Drosophila ribosomal protein mutants control tissue growth non-autonomously via effects on the prothoracic gland and ecdysone.

The ribosome is critical for all aspects of cell growth due to its essential role in protein synthesis. Paradoxically, many Ribosomal proteins (Rps) act as tumour suppressors in Drosophila and vertebrates. To examine how reductions in Rps could lead to tissue overgrowth, we took advantage of the observation that an RpS6 mutant dominantly suppresses the small rough eye phenotype in a cyclin E hypomorphic mutant (cycE(JP)). We demonstrated that the suppression of cycE(JP) by the RpS6 mutant is not a consequence of restoring CycE protein levels or activity in the eye imaginal tissue. Rather, the use of UAS-RpS6 RNAi transgenics revealed that the suppression of cycE(JP) is exerted via a mechanism extrinsic to the eye, whereby reduced Rp levels in the prothoracic gland decreases the activity of ecdysone, the steroid hormone, delaying developmental timing and hence allowing time for tissue and organ overgrowth. These data provide for the first time a rationale to explain the counter-intuitive organ overgrowth phenotypes observed for certain members of the Minute class of Drosophila Rp mutants. They also demonstrate how Rp mutants can affect growth and development cell non-autonomously.

Input from Ras is required for maximal PI(3)K signalling in Drosophila.

Class I phosphoinositide 3-kinases (PI(3)Ks) are activated through associated adaptor molecules in response to G protein-coupled and tyrosine kinase receptor signalling. They contain Ras-binding domains (RBDs) and can also be activated through direct association with active GTP-bound Ras. The ability of Ras to activate PI(3)K has been established in vitro and by overexpression analysis, but its relevance for normal PI(3)K function in vivo is unknown. The Drosophila class I PI(3)K, Dp110, is activated by nutrient-responsive insulin signalling and modulates growth, oogenesis and metabolism. To investigate the importance of Ras-mediated PI(3)K activation for normal PI(3)K function, we replaced Dp110 with Dp110(RBD), which is unable to bind to Ras but otherwise biochemically normal. We found that Ras-mediated Dp110 regulation is dispensable for viability. However, egg production, which requires large amounts of growth, is dramatically lowered in Dp110(RBD) flies. Furthermore, insulin cannot maximally activate PI(3)K signalling in Dp110(RBD) imaginal discs and Dp110(RBD) flies are small. Thus, Dp110 integrates inputs from its phosphotyrosine-binding adaptor and Ras to achieve maximal PI(3)K signalling in specific biological situations.

A genetic screen for dominant modifiers of a small-wing phenotype in Drosophila melanogaster identifies proteins involved in splicing and translation.

Studies in the fly, Drosophila melanogaster, have revealed that several signaling pathways are important for the regulation of growth. Among these, the insulin receptor/phosphoinositide 3-kinase (PI3K) pathway is remarkable in that it affects growth and final size without disturbing pattern formation. We have used a small-wing phenotype, generated by misexpression of kinase-dead PI3K, to screen for novel mutations that specifically disrupt organ growth in vivo. We identified several complementation groups that dominantly enhance this small-wing phenotype. Meiotic recombination in conjunction with visible markers and single-nucleotide polymorphisms (SNPs) was used to map five enhancers to single genes. Two of these, nucampholin and prp8, encode pre-mRNA splicing factors. The three other enhancers encode factors required for mRNA translation: pixie encodes the Drosophila ortholog of yeast RLI1, and RpL5 and RpL38 encode proteins of the large ribosomal subunit. Interestingly, mutations in several other ribosomal protein-encoding genes also enhance the small-wing phenotype used in the original screen. Our work has therefore identified mutations in five previously uncharacterized Drosophila genes and provides in vivo evidence that normal organ growth requires optimal regulation of both pre-mRNA splicing and mRNA translation.