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Asymmetrical reproductive interference between two sibling species of tea looper: Ectropis grisescens and Ectropis obliqua

  • G.-H. Zhang (a1) (a2), Z.-J. Yuan (a1), K.-S. Yin (a1), J.-Y. Fu (a1), M.-J. Tang (a1) and Q. Xiao (a1)...

Abstract

Ectropis grisescens Warren and Ectropis obliqua (Prout) are two morphologically similar sibling species with overlapping ranges. In this study, manipulative laboratory experiments were conducted to examine the possibility of reproductive interference in sympatric populations of E. grisescens and E. obliqua and the potential consequences of the mating interaction. Our results showed that the presence of males or females of different species could incur mating interference and significant reduction of F 1 offspring. The reduction was not significant relevant to the initial relative abundance of E. grisescens and E. obliqua. Detailed observations of mating opportunity showed that female mating frequencies of both species were not significantly affected by the absolute species density, but the mating success of E. obliqua females with conspecific males depended on species ratio. In addition, adding males to the other species resulted in lower number of offspring suggesting that the males’ behaviour might be linked with mating interference. Males of both E. grisescens and E. obliqua could interfere the intraspecific mating of the other species, but the impact of the mating interference differed. These combined data indicated that asymmetric reproductive interference existed in E. grisescens and E. obliqua under laboratory conditions, and the offspring of the mixed species were significantly reduced. The long term outcome of this effect is yet to be determined since additional reproductive factors such as oviposition rate and progeny survival to adulthood may reduce the probability of demographic displacement of one species by the other in overlapping niches.

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Copyright

This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.

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*Address for correspondence Tel: +86 0571 86650801 Fax: +86 0571 86650720 E-mail: xqtea@mail.tricaas.com

References

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Ardeh, M.J., de Jong, P.W., Loomans, A.J.M. & van Lenteren, C. (2004) Inter- and intraspecific effects of volatile and nonvolatile sex pheromones on males, mating behaviour, and hybridization in Eretmocerus mundus and E-eremicus (Hymenoptera : Aphelinidae). Journal of Insect Behaviour 17, 745759.
Ben-David, T., Gerson, U. & Morin, S. (2009) Asymmetric reproductive interference between two closely related spider mites: Tetranychus urticae and T-turkestani (Acari: Tetranychidae). Experimental and Applied Acarology 48, 213227.
Bleu, J., Bessa-Gomes, C. & Laloi, D. (2012) Evolution of female choosiness and mating frequency: effects of mating cost, density and sex ratio. Animal Behaviour 83, 131136.
Chapman, T., Arnqvist, G., Bangham, J. & Rowe, L. (2003) Sexual conflict. Trends in Ecology and Evolution 18, 4147.
Chapple, D.G., Simmonds, S.M. & Wong, B.B. (2012) Can behavioural and personality traits influence the success of unintentional species introductions? Trends in Ecology and Evolution 27, 5764.
Coyne, J.A. & Orr, H.A. (1989) Patterns of speciation in Drosophila. Evolution 43, 362381.
Crowder, D.W., Horowitz, A.R., De Barro, P.J., Liu, S.S., Showalter, A.M., Kontsedalov, S., Khasdan, V., Shargal, A., Liu, J. & Carriere, Y. (2010 a) Mating behaviour, life history and adaptation to insecticides determine species exclusion between whiteflies. Journal of Animal Ecology 79, 563570.
Crowder, D.W., Sitvarin, M.I. & Carriere, Y. (2010 b) Plasticity in mating behaviour drives asymmetric reproductive interference in whiteflies. Animal Behaviour 79, 579587.
Dame, E.A. & Petren, K. (2006) Behavioural mechanisms of invasion and displacement in Pacific island geckos (Hemidactylus). Animal Behaviour 71, 11651173.
Gröning, J. & Hochkirch, A. (2008) Reproductive interference between animal species. Quarterly Review of Biology 83, 257282.
Gröning, J., Lücke, N., Finger, A. & Hochkirch, A. (2007) Reproductive interference in two ground-hopper species: testing hypotheses of coexistence in the field. Oikos 116, 14491460.
Harari, A.R., Zahavi, T., Gordon, D., Anshelevich, L., Harel, M., Ovadia, S. & Dunkelblum, E. (2007) Pest management programmes in vineyards using male mating disruption. Pest Management Science 63, 769775.
Himuro, C. & Fujisaki, K. (2012) The effects of male harassment on mating duration in the seed bug, Togo hemipterus. Entomologia Experimentalis Et Applicata 142, 5359.
Hochkirch, A. & Groning, J. (2012) Niche overlap in allotopic and syntopic populations of sexually interacting ground-hopper species. Insect Science 19, 391402.
Hochkirch, A. & Lemke, I. (2011) Asymmetric mate choice, hybridization, and hybrid fitness in two sympatric grasshopper species. Behavioural Ecology and Sociobiology 65, 16371645.
Hochkirch, A., Gröning, J. & Bucker, A. (2007) Sympatry with the devil: reproductive interference could hamper species coexistence. Journal of Animal Ecology 76, 633642.
Jiang, N., Liu, S.X., Xue, D.Y., Tang, M.J., Xiao, Q., Han, H.X. (2014) External morphology and molecular identification of two tea Geometrid moth from southern China. Chinese Journal of Applied Entomology 51, 9871002.
Judd, G.J.R. & Gardiner, M.G.T. (2005) Towards eradication of codling moth in British Columbia by complimentary actions of mating disruption, tree banding and sterile insect technique: five-year study in organic orchards. Crop Protection 24, 718733.
Keranen, I., Kahilainen, A., Knott, K.E., Kotiaho, J.S. & Kuitunen, K. (2013) High maternal species density mediates unidirectional heterospecific matings in Calopteryx damselflies. Biological Journal of the Linnean Society 108, 534545.
Kim, S.S., Beljaev, E.A., Oh, S.H. (2001) Illustrated catalogue of Geomotridae in Korea (Lepidoptera: Geometrinae, Ennominae). pp. 1278 in Park, K.T. (Ed.). Insects of Korea Series 8. Daejeon, Korea Reasearch Institute of Bioscience and Biotechnology & Center for Insect Systematics.
Kishi, S., Nishida, T. & Tsubaki, Y. (2009) Reproductive interference determines persistence and exclusion in species interactions. Journal of Animal Ecology 78, 10431049.
Liu, S.S., De Barro, P.J., Xu, J., Luan, J.B., Zang, L.S., Ruan, Y.M. & Wan, F.H. (2007) Asymmetric mating interactions drive widespread invasion and displacement in a whitefly. Science 318, 17691772.
Luan, J.B. & Liu, S.S. (2012) Differences in mating behaviour lead to asymmetric mating interactions and consequential changes in sex ratio between an invasive and an indigenous whitefly. Integrative Zoology 7, 115.
Luan, J.B., De Barro, P.J., Ruan, Y.M. & Liu, S.S. (2013) Distinct behavioural strategies underlying asymmetric mating interactions between invasive and indigenous whiteflies. Entomologia Experimentalis et Applicata 146, 186194.
Luan, J.B., Wang, X.W., Colvin, J. & Liu, S.S. (2014) Plant-mediated whitefly-begomovirus interactions: research progress and future prospects. Bulletin of Entomological Research 104, 267276.
Noriyuki, S., Osawa, N. & Nishida, T. (2012) Asymmetric reproductive interference between specialist and generalist predatory ladybirds. Journal of Animal Ecology 81, 10771085.
Reitz, S.R. & Trumble, J.T. (2002) Competitive displacement among insects and arachnids. Annual Review of Entomology 47, 435465.
Rowe, L. & Arnqvist, G. (2002) Sexually antagonistic coevolution in a mating system: combining experimental and comparative approaches to address evolutionary processes. Evolution 56, 754767.
Sato, R. (1984) Taxonomic study of the genus Hypomecis Hübner and its allied genera from Japan (Lepidoptera: Geometridae: Ennominae). Special Bulletin of Essa Entomological Society 1, 1–213.
Scott Schneider, S., DeGrandi-Hoffman, G. & Smith, D.R. (2004) The African honey bee: factors contributing to a successful biological invasion. Annual Review of Entomology 49, 351376.
Seehausen, O. (2004) Hybridization and adaptive radiation. Trends in Ecology and Evolution 19, 198207.
Servedio, M.R. & Noor, M.A.F. (2003) The role of reinforcement in speciation: theory and data. Annual Review of Ecology, Evolution and Systematics 34, 339364.
Soares, A.O. & Serpa, A. (2007) Interference competition between ladybird beetle adults (Coleoptera : Coccinellidae): effects on growth and reproductive capacity. Population Ecology 49, 3743.
Suckling, D.M., Stringer, L.D., Stephens, A.E., Woods, B., Williams, D.G., Baker, G. & El-Sayed, A.M. (2013) From integrated pest management to integrated pest eradication: technologies and future needs. Pest Management Science 70, 179189.
Sun, D.B., Li, J., Liu, Y.Q., Crowder, D.W. & Liu, S.S. (2014) Effects of reproductive interference on the competitive displacement between two invasive whiteflies. Bulletin of Entomological Research 104, 334346.
Swinhoe, C. (1902) New and little known species of Drepanulidae, Epiplemidae, Microniidae and Geometridae in the national collection. Transactions of the Royal Entomological Society London 3 584677.
Thum, R.A. (2007) Reproductive interference, priority effects and the maintenance of parapatry in Skistodiaptomus copepods. Oikos 116, 759768.
Wang, P., Crowder, D.W. & Liu, S.S. (2012) Roles of mating behavioural interactions and life history traits in the competition between alien and indigenous whiteflies. Bulletin of Entomological Research 102, 395405.
Warren, W. (1894) New genera and species of Geometridae. Novitates Zoologicae 1, 366466.
Wehrli, E. (1939–1954) Subfamilie: Geometrinae. Seitz, A. (ed). Die Gross-Schmetterlinge der Erde. Abt. I. Die Spannerartigen Nachtfalter. Bd. 4 (Supplement), 254766, pls. 19–53. Verlag, A. Kernen, Stuttgart, German.
Xi, Y., Yin, K.S., Tang, M.J., Xiao, Q. (2014) Geographic populations of the tea geometrid, Ectropis obliqua (Lepidoptera: Geometridae) in Zhejiang, eastern China have differentiated into different species. Acta Entomologica Sinica 57, 11171122.
Zhang, H.H. & Tan, J.C. (2004) Tea pests and non-pollution management in China. Hefei, Anhui Science and Technology Publishing House, 1389.
Zhang, G.H., Ysuan, Z.J., Zhang, C.X., Yin, K.S., Tang, M.J., Guo, H.W., Fu, J.Y., Xiao, Q. (2014) Detecting deep divergence in seventeen populations of tea geometrid (Ectropis obliqua Prout) in China by COI mtDNA and cross-breeding. PLoS ONE 9, e99373.

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