Litcius/Paper detail

A 2020 view of tension-based cortical morphogenesis

David C. Van Essen

2020Proceedings of the National Academy of Sciences141 citationsDOIOpen Access PDF

Abstract

385, 313-318 (1997)]. Tension-based morphogenesis (TBM) is a conceptually simple and general hypothesis based on physical forces that help shape all living things. Moreover, if each axon and dendrite strive to shorten while preserving connectivity, aggregate wiring length would remain low. TBM can explain key aspects of how the cerebral and cerebellar cortices remain thin, expand in surface area, and acquire their distinctive folds. This article reviews progress since 1997 relevant to TBM and other candidate morphogenetic mechanisms. At a cellular level, studies of diverse cell types in vitro and in vivo demonstrate that tension plays a major role in many developmental events. At a tissue level, I propose a differential expansion sandwich plus (DES+) revision to the original TBM model for cerebral cortical expansion and folding. It invokes tangential tension and "sulcal zipping" forces along the outer cortical margin as well as tension in the white matter core, together competing against radially biased tension in the cortical gray matter. Evidence for and against the DES+ model is discussed, and experiments are proposed to address key tenets of the DES+ model. For cerebellar cortex, a cerebellar multilayer sandwich (CMS) model is proposed that can account for many distinctive features, including its unique, accordion-like folding in the adult, and experiments are proposed to address its specific tenets.

Topics & Concepts

MorphogenesisNeuroscienceWhite matterTension (geology)Cerebral cortexBiologyComputer scienceAnatomyPhysicsMedicineCompression (physics)RadiologyThermodynamicsMagnetic resonance imagingBiochemistryGeneCellular Mechanics and InteractionsMicrotubule and mitosis dynamicsMicro and Nano Robotics