Gene pleiotropy constrains gene expression changes in ﬁsh adapted to different thermal conditions
Spiros Papakostas, L. Asbjørn Vøllestad et al. in Nature Communications. Open Access.
Spiros Papakostas, L. Asbjørn Vøllestad, Matthieu Bruneaux, Tutku Aykanat, Joost Vanoverbeke, Mei Ning, Craig R. Primmer and Erica H. Leder
Understanding the factors that shape the evolution of gene expression is a central goal in biology, but the molecular mechanisms behind this remain controversial. A related major goal is ascertaining how such factors may affect the adaptive potential of a species or population. Here we demonstrate that temperature-driven gene expression changes in ﬁsh adapted to differing thermal environments are constrained by the level of gene pleiotropy estimated by either the number of protein interactions or gene biological processes. Genes with low pleiotropy levels were the main drivers of both plastic and evolutionary global expression proﬁle changes, while highly pleiotropic genes had limited expression response to temperature treatment. Our study provides critical insights into the molecular mechanisms by which natural populations can adapt to changing environments. In addition to having important implications for climate change adaptation, these results suggest that gene pleiotropy should be considered more carefully when interpreting expression proﬁling data.
Volume 5, Article number 407
Published June 10, 2014 1:42 PM