most Macrolepidoptera. Monophyly is significantly rejected by one or more character sets for the putative clades Macrolepidoptera as currently defined (P < 0.05) and Macrolepidoptera excluding Noctuoidea and Bombycoidea sensu lato (P 0.005), and nearly so for the superfamily Drepanoidea as currently defined (P < 0.08). Superfamilies are typically recovered or nearly so, but usually without strong support. Relationships within superfamilies and families, however, are often robustly resolved. We provide some of the first strong molecular evidence on deeper splits within Pyraloidea, Tortricoidea, Geometroidea, Noctuoidea and others. Separate analyses of mostly synonymous versus non-synonymous character sets revealed notable differences (though not strong conflict), including a marked influence of compositional heterogeneity on apparent signal in the third codon position (nt3). As available model partitioning methods cannot correct for this variation, we assessed overall phylogeny resolution through separate examination of trees from each character set. Exploration of {"}tree space{"} with GARLI, using grid computing, showed that hundreds of searches are typically needed to find the best-feasible phylogeny estimate for these data. Conclusion. Our results (a) corroborate the broad outlines of the current working phylogenetic hypothesis for Ditrysia, (b) demonstrate that some prominent features of that hypothesis, including the position of the butterflies, need revision, and (c) resolve the majority of family and subfamily relationships within superfamilies as thus far sampled. Much further gene and taxon sampling will be needed, however, to strongly resolve individual deeper nodes.",

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note = "Funding Information: We are greatly indebted to generous colleagues for supplying specimens for this study, including J. K. Adams, D. Adamski, K. Nishida, V. Becker, N. Bloomfield, T. Burbidge, J. Farr, G. Clarke, R. F. Denno, E. Edwards, M. Fibiger, T. Friedlander, J. Giebultowicz, R.J.B. Hoare, K. R. Horst, R. Hutch-ings, N. Hyde'n, W. Kelly, R. LeClerc, M. J. Matthews, N. McFarland, D. Messersmith, A. Mitchell, R. Poole, K.-T. Park, J. O. Nelson, E. S. Nielsen, R.S. Peigler, K. Pullen, R. Robertson, G. Tremewan, A. Venables, A. Willis, and K. Wolfe. Suwei Zhao and Kongyi Jiang provided technical assistance, and K. Mitter made essential contributions as specimen collection and database manager. We are grateful to M. Mutanen, L. Kaila, N. Wahlberg for permission to cite their work in progress. We thank D. Sean Brady, Sonja Scheffer and the five anonymous reviewers for helpful comments on the manuscript. Financial support was provided by the U.S. National Science Foundation's Assembling the Tree of Life program, award numbers 0531626 and 0531769, and by NSF grants BSR 9024770 and DEB 9306296, 9400829, 9705072, 0072730, and 0515699 to DHJ.",

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doi = "10.1186/1471-2148-9-280",

language = "English (US)",

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T1 - Toward reconstructing the evolution of advanced moths and butterflies (Lepidoptera: Ditrysia)

T2 - An initial molecular study

AU - Regier, Jerome C.

AU - Zwick, Andreas

AU - Cummings, Michael P.

AU - Kawahara, Akito Y.

AU - Cho, Soowon

AU - Weller, Susan

AU - Roe, Amanda

AU - Baixeras, Joaquin

AU - Brown, John W.

AU - Parr, Cynthia

AU - Davis, Donald R.

AU - Epstein, Marc

AU - Hallwachs, Winifred

AU - Hausmann, Axel

AU - Janzen, Daniel H.

AU - Kitching, Ian J.

AU - Solis, M. Alma

AU - Yen, Shen Horn

AU - Bazinet, Adam L.

AU - Mitter, Charles

N1 - Funding Information: We are greatly indebted to generous colleagues for supplying specimens for this study, including J. K. Adams, D. Adamski, K. Nishida, V. Becker, N. Bloomfield, T. Burbidge, J. Farr, G. Clarke, R. F. Denno, E. Edwards, M. Fibiger, T. Friedlander, J. Giebultowicz, R.J.B. Hoare, K. R. Horst, R. Hutch-ings, N. Hyde'n, W. Kelly, R. LeClerc, M. J. Matthews, N. McFarland, D. Messersmith, A. Mitchell, R. Poole, K.-T. Park, J. O. Nelson, E. S. Nielsen, R.S. Peigler, K. Pullen, R. Robertson, G. Tremewan, A. Venables, A. Willis, and K. Wolfe. Suwei Zhao and Kongyi Jiang provided technical assistance, and K. Mitter made essential contributions as specimen collection and database manager. We are grateful to M. Mutanen, L. Kaila, N. Wahlberg for permission to cite their work in progress. We thank D. Sean Brady, Sonja Scheffer and the five anonymous reviewers for helpful comments on the manuscript. Financial support was provided by the U.S. National Science Foundation's Assembling the Tree of Life program, award numbers 0531626 and 0531769, and by NSF grants BSR 9024770 and DEB 9306296, 9400829, 9705072, 0072730, and 0515699 to DHJ.

PY - 2009

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N2 - Abstract. Background. In the mega-diverse insect order Lepidoptera (butterflies and moths; 165,000 described species), deeper relationships are little understood within the clade Ditrysia, to which 98% of the species belong. To begin addressing this problem, we tested the ability of five protein-coding nuclear genes (6.7 kb total), and character subsets therein, to resolve relationships among 123 species representing 27 (of 33) superfamilies and 55 (of 100) families of Ditrysia under maximum likelihood analysis. Results. Our trees show broad concordance with previous morphological hypotheses of ditrysian phylogeny, although most relationships among superfamilies are weakly supported. There are also notable surprises, such as a consistently closer relationship of Pyraloidea than of butterflies to most Macrolepidoptera. Monophyly is significantly rejected by one or more character sets for the putative clades Macrolepidoptera as currently defined (P < 0.05) and Macrolepidoptera excluding Noctuoidea and Bombycoidea sensu lato (P 0.005), and nearly so for the superfamily Drepanoidea as currently defined (P < 0.08). Superfamilies are typically recovered or nearly so, but usually without strong support. Relationships within superfamilies and families, however, are often robustly resolved. We provide some of the first strong molecular evidence on deeper splits within Pyraloidea, Tortricoidea, Geometroidea, Noctuoidea and others. Separate analyses of mostly synonymous versus non-synonymous character sets revealed notable differences (though not strong conflict), including a marked influence of compositional heterogeneity on apparent signal in the third codon position (nt3). As available model partitioning methods cannot correct for this variation, we assessed overall phylogeny resolution through separate examination of trees from each character set. Exploration of "tree space" with GARLI, using grid computing, showed that hundreds of searches are typically needed to find the best-feasible phylogeny estimate for these data. Conclusion. Our results (a) corroborate the broad outlines of the current working phylogenetic hypothesis for Ditrysia, (b) demonstrate that some prominent features of that hypothesis, including the position of the butterflies, need revision, and (c) resolve the majority of family and subfamily relationships within superfamilies as thus far sampled. Much further gene and taxon sampling will be needed, however, to strongly resolve individual deeper nodes.

AB - Abstract. Background. In the mega-diverse insect order Lepidoptera (butterflies and moths; 165,000 described species), deeper relationships are little understood within the clade Ditrysia, to which 98% of the species belong. To begin addressing this problem, we tested the ability of five protein-coding nuclear genes (6.7 kb total), and character subsets therein, to resolve relationships among 123 species representing 27 (of 33) superfamilies and 55 (of 100) families of Ditrysia under maximum likelihood analysis. Results. Our trees show broad concordance with previous morphological hypotheses of ditrysian phylogeny, although most relationships among superfamilies are weakly supported. There are also notable surprises, such as a consistently closer relationship of Pyraloidea than of butterflies to most Macrolepidoptera. Monophyly is significantly rejected by one or more character sets for the putative clades Macrolepidoptera as currently defined (P < 0.05) and Macrolepidoptera excluding Noctuoidea and Bombycoidea sensu lato (P 0.005), and nearly so for the superfamily Drepanoidea as currently defined (P < 0.08). Superfamilies are typically recovered or nearly so, but usually without strong support. Relationships within superfamilies and families, however, are often robustly resolved. We provide some of the first strong molecular evidence on deeper splits within Pyraloidea, Tortricoidea, Geometroidea, Noctuoidea and others. Separate analyses of mostly synonymous versus non-synonymous character sets revealed notable differences (though not strong conflict), including a marked influence of compositional heterogeneity on apparent signal in the third codon position (nt3). As available model partitioning methods cannot correct for this variation, we assessed overall phylogeny resolution through separate examination of trees from each character set. Exploration of "tree space" with GARLI, using grid computing, showed that hundreds of searches are typically needed to find the best-feasible phylogeny estimate for these data. Conclusion. Our results (a) corroborate the broad outlines of the current working phylogenetic hypothesis for Ditrysia, (b) demonstrate that some prominent features of that hypothesis, including the position of the butterflies, need revision, and (c) resolve the majority of family and subfamily relationships within superfamilies as thus far sampled. Much further gene and taxon sampling will be needed, however, to strongly resolve individual deeper nodes.

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Toward reconstructing the evolution of advanced moths and butterflies (Lepidoptera: Ditrysia): An initial molecular study

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