The mechanical journey of primordial germ cells.

Abstract

Primordial germ cells (PGCs) are the earliest progenitors of germline cells of the gonads in animals. The tissues that arise from primordial germ cells give rise to the male as well as female gametes and are thus responsible for transmitting genetic information to subsequent generations. Their development from single cells to fully formed tissues has thus been of great importance. In most higher animals, PGCs are initially specified at a site away from the gonads. They then migrate across multiple tissue contexts to reach a mesodermal mass of cells called the genital ridge, where they associate with somatic cells to form the sex-specific reproductive organs. This migratory behavior has been studied extensively to identify the various tissues PGCs interact with and how this might affect their development. A crucial point overlooked by classical studies has been the physical environment experienced by PGCs as they migrate and the mechanical challenges they might encounter. It has long been understood that migrating cells can sense and adapt to physical forces around them via a variety of mechanisms. Studies have also shown that these mechanical signals can guide stem cell fate. In this review, we summarize the mechanical microenvironment of migrating PGCs in different organisms. We describe how cells can adapt to this environment and how this adaptation can influence cell fate. We propose that mechanical signals play a crucial role in normal development of the germline and shed light on this unexplored area of developmental biology.