Developmental single-cell transcriptomics of hypothalamic POMC progenitors reveal the genetic trajectories of multiple neuropeptidergic phenotypes

Abstract

Proopiomelanocortin (POMC) neurons of the hypothalamic arcuate nucleus are essential to regulate food intake and energy balance. However, the ontogenetic transcriptional programs that specify the identity and functioning of these neurons are poorly understood. Here, we use scRNAseq to define the transcriptomes characterizing POMC progenitors in the developing hypothalamus and TRAP-seq to analyze the subsequent translatomes of mature POMC neurons. Our data show that Pomc-expressing neurons originate from multiple developmental pathways expressing distinct combinations of transcription factors. The predominant cluster, featured by high levels of Pomc and Prdm12 transcripts represents the precursor of canonical arcuate POMC neurons. Additional clusters of progenitors expressing lower levels of Pomc mature into different neuronal phenotypes characterized by distinct combinations of transcription factors, neuropeptides, processing enzymes, cell surface and nuclear receptors. We conclude that the genetic programs specifying the identity and differentiation of arcuate POMC neurons are diverse and generate a heterogeneous repertoire of neuronal phenotypes early in development that continue to evolve postnatally.