Decoupling the Variances of Heterosis and Inbreeding Effects Is Evidenced in Yeast's Life-History and Proteomic Traits

Overview

Journal Genetics

Publisher Oxford University Press

Specialty Genetics

Date 2018 Dec 5

PMID 30509954

Citations 2

Authors

Marianyela Petrizzelli

Dominique de Vienne

Christine Dillmann

Affiliations

Soon will be listed here.

Abstract

Heterosis (hybrid vigor) and inbreeding depression, commonly considered as corollary phenomena, could nevertheless be decoupled under certain assumptions according to theoretical population genetics works. To explore this issue on real data, we analyzed the components of genetic variation in a population derived from a half-diallel cross between strains from and , two related yeast species involved in alcoholic fermentation. A large number of phenotypic traits, either molecular (coming from quantitative proteomics) or related to fermentation and life history, were measured during alcoholic fermentation. Because the parental strains were included in the design, we were able to distinguish between inbreeding effects, which measure phenotypic differences between inbred and hybrids, and heterosis, which measures phenotypic differences between a specific hybrid and the other hybrids sharing a common parent. The sources of phenotypic variation differed depending on the temperature, indicating the predominance of genotype-by-environment interactions. Decomposing the total genetic variance into variances of additive (intra- and interspecific) effects, of inbreeding effects, and of heterosis (intra- and interspecific) effects, we showed that the distribution of variance components defined clear-cut groups of proteins and traits. Moreover, it was possible to cluster fermentation and life-history traits into most proteomic groups. Within groups, we observed positive, negative, or null correlations between the variances of heterosis and inbreeding effects. To our knowledge, such a decoupling had never been experimentally demonstrated. This result suggests that, despite a common evolutionary history of individuals within a species, the different types of traits have been subject to different selective pressures.

Citing Articles

Data integration uncovers the metabolic bases of phenotypic variation in yeast.

Petrizzelli M, de Vienne D, Nidelet T, Nous C, Dillmann C PLoS Comput Biol. 2021; 17(7):e1009157.

PMID: 34264947 PMC: 8315545. DOI: 10.1371/journal.pcbi.1009157.

Comparative proteomic analysis reveals that the Heterosis of two maize hybrids is related to enhancement of stress response and photosynthesis respectively.

Wang D, Mu Y, Hu X, Ma B, Wang Z, Zhu L BMC Plant Biol. 2021; 21(1):34.

PMID: 33422018 PMC: 7796551. DOI: 10.1186/s12870-020-02806-5.

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