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Selection for a threshold character in Drosophila II. Homeostatic behaviour on relaxation of selection

Published online by Cambridge University Press:  14 April 2009

B. D. H. Latter
Affiliation:
Division of Plant Industry, C.S.I.R.O., Canberra, Australia
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This paper is concerned with three related aspects of the behaviour of populations under artificial selection for increased scutellar bristle number: (i) the pattern of response on the probit scale; (ii) the homeostatic behaviour of the selection lines on relaxation of artificial selection; and (iii) correlated responses in generation interval, reproductive capacity and competitive ability. The study was designed so that linkage would be a comparatively unimportant factor in promoting correlated responses to selection, and the effects of genetic sampling from generation to generation were also reduced to a low level.

Progress from the base mean of 4·05 bristles in females to a level of almost 8 bristles has been shown to involve two distinct phases with realized heritabilities of 0·34 and 0·10 respectively, the zone of transition corresponding closely to the position of the 6/7 threshold on the underlying scale. In addition to an apparent average reduction of about 25% in the additive genetic standard deviation in phase II by comparison with phase I, the loss in response due to the opposition of natural selection has been shown to reach a maximum near the zone of separation of the two phases.

The pattern of behaviour of the populations under artificial and natural selection has suggested the presence in the base population of genes of large effect on both bristle number and reproductive fitness. There is also evidence of additional genetic variation in bristle number which is effectively neutral with respect to fitness. Continued selection for increased scutellar bristle number in large populations has been shown to reduce mean competitive ability by more than 80%.

Type
Research Article
Copyright
Copyright © Cambridge University Press 1966

References

REFERENCES

Gowe, R. S., Robertson, A. & Latter, B. D. H. (1959). Environment and poultry breeding problems. V. The design of poultry control strains. Poult. Sci. 38, 462471.CrossRefGoogle Scholar
Knight, G. R. & Robertson, A. (1957). Fitness as a measurable character in Drosophila. Genetics, 42, 524530.CrossRefGoogle ScholarPubMed
Latter, B. D. H. (1963). Genetic homeostasis and the theory of canalization. In Statistical Genetics and Plant Breeding (Hanson, W. D. & Robinson, H. F., eds.), pp. 455467. National Academy of Sciences—National Research Council Pub. 982.Google Scholar
Latter, B. D. H. (1964). Selection for a threshold character in Drosophila. I. An analysis of the phenotypic variance on the underlying scale. Genet. Res. 5, 198210.CrossRefGoogle Scholar
Latter, B. D. H. (1967). The response to artificial selection due to autosomal genes of large effect. IV. The increase in frequency of deleterious recessive genes in finite populations. Aust. J. biol. Sci. (in press).Google Scholar
Latter, B. D. H. & Robertson, A. (1962). The effects of inbreeding and artificial selection on reproductive fitness. Genet. Res. 3, 110138.CrossRefGoogle Scholar
Robertson, A. (1961). Inbreeding in artificial selection programmes. Genet. Res. 2, 189194.CrossRefGoogle Scholar
Thoday, J. M. (1961). Location of polygenes. Nature, Lond. 191, 368370.CrossRefGoogle Scholar