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LATE-QUATERNARY FOSSIL CHIRONOMIDAE (DIPTERA) FROM HIPPA LAKE, QUEEN CHARLOTTE ISLANDS, BRITISH COLUMBIA, WITH SPECIAL REFERENCE TO CORYNOCERA ZETT.

Published online by Cambridge University Press:  31 May 2012

Ian R. Walker
Affiliation:
Department of Biological Sciences, and Institute for Quaternary Research, Simon Fraser University, Burnaby, British Columbia, Canada V5A 1S6
Rolf W. Mathewes
Affiliation:
Department of Biological Sciences, and Institute for Quaternary Research, Simon Fraser University, Burnaby, British Columbia, Canada V5A 1S6

Abstract

Chironomid stratigraphic analyses of sediment from Hippa Lake, Queen Charlotte Islands, B.C., revealed a fossil chironomid record unlike that reported for deeper lakes of southwestern British Columbia, but similar to an arctic Alaskan sequence. Little evidence of trophic succession or climatic change was noted.

Chironomids, including Corynocera nr. ambigua Zett., rapidly colonized the lake. Because the known adults of Corynocera Zett. are brachypterous, the early arrival of C. nr. ambigua at Hippa Lake suggested either that this species survived in a Queen Charlotte glacial refugium, that chironomids can disperse very rapidly, even without active flight, or the existence of a previously undescribed Corynocera species with well-developed wings.

Elsewhere, fossils of the C. ambigua group are commonly associated with fossil oospores of Chara Valliant and Nitella Agardh. North American records are inconsistent, although similar correlations existed in some coastal lakes of British Columbia.

Résumé

Des analyses stratigraphiques des sédiments du lac Hippa des Iles de la Reine Charlotte, C.-B., ont révélé une faune chironomide fossile différente de celles rapportées dans des lacs plus profonds du sud-ouest de la Colombie Britannique, et similaire à une séquence de provenance arctique en Alaska. On a découvert peu d’évidence de succession trophique ou de changement climatique.

Des chironomides y compris Corynocera proche d’ambigua Zett. ont rapidement colonisé le lac. Etant donné que les adultes connus de Corynocera Zett. sont brachyptères, l’arrivée hâtive de C. proche d’ambigua au lac Hippa indique que cette espèce a survécu dans un refugium glaciaire des Iles, ou que les chironomides peuvent se disperser très rapidement et ce même sans l’assistance du vol, ou encore l’existence d’une espèce de Corynocera non décrite avec des ailes pleinement développées.

Ailleurs, les fossiles du groupe C. ambigua sont communément associés aux oospores fossiles de Chara Vallianl et Nitella Agardh. Les mentions nord-américaines sont incohérentes, mais des corrélations similaires existaient dans certains lacs côtiers de la Colombie Britannique.

Type
Articles
Copyright
Copyright © Entomological Society of Canada 1988

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References

Andersen, F.S. 1938. Spätglaziale Chironomiden. Medd. Dan. geol. Foren. 9: 320326.Google Scholar
Andersen, F.S. 1943. Dryadotanytarsus edentulus n.gen. et sp. (Dipt. Chiron.) from the late glacial period in Denmark. Ent. Medd. 23: 174178.Google Scholar
Berglund, B.E. (Ed.). 1986. Handbook of Holocene Palaeoecology and Palaeohydrology. John Wiley & Sons, New York. 869 pp.Google Scholar
Berglund, B.E., and Digerfeldt, G.. 1970. A palaeoecological study of the Late-Glacial lake at Torreberga, Scania, south Sweden. Oikos 21: 98128.CrossRefGoogle Scholar
Brodin, Y. 1986. The postglacial history of Lake Flarken, southern Sweden, interpreted from subfossil insect remains. Int. Rev. gesamten Hydrobiol. 71: 371432.CrossRefGoogle Scholar
Butler, M., Miller, M.C., and Mozley, S.. 1981. Macrobenthos. pp. 297339in Hobbie, J.E., (Ed.), Limnology of Tundra Ponds, Barrow, Alaska. US/IBP Synthesis Series 13. Dowden, Hutchinson and Ross, Stroudsburg, PA.Google Scholar
Calder, J.A., and Taylor, R.L.. 1968. Flora of the Queen Charlotte Islands. Part 1. Can. Dep. Agric. Monogr. 4: 1659.Google Scholar
Clague, J.J., Mathewes, R.W., and Warner, B.G.. 1982. Late Quaternary geology of eastern Graham Island, Queen Charlotte Islands, British Columbia. Can. J. Earth Sci. 19: 17861795.CrossRefGoogle Scholar
Cranston, P.S. 1982. The metamorphosis of Symposiocladius lignicola (Kieffer) n.gen., n.comb., a woodmining Chironomidae (Diptera). Ent. scand. 13: 419429.CrossRefGoogle Scholar
Danks, H.V. 1981. Arctic Arthropods: A Review of Systematics and Ecology with Particular Reference to the North American Fauna. Entomological Society of Canada, Ottawa. 608 pp.Google Scholar
Deevey, E.S. Jr., 1955. Paleolimnology of the Upper Swamp Deposit, Pyramid Valley. Rec. Canterbury Mus. 6: 291344.Google Scholar
Donald, D.B., Alger, D.J., and Antoniuk, G.A.. 1985. Limnological Studies in Jasper National Park. Part Ten: The North Boundary Lakes. Can. Wildlife Serv., Edmonton. 144 pp.Google Scholar
Downes, J.A. 1962. What is an arctic insect? Can. Ent. 94: 143162.CrossRefGoogle Scholar
Environment Canada. 1982. Canadian climate normals (1951–1980). Vol. 2, 3, 4, and 6. Atmospheric Environment Service, Ottawa, Canada.Google Scholar
Fitkau, E.J., and Reiss, F.. 1978. Chironomidae. pp. 404440in Illies, J. (Ed ), Limnofauna Europaea, 2nd ed. Gustav Fischer Verlag, Stuttgart.Google Scholar
Fjellberg, A. 1972. Present and late Weichselian occurrence of Corynocera ambigua Zett. (Dipt., Chironomidae) in Norway. Nor. Ent. Tidsskr. 19: 5961.Google Scholar
Green, D.G. 1987. Pollen evidence for the postglacial origins of Nova Scotia's forests. Can. J. Bot. 65: 11631179.CrossRefGoogle Scholar
Günther, J. 1983. Development of Grossensee (Holstein, Germany): variations in trophic status from the analysis of subfossil microfauna. Hydrobiologia 103: 231234.CrossRefGoogle Scholar
Hamilton, A.L. 1965. An analysis of a freshwater benthic community with special reference to the Chironomidae. 2 parts. Ph.D. thesis. University of British Columbia, Vancouver.Google Scholar
Hare, R.L. 1976. The macroscopic zoobenthos of Parry Sound, Georgian Bay. M.Sc. thesis, University of Waterloo, Waterloo, Canada.Google Scholar
Hirvenoja, M. 1960. Massenauftreten von Corynocera ambigua Zett. (Dipt. Chironomidae) im See Sompiojärvi, Finnish-Lappland. Ann. Ent. Fenn. 26: 157163.Google Scholar
Hirvenoja, M. 1961. Description of the larva of Corynocera ambigua Zett. (Dipt. Chironomidae) and its relation to the subfossil species Dryadotanytarsus edentulus Anders. and D. duffi Deevey. Ann. Ent. Fenn. 27: 105110.Google Scholar
Hofmann, W. 1978. Analysis of animal microfossils from the Groβer Segeberger See (F.R.G.). Arch. Hydrobiol. 82: 316346.Google Scholar
Hofmann, W. 1983 a. Stratigraphy of subfossil Chironomidae and Ceratopogonidae (Insecta: Diptera) in late glacial littoral sediments from Lobsigensee (Swiss Plateau). Studies in the late Quaternary of Lobsigensee 4. Rev. Paléobiol. 2: 205209.Google Scholar
Hofmann, W. 1983 b. Stratigraphy of Cladocera and Chironomidae in a core from a shallow North German Lake. Hydrobiologia 103: 235239.CrossRefGoogle Scholar
Hofmann, W. 1984. A subfossil record of the presumed larva of Corynocera oliveri Lindeberg from the Lobsigensee (Swiss Plateau). Studies in the late Quaternary of Lobsigensee 8. Spixiana 7: 211214.Google Scholar
Hofmann, W. 1985. Developmental history of Lobsigensee: subfossil Chironomidae (Diptera). pp. 154–156 in Lobsigensee — Late-glacial and Holocene Environments of a Lake on the Central Swiss Plateau. Diss. Bot. 87: 127170.Google Scholar
Lindeberg, B. 1970. Tanytarsini (Diptera, Chironomidae) from northern Fennoscandia. Ann. zool. fenn. 7: 303312.Google Scholar
Livingstone, D.A. 1953. On the paleolimnology of arctic Alaska. Ph.D. thesis, Yale University, New Haven, CT.Google Scholar
Livingstone, D.A., Bryan, K. Jr., and Leahy, R.G.. 1958. Effects of an arctic environment on the origin and development of freshwater lakes. Limnol. Oceanogr. 3: 192214.CrossRefGoogle Scholar
Maguire, B. Jr., 1963. The passive dispersal of small aquatic organisms and their colonization of isolated bodies of water. Ecol. Monogr. 33: 161185.CrossRefGoogle Scholar
Mathewes, R.W. 1973. A palynological study of postglacial vegetation changes in the Univeristy Research Forest, southwestern British Columbia. Can. J. Bot. 51: 20852103.CrossRefGoogle Scholar
Mathewes, R.W. 1988. Paleobotany of the Queen Charlotte Islands. In Scudder, G.G.E., and Gessler, N. (Eds.), The Outer Shores: Proceedings of the Queen Charlotte Islands Symposium. Queen Charlotte Islands Museum, Skidegate, B.C. In press.Google Scholar
Mathewes, R.W., Vogel, J.S., Southon, J.R., and Nelson, D.E.. 1985. Accelerator radiocarbon date confirms early deglaciation of the Queen Charlotte Islands. Can. J. Earth Sci. 22: 790791.CrossRefGoogle Scholar
Moore, J.W. 1978. Some factors influencing the diversity and species composition of benthic invertebrate communities in twenty arctic and subarctic lakes. Int. Rev. gesamten Hydrobiol. 63: 757771.CrossRefGoogle Scholar
Mothes, G. 1968. Einige ökologisch interessante Chironomiden aus dem Stechlinseegebeit. Ann. Zool. Fenn. 5: 9296.Google Scholar
Murray, D.A. 1983. An inventory of Irish Chironomidae (Diptera). Mem. Am. ent. Soc. 34: 223233.Google Scholar
Oliver, D.R., and Roussel, M.E.. 1983. The insects and arachnids of Canada. Part II. The genera of larval midges of Canada; Diptera: Chironomidae. Agric. Can. Publ. 1746: 1263.Google Scholar
Pinder, L.C.V., and Reiss, F.. 1983. The larvae of Chironominae (Diptera: Chironomidae) of the Holarctic region — Keys and diagnoses. Ent. scand. Suppl. 19: 293435.Google Scholar
Pinder, L.C.V. 1986. The pupae of Chironominae (Diptera: Chironomidae) of the Holarctic region — Keys and diagnoses. Ent. scand. Suppl. 28: 299456.Google Scholar
Province of British Columbia. 1967. Forest cover map 103-F-10-d, 11-a. Forest Inventory Division, British Columbia Forest Service.Google Scholar
Sæther, O.A. 1969. Some Nearctic Podonominae, Diamesinae, and Orthocladiinae (Diptera: Chironomidae). Bull. Fish. Res. Board Can. 170: 1154.Google Scholar
Sæther, O.A. 1975 a. Two new species of Heterotanytarsus Spärck, with keys to Nearctic and Palaearctic males and pupae of the genus (Diptera: Chironomidae). J. Fish. Res. Board Can. 32: 259270.CrossRefGoogle Scholar
Sæther, O.A. 1975 b. Nearctic and palaearctic Heterotrissocladius (Diptera: Chironomidae). Bull. Fish. Res. Board Can. 193: 167.Google Scholar
Sæther, O.A. 1977. Taxonomic studies on Chironomidae: Nanocladius, Pseudochironomus, and the Harnischia complex. Bull. Fish. Res. Board Can. 196: 1143.Google Scholar
Schakau, B., and Frank, C.. 1984. Die Entwicklung der Chironomiden-Fauna (Diptera) des Tegeler Sees im Spät- und Postglazial. Verh. Ges. Okol. 12: 375382.Google Scholar
Schuster, R.M., and Schofield, W.B.. 1982. On Dendrobazzania, a new genus of Lepidoziaceae (Jungermanniales). Bryologist 85: 231238.CrossRefGoogle Scholar
Sutherland Brown, A. 1968. Geology of the Queen Charlotte Islands, British Columbia. B.C. Dep. Mines Petroleum Resour. Bull. 54.Google Scholar
Sutherland Brown, A., and Nasmith, H.. 1962. The glaciation of the Queen Charlotte Islands. Can. Field-Nat. 76: 209219.CrossRefGoogle Scholar
Tobolski, K. 1985. Plant macrofossils from Lobsigensee. pp. 140–143 in Lobsigensee — Late-glacial and Holocene Environments of a Lake on the Central Swiss Plateau. Diss. Bot. 87: 127170.Google Scholar
Vitt, D.H., and Schofield, W.B.. 1976. Seligeria careyana, a new species from the Queen Charlotte Islands, western Canada. Bryologist 79: 231234.CrossRefGoogle Scholar
Wainman, N. 1986. Forest history of the last 12,000 years based on plant macrofossil analysis of lake sediment from southwestern B.C. M.Sc. thesis, Simon Fraser University, Burnaby, B.C.CrossRefGoogle Scholar
Walker, I.R. 1988. Late-Quaternary Palaeoecology of Chironomidae (Diptera: Insecta) from lake sediments in British Columbia. Ph.D. thesis, Simon Fraser University, Burnaby, B.C.Google Scholar
Walker, I.R., Fernando, C.H., and Paterson, C.G.. 1985. Associations of Chironomidae (Diptera) of shallow, acid, humic lakes and bog pools in Atlantic Canada, and a comparison with an earlier paleoecological investigation. Hydrobiologia 120: 1122.CrossRefGoogle Scholar
Walker, I.R., and Mathewes, R.W.. 1987. Chironomidae (Diptera) and postglacial climate at Marion Lake, British Columbia, Canada. Quat. Res. 27: 89102.CrossRefGoogle Scholar
Warner, B.G. 1984. Late Quaternary paleoecology of eastern Graham Island, Queen Charlotte Islands, British Columbia, Canada. Ph.D. thesis, Simon Fraser University, Burnaby, B.C.CrossRefGoogle Scholar
Warner, B.G., Mathewes, R.W., and Clague, J.J.. 1982. Ice-free conditions on the Queen Charlotte Islands, British Columbia, at the height of late Wisconsin glaciation. Science 218: 675677.CrossRefGoogle ScholarPubMed
Wiederholm, T. (Ed.). 1983. Chironomidae of the Holarctic region: Keys and diagnoses. Part 1—Larvae. Entomol. scand. Suppl. 19: 1457.Google Scholar
Wiens, A.P., Rosenberg, D.M., and Snow, N.B.. 1975. Species list of aquatic plants and animals collected from the Mackenzie and Porcupine River watersheds from 1971–1973. Can. Fish. & Mar. Serv. Tech. Rep. 557: 139.Google Scholar