Feedback control of organ size precision is mediated by BMP2-regulated apoptosis in the Drosophila eye.

Biological processes are intrinsically noisy, and yet, the result of development-like the species-specific size and shape of organs-is usually remarkably precise. This precision suggests the existence of mechanisms of feedback control that ensure that deviations from a target size are minimized. Still, we have very limited understanding of how these mechanisms operate. Here, we investigate the problem of organ size precision using the Drosophila eye. The size of the adult eye depends on the rates at which eye progenitor cells grow and differentiate. We first find that the progenitor net growth rate results from the balance between their proliferation and apoptosis, with this latter contributing to determining both final eye size and its variability. In turn, apoptosis of progenitor cells is hampered by Dpp, a BMP2/4 signaling molecule transiently produced by early differentiating retinal cells. Our genetic and computational experiments show how the status of retinal differentiation is communicated to progenitors through the differentiation-dependent production of Dpp, which, by adjusting the rate of apoptosis, exerts a feedback control over the net growth of progenitors to reduce final eye size variability.

Visualization and Quantification of Drosophila Larval Ovaries.

The morphogenesis of the ovarian germline stem cell (GSC) niche during larval stages in Drosophila provides the initial cellular and molecular basis for female gamete production in the adult. During larval instars, the Drosophila female gonad matures gradually from a round structure enclosing primordial germ cells (PGCs) and somatic cells into a functional organ containing GSC populations in their niches that later in adult stages support oogenesis. In this chapter, we describe a technique for dissecting, staining, and analyzing gonads from female Drosophila larvae and early pupae, offering the possibility of a direct view of the morphogenesis of an ovarian niche.

A Yap-dependent mechanoregulatory program sustains cell migration for embryo axis assembly.

The assembly of the embryo's primary axis is a fundamental landmark for the establishment of the vertebrate body plan. Although the morphogenetic movements directing cell convergence towards the midline have been described extensively, little is known on how gastrulating cells interpret mechanical cues. Yap proteins are well-known transcriptional mechanotransducers, yet their role in gastrulation remains elusive. Here we show that the double knockout of yap and its paralog yap1b in medaka results in an axis assembly failure, due to reduced displacement and migratory persistence in mutant cells. Accordingly, we identified genes involved in cytoskeletal organization and cell-ECM adhesion as potentially direct Yap targets. Dynamic analysis of live sensors and downstream targets reveal that Yap is acting in migratory cells, promoting cortical actin and focal adhesions recruitment. Our results indicate that Yap coordinates a mechanoregulatory program to sustain intracellular tension and maintain the directed cell migration for embryo axis development.