Origin and Development of the Germ Line in Sea Stars

Overview

Journal Genesis

Specialties Biology
Molecular Biology

Date 2014 Mar 21

PMID 24648114

Citations 11

Authors

Gary M Wessel

Tara Fresques

Masato Kiyomoto

Mamiko Yajima

Vanesa Zazueta

Affiliations

Soon will be listed here.

Abstract

This review summarizes and integrates our current understanding of how sea stars make gametes. Although little is known of the mechanism of germ line formation in these animals, recent results point to specific cells and to cohorts of molecules in the embryos and larvae that may lay the ground work for future research efforts. A coelomic outpocketing forms in the posterior of the gut in larvae, referred to as the posterior enterocoel (PE), that when removed, significantly reduces the number of germ cell later in larval growth. This same PE structure also selectively accumulates several germ-line associated factors-vasa, nanos, piwi-and excludes factors involved in somatic cell fate. Since its formation is relatively late in development, these germ cells may form by inductive mechanisms. When integrated into the morphological observations of germ cells and gonad development in larvae, juveniles, and adults, the field of germ line determination appears to have a good model system to study inductive germ line determination to complement the recent work on the molecular mechanisms in mice. We hope this review will also guide investigators interested in germ line determination and regulation of the germ line into how these animals can help in this research field. The review is not intended to be comprehensive-sea star reproduction has been studied for over 100 years and many reviews are comprehensive in their coverage of, for example, seasonal growth of the gonads in response to light, nutrient, and temperature. Rather the intent of this review is to help the reader focus on new experimental results attached to the historical underpinnings of how the germ cell functions in sea stars with particular emphasis to clarify the important areas of priority for future research.

Citing Articles

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Annelids as models of germ cell and gonad regeneration.

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Gene regulatory divergence amongst echinoderms underlies appearance of pigment cells in sea urchin development.

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A conserved node in the regulation of Vasa between an induced and an inherited program of primordial germ cell specification.

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