The emergence of vertebrates was accompanied by a major increase in nervous system complexity, as a sophisticated brain and spinal cord evolved to process enhanced sensory input and direct co-ordinated motor output. Such complexity is achieved by an increase in cell number, a greater diversity of cell types and sophisticated mechanisms to organise them. Is has long been debated whether the “2R” whole genome duplications (WGD), which occurred just before the vertebrate split, contributed to the vertebrate increased complexity. To address this, we focus on the lamprey spinal cord –a representative of the first branching vertebrates – and relate gene duplication events to the emergence of new neural cell types. Bulk RNA sequencing and developmental studies have started to shed light on neural patterning mechanisms in lamprey, but they do not provide cellular resolution in this complex tissue. This project combines traditional molecular methods with cutting-edge single cell mRNA profiling, to explore (1) the cellular diversity of the lamprey spinal cord, (2) the molecular mechanisms that specify those cell types and (3) the evolutionary origins of these mechanisms.
The action produced a cellular atlas of the lamprey spinal cord and demonstrated that genes duplicated through whole-genome duplication (WGD) events became incorporated into distinct gene regulatory networks (GRNs), contributing to the evolution of vertebrate complexity.