Abstract
During vertebrate embryonic development, early skin, muscle, and bone progenitor populations organize into segments known as somites. Defects in this conserved process of segmentation lead to skeletal and muscular deformities, such as congenital scoliosis, a curvature of the spine caused by vertebral defects. Environmental stresses such as hypoxia or heat shock produce segmentation defects, and significantly increase the penetrance and severity of vertebral defects in genetically susceptible individuals. Here we show that a brief exposure to a high osmolarity solution causes reproducible segmentation defects in developing zebrafish (Danio rerio) embryos. Both osmotic shock and heat shock produce border defects in a dose-dependent manner, with an increase in both frequency and severity of defects. We also show that osmotic treatment has a delayed effect on somite development, similar to that observed in heat shocked embryos. Our results establish osmotic shock as an alternate experimental model for stress, affecting segmentation in a manner comparable to other known environmental stressors. The similar effects of these two distinct environmental stressors support a model in which a variety of cellular stresses act through a related response pathway that leads to disturbances in the segmentation process.
Highlights
IntroductionThese segments arise during early embryonic development, when the paraxial mesoderm becomes subdivided into somites
We show that osmotic treatment has a delayed effect, similar to that observed in heat shocked embryos
Embryos exhibited a wide array of defects from mild to severe
Summary
These segments arise during early embryonic development, when the paraxial mesoderm becomes subdivided into somites. The molecular and cellular mechanisms of somite development are generally conserved between all vertebrates that have been examined [1]. Unsegmented presomitic mesoderm (PSM) expresses a set of genes—the segmentation clock—at levels that oscillate with the same temporal periodicity as segmentation. Near the anterior end of the PSM, a gene regulatory network involving the tbx, mesp, and ripply genes is activated. This network is part of a reading head that translates the information from the clock genes and the wavefront into the morphogenetic process of segmentation
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