Patched-mediated regulation of Smoothened trafficking and activity by Lipophorin-derived lipids

Hedgehog is a lipid-linked morphogen that is carried on lipoprotein particles and that regulates both patterning and proliferation in a wide variety of vertebrate and invertebrate tissues. Hyperactivity of Hedgehog signaling causes numerous forms of cancer. Hedgehog acts by binding to its receptor Patched, relieving the suppression of Smoothened and initiating Smoothened signaling. The mechanism by which Patched represses Smoothened has been unclear, but correlates with reduced Smoothened levels on the basolateral membrane. The structural homology of Patched with the Niemann-Pick-Type C1 protein and bacterial transmembrane transporters suggests that Patched might regulate lipid trafficking to repress Smoothened. However, no endogenous lipid regulators of Smoothened have yet been identified, nor has it ever been shown that Patched actually controls lipid trafficking. This work shows that, in Drosophila melanogaster, the Sterol-Sensing Domain of Patched regulates Smoothened trafficking from Patched-positive endosomes. Furthermore, it demonstrates that Patched recruits internalized lipoproteins to Patched-positive endosomes. Thereby, Patched regulates the efflux of specific lipoprotein-derived lipids from this compartment via its Sterol-Sensing Domain and utilizes these lipids to destabilize Smoothened on the basolateral membrane. We propose that Patched normally promotes Smoothened degradation and subsequently downregulates its activity by changing the lipid composition of endosomes through which Smoothened passes. For this purpose, Patched utilizes a specific lipid – possibly a modified sterol or sphingolipid – derived from lipoproteins. Further, we suggest that the presence of Hedgehog on lipoprotein particles inhibits utilization of their lipids by Patched

Nutrient-Deprived Retinal Progenitors Proliferate in Response to Hypoxia: Interaction of the HIF-1 and mTOR Pathway.

At a cellular level, nutrients are sensed by the mechanistic Target of Rapamycin (mTOR). The response of cells to hypoxia is regulated via action of the oxygen sensor Hypoxia-Inducible Factor 1 (HIF-1). During development, injury and disease, tissues might face conditions of both low nutrient supply and low oxygen, yet it is not clear how cells adapt to both nutrient restriction and hypoxia, or how mTOR and HIF-1 interact in such conditions. Here we explore this question in vivo with respect to cell proliferation using the ciliary marginal zone (CMZ) of Xenopus. We found that both nutrient-deprivation and hypoxia cause retinal progenitors to decrease their proliferation, yet when nutrient-deprived progenitors are exposed to hypoxia there is an unexpected rise in cell proliferation. This increase, mediated by HIF-1 signalling, is dependent on glutaminolysis and reactivation of the mTOR pathway. We discuss how these findings in non-transformed tissue may also shed light on the ability of cancer cells in poorly vascularised solid tumours to proliferate.Wellcome Trust (Grant ID: 100329/Z/12/Z)This is the final version of the article. It first appeared from MDPI via http://dx.doi.org/10.3390/jdb402001

Nutrient-Deprived Retinal Progenitors Proliferate in Response to Hypoxia: Interaction of the HIF-1 and mTOR Pathway

At a cellular level, nutrients are sensed by the mechanistic Target of Rapamycin (mTOR). The response of cells to hypoxia is regulated via action of the oxygen sensor Hypoxia-Inducible Factor 1 (HIF-1). During development, injury and disease, tissues might face conditions of both low nutrient supply and low oxygen, yet it is not clear how cells adapt to both nutrient restriction and hypoxia, or how mTOR and HIF-1 interact in such conditions. Here we explore this question in vivo with respect to cell proliferation using the ciliary marginal zone (CMZ) of Xenopus. We found that both nutrient-deprivation and hypoxia cause retinal progenitors to decrease their proliferation, yet when nutrient-deprived progenitors are exposed to hypoxia there is an unexpected rise in cell proliferation. This increase, mediated by HIF-1 signalling, is dependent on glutaminolysis and reactivation of the mTOR pathway. We discuss how these findings in non-transformed tissue may also shed light on the ability of cancer cells in poorly vascularised solid tumours to proliferate