Yorkie drives supercompetition by non-autonomous induction of autophagy via bantam microRNA in Drosophila.

Mutations in the tumor-suppressor Hippo pathway lead to activation of the transcriptional coactivator Yorkie (Yki), which enhances cell proliferation autonomously and causes cell death non-autonomously. While Yki-induced cell proliferation has extensively been studied, the mechanism by which Yki causes cell death in nearby wild-type cells, a phenomenon called supercompetition, and its role in tumorigenesis remained unknown. Here, we show that Yki-induced supercompetition is essential for tumorigenesis and is driven by non-autonomous induction of autophagy.

Epithelial cell-turnover ensures robust coordination of tissue growth in Drosophila ribosomal protein mutants.

Highly reproducible tissue development is achieved by robust, time-dependent coordination of cell proliferation and cell death. To study the mechanisms underlying robust tissue growth, we analyzed the developmental process of wing imaginal discs in Drosophila Minute mutants, a series of heterozygous mutants for a ribosomal protein gene. Minute animals show significant developmental delay during the larval period but develop into essentially normal flies, suggesting there exists a mechanism ensuring robust tissue growth during abnormally prolonged developmental time.

Wingless signaling regulates winner/loser status in Minute cell competition.

Cells heterozygously mutant for a ribosomal protein gene, called Minute/+ mutants, are eliminated from epithelium by cell competition when surrounded by wild-type cells. Whereas several factors that regulate Minute cell competition have been identified, the mechanisms how winner/loser status is determined and thereby triggers cell competition are still elusive. To address this, we established two assay systems for Minute cell competition, namely (i) the CORE (competitive elimination of RpS3-RNAi-expressing cells) system in which RpS3-RNAi-expressing wing pouch cells are eliminated from wild-type wing disc and (ii) the SURE (supercompetition of RpS3-expressing clones in RpS3/+ tissue) system in which RpS3-over-expressing clones generated in RpS3/+ wing disc outcompete surrounding RpS3/+ cells.