Multigene fossil-calibrated analysis of the African lampeyes (Cyprinodontoidei: Procatopodidae) reveals an early Oligocene origin and Neogene diversification driven by palaeogeographic and palaeoclimatic events

Abstract

Here, we present the first molecular and fossil-dated analysis focusing in the Procatopodidae, a widely distributed and little known African oviparous killifish family. The analysis included 36 species representing all Procatopodidae genera except the monotypic Aapticheilichthys. Procatopodidae relationships were established through maximum likelihood and bayesian inference approaches based on fragments of one mitochondrial and five nuclear genes, a total of 5691 bp. The Procatopodidae is herein considered a monophyletic group, sister to the Old world Valenciidae and Aphaniidae. The genus Plataplochilus represent the most basal procatopodid lineage and the brackish water species Aplocheilichthys spilauchen is placed within the Procatopodidae. A clade including the morphologically distinct species of Congopanchax, Lacustricola, and Lamprichthys is herein suggested for the first time, and the genera Micropanchax, Poropanchax, Lacustricola, and Hypsopanchax revealed to be paraphyletic. A fossil-calibrated analysis, based on the same dataset, provided the first information about the evolution of the Procatopodidae in Africa. Our estimates indicate an early Oligocene origin for the Procatopodidae, as a consequence of the Eocene trans-Saharan epicontinental sea retreat, and also indicated that major Neogene paleogeographical and paleoenvironmental events influenced procatopodids diversification (e.g., increase activity in the African rift; late Miocene aridification; Pliocene and Pleistocene climatic instability).

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Acknowledgments

We are grateful to J-F. Agnèse, R. Bayer, H. Kärst, B. Nagy, R. Numrich, H. Ott, E. Purzl, R. Sonnenberg, T. Terceira, J. Vandermissen, J. Van der Zee, R. Wildekamp, and T. Woeltjs for donating specimens and/or providing pictures, and to I. Eidus, Z. Gabsi, G. Lenglet, J. Maclaine, M. Parrent, P. Pruvost, J. Snoeks, E. Vreven, and T. Walschaerts for hospitality during visits to their institutions and/or for the loan of specimens. We are also grateful to P. Amorim, A. Katz, and J. Mattos for laboratorial assistance during molecular analysis and to E. Henschel for reading a preliminary version of the manuscript. Part of this study was conducted by PHNB during a long-term stay at MRAC; special thanks to J. Snoeks and E. Vreven for providing fine conditions to develop researches in their institution, and to E. Abwe, J. Bamps, E. Decru, C. Garin, K. Kise, B. Mafuta, B. Manda, T. Musschoot, A. Nackaerts, M. Parrent, M. Van Steenberge, and A. Zamba for the daily help and technical assistance in MRAC. Some of the specimens included in this study were collected during expeditions supported by PRODEPAAK (NN/3000769) a Belgian Development Cooperation (BDC) project (2008-2013) for financial and logistical support to the Katanga Expedition 2012, and by the Mbisa Congo project (2013-2018) a framework agreement project of the RMCA with the Belgian Development Cooperation (BDC).

Funding

This study was supported by CNPq (Conselho Nacional de Desenvolvimento Científico e Tecnológico – Ministério de Ciência e Tecnologia; grant 141813/2014-8 to PHNB, and 307349/2015-2 and 200627/2015-5 to WJEMC); and CAPES (Coordenação de Aperfeiçoamento de Pessoal de Nível Superior, grant 99999.003613/2015-01 to PHNB).

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Online Resource 1

Representativeness of Procatopodidae genera included in the present study. The symbol (T) refers to genus type species. (XLSX 12 kb)

Online Resource 2

Included specimens, GenBank accession numbers and localities (XLSX 17 kb)

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ML performed in Garli 2.0 and BI analysis performed in MrBayes v3.2.5 including both nuclear and mitochondrial partitions. (PDF 2346 kb)

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Time analysis performed in BEAST v.1.8 including both nuclear and mitochondrial partitions. (PDF 2514 kb)

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Posterior probability support values of the time analysis performed in BEAST v.1.8 including only nuclear partitions. (PDF 1155 kb)

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Bragança, P.H.N., Costa, W.J.E.M. Multigene fossil-calibrated analysis of the African lampeyes (Cyprinodontoidei: Procatopodidae) reveals an early Oligocene origin and Neogene diversification driven by palaeogeographic and palaeoclimatic events. Org Divers Evol 19, 303–320 (2019). https://doi.org/10.1007/s13127-019-00396-1

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Keywords

  • Killifish
  • Africa
  • Cyprinodontiformes
  • Systematics
  • Procatopodidae