COVARIANCE OF ADULT SIZE AND DEVELOPMENT TIME IN THE PARASITOID WASP APHIDIUS-ERVI IN RELATION TO THE SIZE OF ITS HOST, ACYRTHOSIPHON-PISUM

被引：103

作者：

SEQUEIRA, R ^{[1
]}

MACKAUER, M ^{[1
]}

机构：

[1] SIMON FRASER UNIV,DEPT BIOL SCI,CTR PEST MANAGEMENT,BURNABY V5A 1S6,BC,CANADA

来源：

EVOLUTIONARY ECOLOGY | 1992年 / 6卷 / 01期

关键词：

APHIDIUS-ERVI; ADULT SIZE; DEVELOPMENT TIME; HOST SIZE; COVARIATION; LIFE-HISTORY STRATEGY; PARASITOID; PEA APHID;

D O I：

10.1007/BF02285332

中图分类号：

Q14 [生态学（生物生态学）];

学科分类号：

071012 ; 0713 ;

摘要：

Adult size (in terms of dry weight; DW) and development time (T(p)) of the solitary parasitoid Aphidius ervi varied when reared in different nymphal instars of its host, apterous virginoparae of the pea aphid (Acyrthosiphon pisum). Parasitoid DW increased with an increase in the DW of the host at parasitization, from the first to the third aphid instar. Female wasps gained 1.1 times more in DW than their male counterparts in all four host classes, but T(p) did not significantly differ between the sexes. Parasitoid DW was consistently more variable than T(p). The two traits covaried positively with an increase in host size from the first to the third instar, but they varied independently in parasitoids from fourth-instar hosts. The host size (and stage) at the time of parasitization imposes constraints on the growth and development of immature A. ervi that are reflected in the pattern of covariation between DW and T(p). When growing in aphids below a certain size threshold, parasitoids can maximize fitness by a trade-off between DW and T(p). Consequently, the assumption implicit in host-size models of parasitoid oviposition decisions - that females incur a relatively greater reduction in size (used as an index of fecundity) than males when developing in poor quality hosts - can be falsified.

引用

页码：34 / 44

页数：11

共 50 条

[1]

Arthur A.P., Wylie H.G., Effects of host size on sex ratio, developmental time and size of Pimpla turionellae L, Entomophaga, 4, pp. 297-301, (1959)

[2]

Bell G., Measuring the cost of reproduction. I. The correlation structure of the life table of a plankton rotifer, Evolution, 38, pp. 300-13, (1984)

[3]

Bell G., Measuring the cost of reproduction. II. The correlation structure of the life table of five freshwater invertebrates, Evolution, 38, pp. 314-26, (1984)

[4]

Boggs C.L., Nutritional and life history determinants of resource allocation in holometabolous insects, The American Naturalist, 117, pp. 692-709, (1981)

[5]

Brough C.N., Dixon A.F.G., Kindlmann P., Pattern of growth and fat content of somatic and gonadal tissues of virginoparae of the vetch aphid, Megoura viciae Buckton, Ent. Exp. Appl., 56, pp. 269-75, (1990)

[6]

Charnov E.L., The genetical evolution of patterns of sexuality: Darwinian fitness, The American Naturalist, 113, pp. 465-80, (1979)

[7]

Charnov E.L., The Theory of Sex Allocation, (1982)

[8]

Charnov E.L., Los-den Hartog R.L., Jones W.T., van den Assem L., Sex ratio evolution in a variable environment, Nature, 289, pp. 27-33, (1981)

[9]

Cloutier C., Amino acid utilization in the aphid Acyrthosiphon pisum infected by the parasitoid Aphidius smithi, J. Ins. Physiol., 32, pp. 263-7, (1986)

[10]

Cloutier C., Mackauer M., The effect of parasitism by Aphidius smithi (Hymenoptera: Aphidiidae) on the food budget of the pea aphid, Acyrthosiphon pisum (Homoptera: Aphididae), Canadian Journal of Zoology, 57, pp. 1605-11, (1979)

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