Abstract
Major evolutionary transitions describe how biological complexity arises; e.g. in evolution of complex multicellular bodies, and superorganismal insect societies. Such transitions involve the evolution of division of labour, e.g. as queen and worker castes in insect societies. Castes across different evolutionary lineages are thought to be regulated by a conserved genetic toolkit. However, this hypothesis has not been tested thoroughly across the complexity spectrum of the major transition. Here we reveal, using machine learning analyses of brain transcription, evidence of a shared genetic toolkit across the spectrum of social complexity in Vespid wasps. Whilst molecular processes underpinning the simpler societies (which likely represent the origins of social living) are conserved throughout the major transition, additional processes appear to come into play in more complex societies. Such fundamental shifts in regulatory processes with complexity may typify other major evolutionary transitions, such as the evolution of multicellularity.
Competing Interest Statement
The authors have declared no competing interest.
Abbreviations
- DOL
- division of labour
- ORF
- open reading frame
- MT
- major transition
- GO
- gene ontology
- SRA
- sequence read archive
- NCBI
- National Centre for Biotechnology Information
- BUSCO
- Benchmarking set of Universal Single-Copy Orthologs
- SVM
- support vector machine
- PCA
- principal components analysis
- Blast
- Basic local alignment search tool
- nr
- non-redundant