Publication:20161202114644
From Bioinformatics Core Wiki
| Publication | |
|---|---|
| URL | https://www.ncbi.nlm.nih.gov/pubmed/26483466 |
| Title | Molecular signatures of plastic phenotypes in two eusocial insect species with simple societies
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| Authors | Solenn Patalano, Anna Vlasova, Chris Wyatt, Philip Ewels, Francisco Camara, Pedro G. Ferreira, Claire L. Asher, Tomasz P. Jurkowski, Anne Segonds-Pichon, Martin Bachman, Irene González-Navarrete, André E. Minoche, Felix Krueger, Ernesto Lowy, Marina Marcet-Houben, Jose Luis Rodriguez-Ales, Fabio S. Nascimento, Shankar Balasubramanian, Toni Gabaldon, James E. Tarver, Simon Andrews, Heinz Himmelbauer, William O. H. Hughes, Roderic Guigó, Wolf Reik, Seirian Sumner |
| Date | 2015-11-10
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| Publisher | Proceedings of the National Academy of Sciences of the United States of America |
| DOI | 10.1073/pnas.1515937112 |
| Tag | Animals, Ants, Base Sequence, Brain, DNA Methylation, Gene Expression Regulation, Genome, Insect, Hierarchy, Social, High-Throughput Nucleotide Sequencing, MicroRNAs, Models, Genetic, Molecular Sequence Data, Phenotype, Social Behavior, Transcriptome, Wasps, DNA methylation, genome sequencing, phenotypic plasticity, social evolution, transcriptomes |
Abstract:
Phenotypic plasticity is important in adaptation and shapes the evolution of organisms. However, we understand little about what aspects of the genome are important in facilitating plasticity. Eusocial insect societies produce plastic phenotypes from the same genome, as reproductives (queens) and nonreproductives (workers). The greatest plasticity is found in the simple eusocial insect societies in which individuals retain the ability to switch between reproductive and nonreproductive phenotypes as adults. We lack comprehensive data on the molecular basis of plastic phenotypes. Here, we sequenced genomes, microRNAs (miRNAs), and multiple transcriptomes and methylomes from individual brains in a wasp (Polistes canadensis) and an ant (Dinoponera quadriceps) that live in simple eusocial societies. In both species, we found few differences between phenotypes at the transcriptional level, with little functional specialization, and no evidence that phenotype-specific gene expression is driven by DNA methylation or miRNAs. Instead, phenotypic differentiation was defined more subtly by nonrandom transcriptional network organization, with roles in these networks for both conserved and taxon-restricted genes. The general lack of highly methylated regions or methylome patterning in both species may be an important mechanism for achieving plasticity among phenotypes during adulthood. These findings define previously unidentified hypotheses on the genomic processes that facilitate plasticity and suggest that the molecular hallmarks of social behavior are likely to differ with the level of social complexity.
Phenotypic plasticity is important in adaptation and shapes the evolution of organisms. However, we understand little about what aspects of the genome are important in facilitating plasticity. Eusocial insect societies produce plastic phenotypes from the same genome, as reproductives (queens) and nonreproductives (workers). The greatest plasticity is found in the simple eusocial insect societies in which individuals retain the ability to switch between reproductive and nonreproductive phenotypes as adults. We lack comprehensive data on the molecular basis of plastic phenotypes. Here, we sequenced genomes, microRNAs (miRNAs), and multiple transcriptomes and methylomes from individual brains in a wasp (Polistes canadensis) and an ant (Dinoponera quadriceps) that live in simple eusocial societies. In both species, we found few differences between phenotypes at the transcriptional level, with little functional specialization, and no evidence that phenotype-specific gene expression is driven by DNA methylation or miRNAs. Instead, phenotypic differentiation was defined more subtly by nonrandom transcriptional network organization, with roles in these networks for both conserved and taxon-restricted genes. The general lack of highly methylated regions or methylome patterning in both species may be an important mechanism for achieving plasticity among phenotypes during adulthood. These findings define previously unidentified hypotheses on the genomic processes that facilitate plasticity and suggest that the molecular hallmarks of social behavior are likely to differ with the level of social complexity.
