Project description:Epithelial polarity is controlled by a polarity machinery including the Rho GTPase CDC42 and Scribble/PAR. By using intestinal stem cell (ISC)-specific deletion of CDC42 in Olfm4-IRES-eGFPCreERT2;CDC42flox/flox mice, we found that ISC-initiated CDC42 loss caused a drastic hyper-proliferation of transit amplifying (TA) cells and disrupted epithelial polarity. CDC42-null crypts displayed expanded TA cell and diminished ISC populations, accompanied by elevated hippo signaling via YAP/TAZ - Ereg and mTOR activation, independent from canonical Wnt signaling. YAP/TAZ conditional knockout restored the balance of ISC/TA cell populations and crypt proliferation but did not rescue the polarity in CDC42-null small intestine. mTOR or EGFR inhibitor treatment of CDC42 KO mice exhibited similar rescuing effects without affecting YAP/TAZ signaling. Inducible ablation of Scribble in intestinal epithelial cells mimics that of CDC42 KO defects including crypt hyperplasia and hippo signaling activation. Mammalian epithelial polarity regulates ISC and TA cell fate and proliferation via a hippo-Ereg-mTOR cascade.

Project description:The atypical Protein Kinase C (aPKC) is a critical component of the PAR polarity complex, as well as of cell polarity in general. There are two paralogs of aPKC in the mammalian genome. Their expression pattern and functional role in oligodendrocyte lineage differentiation and development remains heretofore uncharacterized. Here we show that both paralogs of aPKC – PRKCI, the primary transcript of Prkci and PKMz, an alternate transcript of Prkcz – are expressed during oligodendrocyte differentiation, yet are functionally non-redundant. Asymmetric cell division and early specification of the oligodendrocyte fate stage required both paralogs. By contrast, the stage of oligodendrocyte maturation involving membrane polarization and myelination of axons continued to require PKMz, but no longer needed PRKCI. Taken together, our results indicate to a two-stage role of aPKCs and cell polarity in oligodendrocyte differentiation and development.

Project description:The atypical Protein Kinase C (aPKC) is a critical component of the PAR polarity complex, as well as of cell polarity in general. There are two paralogs of aPKC in the mammalian genome. Their expression pattern and functional role in oligodendrocyte lineage differentiation and development remains heretofore uncharacterized. Here we show that both paralogs of aPKC – PRKCI, the primary transcript of Prkci and PKMz, an alternate transcript of Prkcz – are expressed during oligodendrocyte differentiation, yet are functionally non-redundant. Asymmetric cell division and early specification of the oligodendrocyte fate stage required both paralogs. By contrast, the stage of oligodendrocyte maturation involving membrane polarization and myelination of axons continued to require PKMz, but no longer needed PRKCI. Taken together, our results indicate to a two-stage role of aPKCs and cell polarity in oligodendrocyte differentiation and development.

Project description:The transition from totipotency to pluripotency and subsequent differentiation in the mammalian embryo segregates embryonic and extra-embryonic progenitor cells. Despite its central importance, it remains entirely unknown how the timing of this major process is regulated. Here, we uncover that Tfap2c and Tead4 mediated transcriptional activity work in concert with the Rho GTPase mediated activation of actomyosin at the 8-cell stage as the upstream factors that trigger cell polarization and hence the first cell fate segregation in the mouse embryo. We show that they act together to control the establishment of cell polarisation, the activation of polarity dependent Hippo signalling, and the early expression of transcription factors required for the differentiation of the first extra-embryonic lineage. These results define the key step in the transition from totipotency to pluripotency and its relationship to the first cell fate specification event in the mouse embryo.

Project description:Wnt signaling is a highly conserved metazoan pathway that plays a crucial role in cell-fate determination and morphogenesis during development. Wnt ligands can induce disparate cellular responses. The exact mechanism behind these different outcomes is not fully understood but may be due to interactions with different receptors on the cell membrane. PTK7/Otk is a transmembrane receptor that is implicated in various developmental and physiological processes including cell polarity, cell migration, and invasion. Here we examine two roles of Otk1 and Otk2 in patterning and neurogenesis. We find that Otk1 is a positive regulator of signaling and Otk2 functions as its inhibitor. We propose that PTK7/Otk functions in signaling and in particular cell migration and polarity contributing to the diversity of cellular responses seen in Wnt-mediated processes.

Project description:A subset of cancer cells are intrinsically sensitive to inhibitors targeting PARG, the poly(ADP-ribose) glycohydrolase that degrades PAR chains. Sensitivity is accompanied by persistent DNA replication stress, and can be induced by inhibition of TIMELESS, a replisome accelerator. However, the nature of the oncogenic vulnerability responsible for intrinsic sensitivity remains undetermined. To understand PARG activity dependency, we analyzed Timeless model systems and intrinsically sensitive ovarian cancer cells. We show that nucleoside supplementation rescues all phenotypes associated with PARG inhibitor sensitivity, including replisome speed and fork-restart ability, S-phase completion and mitotic entry, proliferation dynamics and clonogenic potential, in both a TIMELESShaploinsufficient model and intrinsically sensitive cells. Importantly nucleoside supplementation restores PARG inhibitor resistance without reverting PAR chain accumulation, indicating that sensitivity correlates with PAR chain intolerance. We show that inhibition of thymidylate synthase, an enzyme required for dNTP homeostasis, induces PARG-dependency, and, using label-free, quantitative proteomics, we show that PKMYT1, a negative regulator of CDK1, is overexpressed in PARG inhibitor-sensitive cells. Together, these observations suggest that PARG inhibitor sensitivity reflects an inability to control replisome speed and/or maintain helicase-polymerase coupling in response to nucleotide imbalances, in turn applying selective pressure on mitotic entry controls to maintain genome integrity.

Project description:Smad2 and Smad3 (Smad2/3) primarily mediates the transforming growth factor-β (TGF-β) signaling that drives cell proliferation, differentiation, and migration. The dynamics of the Smad2/3 phosphorylation provides the key mechanism for regulating the TGF-β signaling pathway. Here we identified NLK as a novel regulator of TGF-β signaling pathway via modulating the phosphorylation of Smad2/3 in the linker region.

Project description:Correct neural progenitor fate determination requires the coordination of extrinsic fate determinant signals with intrinsic responses. Post-translational modifications dynamically alter protein function and so are ideally situated to regulate development. Here we show that the deubiquitylaying enzyme, Usp9x modulates both intrinsic and extrinsic regulators of mouse neural progenitors. Nestin-cre mediated deletion of Usp9x from neural progenitors results in a transient disruption of cell adhesion and apical-basal polarity as well as the premature differentiation of intermediate neural progenitors. Ablation of Usp9x also significantly increased β-catenin protein levels, especially S33/S37/T41 phospho-β-catenin, and Wnt signalling. Usp9x was found to be part of the β-catenin destruction complex and loss of Usp9x affects destruction complex composition. Notch signalling was also increased in Usp9x ablated neural progenitors, coinciding with decreased Itch and Numb, and increased Notch intracellular domain protein levels. Usp9x co-localized and immunopreciptiated with Numb from neural progenitors suggesting it is required for Numb stabilisation. These data suggest Usp9x plays a role in coordinating intrinsic responses to extrinsic signals during neural development.

Project description:Determination of RNAs bound by wildtype and P525L mutant FUS in human iPSC-derived motoneurons using PAR-CLIP (Photoactivatable Ribonucleoside-Enhanced Crosslinking and Immunoprecipitation)

Project description:Matrix reverses immortalization-mediated stem cell fate determination