Developmental stability: a major role for cyclin G in drosophila melanogaster

Morphological consistency in metazoans is remarkable given the pervasive occurrence of genetic variation, environmental effects, and developmental noise. Developmental stability, the ability to reduce developmental noise, is a fundamental property of multicellular organisms, yet its genetic bases re...

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Bibliographic Details
Published in:PLoS genetics 2011-10, Vol.7 (10), p.e1002314-e1002314
Main Authors: Debat, Vincent, Bloyer, Sébastien, Faradji, Floria, Gidaszewski, Nelly, Navarro, Nicolas, Orozco-Terwengel, Pablo, Ribeiro, Valérie, Schlötterer, Christian, Deutsch, Jean S, Peronnet, Frédérique
Format: Article
Language:English
Subjects:
Animals
Asymmetry
Base Sequence
Biology
Body Patterning
Body Patterning - genetics
Cell cycle
Cyclin G
Cyclin G - genetics
Cyclin G - physiology
Cyclins
Development Biology
Drosophila
Drosophila melanogaster
Drosophila melanogaster - genetics
Drosophila melanogaster - growth & development
Drosophila Proteins
Drosophila Proteins - genetics
Drosophila Proteins - physiology
Evolution
Evolutionary biology
Gene Regulatory Networks
Genetic Variation
Genotype
Health aspects
Homeostasis
Insects
Life Sciences
Molecular Sequence Data
Morphogenesis
Noise
Phenotype
Physiological aspects
RNA Interference
Studies
Wing
Wings, Animal - anatomy & histology
Wings, Animal - growth & development
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Summary:Morphological consistency in metazoans is remarkable given the pervasive occurrence of genetic variation, environmental effects, and developmental noise. Developmental stability, the ability to reduce developmental noise, is a fundamental property of multicellular organisms, yet its genetic bases remains elusive. Imperfect bilateral symmetry, or fluctuating asymmetry, is commonly used to estimate developmental stability. We observed that Drosophila melanogaster overexpressing Cyclin G (CycG) exhibit wing asymmetry clearly detectable by sight. Quantification of wing size and shape using geometric morphometrics reveals that this asymmetry is a genuine-but extreme-fluctuating asymmetry. Overexpression of CycG indeed leads to a 40-fold increase of wing fluctuating asymmetry, which is an unprecedented effect, for any organ and in any animal model, either in wild populations or mutants. This asymmetry effect is not restricted to wings, since femur length is affected as well. Inactivating CycG by RNAi also induces fluctuating asymmetry but to a lesser extent. Investigating the cellular bases of the phenotypic effects of CycG deregulation, we found that misregulation of cell size is predominant in asymmetric flies. In particular, the tight negative correlation between cell size and cell number observed in wild-type flies is impaired when CycG is upregulated. Our results highlight the role of CycG in the control of developmental stability in D. melanogaster. Furthermore, they show that wing developmental stability is normally ensured via compensatory processes between cell growth and cell proliferation. We discuss the possible role of CycG as a hub in a genetic network that controls developmental stability.
ISSN:1553-7404
1553-7390
1553-7404
DOI:10.1371/journal.pgen.1002314