The occurrence and phylogenetic implications of wing interference patterns in Cynipoidea (Insecta : Hymenoptera)

Article

<< Previous

Contents Vol 25(6)

doi:10.1071/IS11038

Systematics, Phylogeny and Biogeography

	Search




	Advanced Search



	Journal Home

	About the Journal

	Editorial Board

	Contacts



	Content

	Current Issue

	Just Accepted

	Virtual Issues

	All Issues

	Special Issues

	Sample Issue



	For Authors

	General Information

	Notice to Authors

	Submit Article

	Open Access



	For Referees

	Referee Guidelines

	Review Article

	Annual Referee Index



	For Subscribers

	Subscription Prices

	Customer Service

	Print Publication Dates

e-Alerts

Subscribe to our Email Alert or

feeds for the latest journal papers.

Connect with us

Supplementary Series

All volumes of the Australian Journal of Zoology Supplementary Series are online.

The occurrence and phylogenetic implications of wing interference patterns in Cynipoidea (Insecta : Hymenoptera)

Matthew L. Buffington ^A ^C and Robert J. Sandler ^B

^A Systematic Entomology Lab, USDA, c/o USNM, Smithsonian Institution, 10th & Constitution Ave NW, PO Box 37012 MRC-168, Washington, DC 20013, USA.
^B Department of Science & Society, Maxcy Hall, Brown University, Providence, RI 02912, USA.
^C Corresponding author. Email: matt.buffington@ars.usda.gov

Invertebrate Systematics 25(6) 586-597 http://dx.doi.org/10.1071/IS11038
Submitted: 27 September 2011 Accepted: 4 December 2011 Published: 7 May 2012





	PDF (2.3 MB) $40



	Export Citation

Print

Abstract

Wing interference patterns (WIPs) are a potentially rich source of taxonomic data. We surveyed a broad range of Cynipoidea (Hymenoptera) for the presence of these patterns. Further, we used phylogeny to investigate the evolutionary patterns of WIPs throughout the superfamily. We also documented that WIPs occur across nearly all species sampled, in both the hindwing and forewing; in many instances, the forewing WIP is carried over to the hindwing. Only Austrocynips mirabilis Riek lacked WIPs. Among species that possess WIPs, we were able to recognise four distinct categories: radiform (radiating), striatiform (longitudinally striate), campiform (continuous field) and galactiform (amorphous mixture of colours). Wing interference patterns are not found in infuscate wings or areas of infuscation on otherwise hyaline wings, and are reduced on large wings. Within Figitidae, WIPs are more phylogenetically conservative, especially at the tribal level: within Cynipidae the phylogenetic conservatism of WIPs is somewhat less clear, though all Synergini sampled had a very consistent WIPs. For certain genera, such as Ganaspidium and Andricus, WIPs may prove useful for species-level discrimination.

References

Ács, Z., Richard, C., Bihari, P., Blaxter, M., Hayward, A., Melika, G., Csóka, G., Pénzes, Z., Pujade-Villar, J., Nieves-Aldrey, J. L., Schönrogge, K., and Stone, G. (2010). Phylogeny and DNA barcoding of inquiline oak gallwasps (Hymenoptera: Cynipidae) of the Western Palaearctic. Molecular Phylogenetics and Evolution 55, 210–225.
| CrossRef |

Buffington, M. L. (2009). Description, circumscription and phylogenetics of the Zaeucoilini, new tribe (Hymenoptera: Figitidae: Eucoilinae) including a description of a new genus. Systematic Entomology 34, 162–187.
| CrossRef |

Buffington, M. L. (2011). Description, circumscription and phylogenetics of the Diglyphosematini Belizin, 1961, and the description of a new genus (Hymenoptera: Figitidae: Eucoilinae). Proceedings of the Entomological Society of Washington 113, 239–290.
| CrossRef |

Buffington, M. L., Nylander, J. A. A., and Heraty, J. (2007). The phylogeny and evolution of Figitidae (Hymenoptera: Cynipoidea). Cladistics 23, 403–431.
| CrossRef |

Forshage, M., and Nordlander, G. (2008). Identification key to European genera of Eucoilinae (Hymenoptera, Cynipoidea, Figitidae). Insect Systematics & Evolution 39, 341–359.
| CrossRef |

Gibson, A. P., Huber, J. T., and Woolley, J. B. (Eds) (1997). ‘Annotated Keys to the Genera of Nearctic Chalcidoidea (Hymenoptera).’ (NRC Research Press: Ottawa.)

Heraty, J. M. (2004). Molecular systematics, Chalcidoidea and biological control. In ‘Genetics, Evolution and Biological Control’. (Eds L. E. Ehler, R. Siorza and T. Mateille.) pp. 39–71. (CAB International: London.)

Heraty, J., Woolley, J., Hopper, K., Hawks, D., Kim, J.-W., and Buffington, M. (2007). Molecular phylogenetics and reproductive incompatibility in a complex of cryptic species of aphid parasitoids. Molecular Phylogenetics and Evolution 45, 480–493.
| CrossRef | CAS |

Liljeblad, J., Ronquist, F., Nieves-Aldrey, J. L., Fontal-Cazalla, F., Ros-Farré, P., Gaitros, D., and Pujade-Villar, J. (2008). A fully web-illustrated morphological phylogenetic study of relationships among oak gall wasps and their closest relatives (Hymenoptera: Cynipidae). Zootaxa 1796, 1–73.

Moriya, S., Shiga, M., and Adachi, I. (2003). Classical biological control of the chestnut gall wasp in Japan. In ‘First International Symposium on Biological Control of Arthropods’. pp. 407–415. (USDA Forest Service, Forest Health Technology Enterprise Team: Morgantown, WV, USA.)

Nicholls, J. A., Preuss, S., Hayward, A., Melika, G., Csóka, G., Nieves-Aldrey, J. L., Askew, R. R., Tavakoli, M., Schönrogge, K., and Stone, G. N. (2010). Concordant phylogeography and cryptic speciation in two Western Palaearctic oak gall parasitoid species complexes. Molecular Ecology 19, 592–609.
| CrossRef |

Noyes, J. (2000). Encyrtidae of Costa Rica (Hymenoptera: Chalcidoidea), 1. Memoirs of the American Entomological Institute 62, 1–355.

Noyes, J., and Hayat, M. (1994). ‘Oriental Mealybug Parasitoids of the Anagyrini (Hymenoptera: Encyrtidae).’ (CAB International, University Press: Cambridge, UK.)

Nylander, J. A. A., Ronquist, F., Huelsenbeck, J. P., and Nieves-Aldrey, J. L. (2004). Bayesian phylogenetic analysis of combined data. Systematic Biology 53, 47–67.
| CrossRef |

Pujade-Villar, J., Barbotin, F., Folliot, R., and Melika, G. (2005). Are Callirhytis erythrostoma (Dettmer, 1933) and C. erythrosoma (Dettmer, 1933) synonyms of Callirhytis erythrocephala (Giraud, 1859) or different species? (Hymenoptera: Cynipidae: Cynipini). Butlletí de la Institució Catalana d’Història Natural 73, 61–70.

Pujade-Villar, J., Jiménez, M., and Paretas-Martínez, J. (2008). Xyalophoroides quinquelineata (Say, 1836) (Hymenoptera: Figitidae: Figitinae): a species complex or a very variable species? Boletin de La Sociedad Entomológica Aragonesa 43, 367–374.

Ronquist, F. (1999). Phylogeny, classification and evolution of the Cynipoidea. Zoologica Scripta 28, 139–164.
| CrossRef |

Ronquist, F., and Nordlander, G. (1989). Skeletal morphology of an archaic cynipoid (Hymenoptera: Ibaliidae). Entomologica Scandinavica Supplements 33, 1–40.

Shevtsova, E., Hansson, C., Janzen, D., and Kjærandsen, J. (2011). Stable structural color patterns displayed on transparent insect wings. Proceedings of the National Academy of Sciences of the United States of America 108, 668–673.
| CrossRef | CAS |

Stone, G. N., Atkinson, R. J., Rokas, A., Nieves-Aldrey, J. L., Melika, G., Ács, Z., Csóka, G., Hayward, A., Bailey, R., Buckee, C., and Mcvean, G. A. T. (2008). Evidence for widespread cryptic sexual generations in apparently purely asexual Andricus gallwasps. Molecular Ecology 17, 652–665.
| CrossRef |

Wharton, R., Ovruski, S., and Gilstrap, F. (1998). Neotropical Eucoilidae (Cynipoidea) associated with fruit-infesting Tephritidae, with new records from Argentina, Bolivia and Costa Rica. Journal of Hymenoptera Research 7, 102–115.

Subscriber Login

	Username: Password:

Legal & Privacy | Contact Us | Help