Vertebral pattern and morphology is determined during embryonic segmentation

BackgroundThe segmented nature of the adult vertebral column is based on segmentation of the paraxial mesoderm during early embryogenesis. Disruptions to embryonic segmentation, whether caused by genetic lesions or environmental stress, result in adult vertebral pathologies. However, the mechanisms linking embryonic segmentation and the details of adult vertebral morphology are poorly understood.ResultsWe induced border defects using two approaches in zebrafish: heat stress and misregulation of embryonic segmentation genes tbx6, mesp-ba, and ripply1. We assayed vertebral length, regularity, and polarity using microscopic and radiological imaging. In population studies, we find a correlation between specific embryonic border defects and specific vertebral defects, and within individual fish, we trace specific adult vertebral defects to specific embryonic border defects.ConclusionsOur data reveal that transient disruptions of embryonic segment border formation led to significant vertebral anomalies that persist through adulthood. The spacing of embryonic borders controls the length of the vertebra. The positions of embryonic borders control the positions of ribs and arches. Embryonic borders underlie fusions and divisions between adjacent spines and ribs. These data suggest that segment borders have a dominant role in vertebral development.

Automated summary

This study investigates the relationship between embryonic segmentation and adult vertebral morphology using zebrafish models. The authors induce border defects using heat stress and misregulation of segmentation genes, and find correlations between specific embryonic border defects and specific vertebral defects in population and individual studies. The data suggests that segment borders play a dominant role in vertebral development by controlling length, position, fusion, and division of vertebrae and ribs.