Litcius/Paper detail

Control of spinal motor neuron terminal differentiation through sustained Hoxc8 gene activity

Catarina Catela, Yihan Chen, Yifei Weng, Kailong Wen, Paschalis Kratsios

2022eLife39 citationsDOIOpen Access PDF

Abstract

Spinal motor neurons (MNs) constitute cellular substrates for several movement disorders. Although their early development has received much attention, how spinal MNs become and remain terminally differentiated is poorly understood. Here, we determined the transcriptome of mouse MNs located at the brachial domain of the spinal cord at embryonic and postnatal stages. We identified novel transcription factors (TFs) and terminal differentiation genes (e.g. ion channels, neurotransmitter receptors, adhesion molecules) with continuous expression in MNs. Interestingly, genes encoding homeodomain TFs (e.g. HOX, LIM), previously implicated in early MN development, continue to be expressed postnatally, suggesting later functions. To test this idea, we inactivated Hoxc8 at successive stages of mouse MN development and observed motor deficits. Our in vivo findings suggest that Hoxc8 is not only required to establish, but also maintain expression of several MN terminal differentiation markers. Data from in vitro generated MNs indicate Hoxc8 acts directly and is sufficient to induce expression of terminal differentiation genes. Our findings dovetail recent observations in Caenorhabditis elegans MNs, pointing toward an evolutionarily conserved role for Hox in neuronal terminal differentiation.

Topics & Concepts

BiologyHox geneHomeoboxTranscriptomeSpinal cordMotor neuronNeuroscienceEmbryonic stem cellTranscription factorCell biologyGene expressionGeneGene isoformGDF7Cellular differentiationRegulation of gene expressionLIM domainPremovement neuronal activityTranscription (linguistics)NeuronGeneticsEMX2In vitroNeurotransmitterCentral nervous systemCaenorhabditis elegansTerminal (telecommunication)Nervous systemMotor behaviorNeurogenetic and Muscular Disorders ResearchDevelopmental Biology and Gene RegulationZebrafish Biomedical Research Applications