Cytoneme-mediated signaling essential for tumorigenesis.

Communication between neoplastic cells and cells of their microenvironment is critical to cancer progression. To investigate the role of cytoneme-mediated signaling as a mechanism for distributing growth factor signaling proteins between tumor and tumor-associated cells, we analyzed EGFR and RET Drosophila tumor models and tested several genetic loss-of-function conditions that impair cytoneme-mediated signaling. Neuroglian, capricious, Irk2, SCAR, and diaphanous are genes that cytonemes require during normal development. Neuroglian and Capricious are cell adhesion proteins, Irk2 is a potassium channel, and SCAR and Diaphanous are actin-binding proteins, and the only process to which they are known to contribute jointly is cytoneme-mediated signaling. We observed that diminished function of any one of these genes suppressed tumor growth and increased organism survival. We also noted that EGFR-expressing tumor discs have abnormally extensive tracheation (respiratory tubes) and ectopically express Branchless (Bnl, a FGF) and FGFR. Bnl is a known inducer of tracheation that signals by a cytoneme-mediated process in other contexts, and we determined that exogenous over-expression of dominant negative FGFR suppressed tumor growth. Our results are consistent with the idea that cytonemes move signaling proteins between tumor and stromal cells and that cytoneme-mediated signaling is required for tumor growth and malignancy.

Drosophila SCE/dRING E3-ligase inhibits apoptosis in a Dp53 dependent manner.

The Polycomb group (PcG) of proteins control developmental gene silencing and are highly conserved between flies and mammals. PcG proteins function by controlling post-translational modification of histones, such as ubiquitylation, which impacts chromatin compaction and thus gene transcription. Changes in PcG cellular levels have drastic effects on organismal development and are involved in the generation of human pathologies such as cancer. However, the mechanisms controlling their levels of expression and their physiological effects are only partially understood. In this work we describe the effects of modulating levels of SCE/dRING, a conserved E3 ubiquitin ligase and member of the PcG known to mono-ubiquitylate histone H2A. We find that inactivation of Sce induces apoptosis, an effect that is decreased in the absence of Dp53 function. However, over-expression of SCE produce no developmental effects but inhibits DP53-induced apoptosis. Thus, Sce functions as a Dp53-dependent apoptosis inhibitor. The SCE inhibition of DP53-induced apoptosis requires dRYBP, an ubiquitin binding protein and member of the PcG. Moreover, this inhibition of apoptosis involves the reduction of DP53 protein levels. Finally, high levels of SCE inhibit X-ray induced apoptosis as well as the apoptosis associated with tumor growth. We propose that SCE, together with dRYBP, inhibits apoptosis either by epigenetically regulating Dp53 transcription or by controlling the stabilization of DP53 protein levels thus promoting its ubiquitylation for proteaosomal degradation. This function may generate a homeostatic balance between apoptosis and proliferation during development that provides cell survival during the initiation and progression of disease processes.

A novel dRYBP-SCF complex functions to inhibit apoptosis in Drosophila.

A balanced response to intrinsic and extrinsic apoptotic signals is crucial to support homeostatic development and animal survival. Regulation of activation and inhibition of apoptotic pathways involves diverse mechanisms including protein ubiquitylation to control expression levels of apoptotic factors. Here we report that drosophila Ring and YY1 Binding Protein (dRYBP) protein interacts both genetically and biochemically with the E3 ubiquitin ligase SKPA, dCULLIN, F-box (SCF) complex to synergistically inhibit apoptosis in Drosophila. Further, we show that the loss of skpA function activates the intrinsic pathway of apoptosis and down-regulates the levels of expression of the anti-apoptotic DIAP1 protein. Accordingly, the apoptosis induced by inactivation of skpA and dRYBP is rescued by loss of function of the pro-apoptotic gene reaper and overexpression of DIAP1. Of interest, we also find that high levels of SKPA protein rescue the wing phenotype induced by overexpression of Reaper protein. Finally, we demonstrate that overexpression of SKPA inhibits both developmental and radiation-induced apoptosis. We propose that the function of the dRYBP-SCF complex in the inhibition of apoptosis might possibly be to control the levels of the pro-apoptotic and anti-apoptotic proteins most likely by promoting their ubiquitylation and consequently, proteasomal degradation. Given the evolutionary conservation of the dRYBP and the SCF proteins, our results suggest that their mammalian homologs may function in balancing cell survival versus cell death during normal and pathological development.

A protein kinase network regulates the function of aminophospholipid flippases.

Limited exposure of aminophospholipids on the outer leaflet of the plasma membrane is a fundamental feature of eukaryotic cells and is maintained by the action of inward-directed P-type ATPases ("flippases"). Yeast S. cerevisiae has five flippases (Dnf1, Dnf2, Dnf3, Drs2, and Neo1), but their regulation is poorly understood. Two paralogous plasma membrane-associated protein kinases, Pkh1 and Pkh2 (orthologs of mammalian PDK1), are required for viability of S. cerevisiae cells because they activate several essential downstream protein kinases by phosphorylating a critical Thr in their activation loops. Two such targets are related protein kinases Ypk1 and Ypk2 (orthologs of mammalian SGK1), which have been implicated in multiple processes, including endocytosis and coupling of membrane expansion to cell wall remodeling, but the downstream effector(s) of these kinases have been elusive. Here we show that a physiologically relevant substrate of Ypk1 is another protein kinase, Fpk1, a known flippase activator. We show that Ypk1 phosphorylates and thereby down-regulates Fpk1, and further that a complex sphingolipid counteracts the down-regulation of Fpk1 by Ypk1. Our findings delineate a unique regulatory mechanism for imposing a balance between sphingolipid content and aminophospholipid asymmetry in eukaryotic plasma membranes.

dRYBP counteracts chromatin-dependent activation and repression of transcription.

Chromatin dependent activation and repression of transcription is regulated by the histone modifying enzymatic activities of the trithorax (trxG) and Polycomb (PcG) proteins. To investigate the mechanisms underlying their mutual antagonistic activities we analyzed the function of Drosophila dRYBP, a conserved PcG- and trxG-associated protein. We show that dRYBP is itself ubiquitylated and binds ubiquitylated proteins. Additionally we show that dRYBP maintains H2A monoubiquitylation, H3K4 monomethylation and H3K36 dimethylation levels and does not affect H3K27 trimethylation levels. Further we show that dRYBP interacts with the repressive SCE and dKDM2 proteins as well as the activating dBRE1 protein. Analysis of homeotic phenotypes and post-translationally modified histones levels show that dRYBP antagonizes dKDM2 and dBRE1 functions by respectively preventing H3K36me2 demethylation and H2B monoubiquitylation. Interestingly, our results show that inactivation of dBRE1 produces trithorax-like related homeotic transformations, suggesting that dBRE1 functions in the regulation of homeotic genes expression. Our findings indicate that dRYBP regulates morphogenesis by counteracting transcriptional repression and activation. Thus, they suggest that dRYBP may participate in the epigenetic plasticity important during normal and pathological development.