The effect of temperature and wing morphology on quantitative genetic variation in the cricket Gryllus firmus, with an appendix examining the statistical properties of the Jackknife–manova method of matrix comparison

We investigated the effect of temperature and wing morphology on the quantitative genetic variances and covariances of five size‐related traits in the sand cricket, Gryllus firmus. Micropterous and macropterous crickets were reared in the laboratory at 24, 28 and 32 °C. Quantitative genetic paramete...

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Published inJournal of evolutionary biology Vol. 17; no. 6; pp. 1255 - 1267
Main Authors Bégin, M., Roff, D. A., Debat, V.
Format Journal Article
LanguageEnglish
Published Oxford, UK Blackwell Science Ltd 01.11.2004
Blackwell Publishing Ltd
Wiley
Subjects
additive genetic variation
Analysis of Variance
Animals
Biological Evolution
Biological variation
body size
Body Weights and Measures
common principal components
Entomology
Environmental Sciences
Evolutionary biology
Florida
G matrix
genetic correlation
Genetic diversity
Genetic Variation
Gryllidae - anatomy & histology
Gryllidae - genetics
Gryllus firmus
heritability
Insects
Matrix
Orthoptera
Phenotype
phenotypic plasticity
Quantitative Trait, Heritable
Temperature
wing dimorphism
Wings, Animal - anatomy & histology
Florida
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Summary:We investigated the effect of temperature and wing morphology on the quantitative genetic variances and covariances of five size‐related traits in the sand cricket, Gryllus firmus. Micropterous and macropterous crickets were reared in the laboratory at 24, 28 and 32 °C. Quantitative genetic parameters were estimated using a nested full‐sib family design, and (co)variance matrices were compared using the T method, Flury hierarchy and Jackknife–manova method. The results revealed that the mean phenotypic value of each trait varied significantly among temperatures and wing morphs, but temperature reaction norms were not similar across all traits. Micropterous individuals were always smaller than macropterous individuals while expressing more phenotypic variation, a finding discussed in terms of canalization and life‐history trade‐offs. We observed little variation between the matrices of among‐family (co)variation corresponding to each combination of temperature and wing morphology, with only one matrix of six differing in structure from the others. The implications of this result are discussed with respect to the prediction of evolutionary trajectories.
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ISSN:1010-061X
1420-9101
DOI:10.1111/j.1420-9101.2004.00772.x