Person:

Salic, Adrian

In vertebrates, Hedgehog (Hh) signaling initiated in primary cilia activates the membrane protein Smoothened (Smo) and leads to activation of Gli proteins, the transcriptional effectors of the pathway. In the absence of signaling, Gli proteins are inhibited by the cytoplasmic protein Suppressor of Fused (SuFu). It is unclear how Hh activates Gli and whether it directly regulates SuFu. We find that Hh stimulation quickly recruits endogenous SuFu–Gli complexes to cilia, suggesting a model in which Smo activates Gli by relieving inhibition by SuFu. In support of this model, we find that Hh causes rapid dissociation of the SuFu–Gli complex, thus allowing Gli to enter the nucleus and activate transcription. Activation of protein kinase A (PKA), an inhibitor of Hh signaling, blocks ciliary localization of SuFu–Gli complexes, which in turn prevents their dissociation by signaling. Our results support a simple mechanism in which Hh signals at vertebrate cilia cause dissociation of inactive SuFu–Gli complexes, a process inhibited by PKA.

Oxysterols bind the seven-spanner transmembrane protein Smoothened and potently activate vertebrate Hedgehog signaling, a pathway essential in embryonic development, adult stem cell maintenance and cancer. It is unknown, however, if oxysterols are important for normal vertebrate Hedgehog signaling, and whether antagonizing oxysterols can inhibit the Hedgehog pathway. We developed azasterols that block Hedgehog signaling by binding the oxysterol-binding site of Smoothened. We show that the binding site for oxysterols and azasterols maps to the extracellular, cysteine-rich domain of Smoothened, and is completely separable from the site bound by other small molecule modulators, located within the heptahelical bundle of Smoothened. Smoothened mutants in which oxysterol binding is abolished no longer respond to oxysterols, and cannot be maximally activated by the Hedgehog ligand. Our results show that oxysterol binding to vertebrate Smoothened is required for normal Hedgehog signaling, and that targeting the oxysterol binding site is an effective strategy to inhibit Smoothened.

Many aspects of cellular physiology remain unstudied in somatic stem cells. For example, there are almost no data on protein synthesis in any somatic stem cell. We found that the amount of protein synthesized per hour in haematopoietic stem cells (HSCs) in vivo was lower than in most other haematopoietic cells, even if we controlled for differences in cell cycle status or forced HSCs to undergo self-renewing divisions. Reduced ribosome function in Rpl24Bst/+ mice further reduced protein synthesis in HSCs and impaired HSC function. Pten deletion increased protein synthesis in HSCs but also reduced HSC function. Rpl24Bst/+ cell-autonomously rescued the effects of Pten deletion in HSCs, blocking the increase in protein synthesis, restoring HSC function, and delaying leukaemogenesis. Pten deficiency thus depletes HSCs and promotes leukaemia partly by increasing protein synthesis. Either increased or decreased protein synthesis impairs HSC function.