Explore the vast range of titles available.

RAS is frequently mutated in human cancers and has opposing effects on autophagy and tumorigenesis. Identifying determinants of the cellular responses to RAS is therefore vital in cancer research. Here, we show that autophagic activity dictates the cellular response to oncogenic RAS. N-terminal Apoptosis-stimulating of p53 protein 2 (ASPP2) mediates RAS-induced senescence and inhibits autophagy. Oncogenic RAS-expressing ASPP2 ⁽Δ³/Δ³⁾ mouse embryonic fibroblasts that escape senescence express a high level of ATG5/ATG12. Consistent with the notion that autophagy levels control the cellular response to oncogenic RAS, overexpressing ATG5, but not autophagy-deficient ATG5 mutant K130R, bypasses RAS-induced senescence, whereas ATG5 or ATG3 deficiency predisposes to it. Mechanistically, ASPP2 inhibits RAS-induced autophagy by competing with ATG16 to bind ATG5/ATG12 and preventing ATG16/ATG5/ATG12 formation. Hence, ASPP2 modulates oncogenic RAS-induced autophagic activity to dictate the cellular response to RAS: to proliferate or senesce.

Understanding urothelial stem cell biology and differentiation has been limited by the lack of methods for their unlimited propagation. Here, we establish mouse urothelial organoids that can be maintained uninterruptedly for >1 year. Organoid growth is dependent on EGF and Wnt activators. High CD49f/ITGA6 expression features a subpopulation of organoid-forming cells expressing basal markers. Upon differentiation, multilayered organoids undergo reduced proliferation, decreased cell layer number, urothelial program activation, and acquisition of barrier function. Pharmacological modulation of PPARγ and EGFR promotes differentiation. RNA sequencing highlighted genesets enriched in proliferative organoids (i.e. ribosome) and transcriptional networks involved in differentiation, including expression of Wnt ligands and Notch components. Single-cell RNA sequencing (scRNA-Seq) analysis of the organoids revealed five clusters with distinct gene expression profiles. Together with the use of γ-secretase inhibitors, scRNA-Seq confirms that Notch signaling is required for differentiation. Urothelial organoids provide a powerful tool to study cell regeneration and differentiation. The biology of the urothelium has been difficult to study given the lack of methods to propagate these cells. Here, the authors generate mouse urothelial organoids derived from bladder urothelial cells with high CD49f/ITGA6 and define what regulates urothelium differentiation, which is PPARγ, EGFR and Notch signalling.

The urothelium is a stratified epithelium composed of basal cells, one or more layers of intermediate cells, and an upper layer of differentiated umbrella cells. Most bladder cancers (BLCA) are urothelial carcinomas. Loss of urothelial lineage fidelity results in altered differentiation, highlighted by the taxonomic classification into basal and luminal tumors. There is a need to better understand the urothelial transcriptional networks. To systematically identify transcription factors (TFs) relevant for urothelial identity, we defined highly expressed TFs in normal human bladder using RNA-Seq data and inferred their genomic binding using ATAC-Seq data. To focus on epithelial TFs, we analyzed RNA-Seq data from patient-derived organoids recapitulating features of basal/luminal tumors. We classified TFs as “luminal-enriched”, “basal-enriched” or “common” according to expression in organoids. We validated our classification by differential gene expression analysis in Luminal Papillary vs. Basal/Squamous tumors. Genomic analyses revealed well-known TFs associated with luminal (e.g., PPARG, GATA3, FOXA1) and basal (e.g., TP63, TFAP2) phenotypes and novel candidates to play a role in urothelial differentiation or BLCA (e.g., MECOM, TBX3). We also identified TF families (e.g., KLFs, AP1, circadian clock, sex hormone receptors) for which there is suggestive evidence of their involvement in urothelial differentiation and/or BLCA. Genomic alterations in these TFs are associated with BLCA. We uncover a TF network involved in urothelial cell identity and BLCA. We identify novel candidate TFs involved in differentiation and cancer that provide opportunities for a better understanding of the underlying biology and therapeutic intervention.

Francisco Real and colleagues report exome sequencing in urothelial bladder tumors. They show that STAG2 , a subunit of the cohesin complex, is recurrently mutated and provide evidence that STAG2 loss does not lead to increases in aneuploidy. Urothelial bladder cancer (UBC) is heterogeneous at the clinical, pathological and genetic levels. Tumor invasiveness (T) and grade (G) are the main factors associated with outcome and determine patient management 1 . A discovery exome sequencing screen ( n = 17), followed by a prevalence screen ( n = 60), identified new genes mutated in this tumor coding for proteins involved in chromatin modification ( MLL2 , ASXL2 and BPTF ), cell division ( STAG2 , SMC1A and SMC1B ) and DNA repair ( ATM , ERCC2 and FANCA ). STAG2 , a subunit of cohesin, was significantly and commonly mutated or lost in UBC, mainly in tumors of low stage or grade, and its loss was associated with improved outcome. Loss of expression was often observed in chromosomally stable tumors, and STAG2 knockdown in bladder cancer cells did not increase aneuploidy. STAG2 reintroduction in non-expressing cells led to reduced colony formation. Our findings indicate that STAG2 is a new UBC tumor suppressor acting through mechanisms that are different from its role in preventing aneuploidy.

Oncogene-induced senescence represents a key tumor suppressive mechanism. Here, we show that Ras oncogene-induced senescence can be mediated by the recently identified haploinsufficient tumor suppressor apoptosis-stimulating protein of p53 (ASPP) 2 through a novel and p53/p19 Arf /p21 waf1/cip1 -independent pathway. ASPP2 suppresses Ras-induced small ubiquitin-like modifier (SUMO)-modified nuclear cyclin D1 and inhibits retinoblastoma protein (Rb) phosphorylation. The lysine residue, K33, of cyclin D1 is a key site for this newly identified regulation. In agreement with the fact that its nuclear localization is required for its oncogenic activity, we show that nuclear cyclin D1 is far more potent than wild-type (WT) cyclin D1 in bypassing Ras-induced senescence. Thus, this study identifies SUMO modification as a positive regulator of nuclear cyclin D1, and reveals a new way by which cell cycle entry and senescence are regulated.

Understanding urothelial stem cell biology and differentiation has been limited by the lack of methods for their unlimited propagation. Here, we establish mouse urothelial organoids that can be maintained uninterruptedly for >1 year. Organoid growth is dependent on EGF and Wnt activators. High CD49f/ITGA6 expression features a subpopulation of organoid-forming cells expressing basal markers. Upon differentiation, multilayered organoids undergo reduced proliferation, decreased cell layer number, urothelial program activation, and acquisition of barrier function. Pharmacological modulation of PPARγ and EGFR promotes differentiation. RNA sequencing highlighted genesets enriched in proliferative organoids (i.e. ribosome) and transcriptional networks involved in differentiation, including expression of Wnt ligands and Notch components. Single-cell RNA sequencing (scRNA-Seq) analysis of the organoids revealed five clusters with distinct gene expression profiles. Together, with the use of γ-secretase inhibitors and scRNA-Seq, confirms that Notch signaling is required for differentiation. Urothelial organoids provide a powerful tool to study cell regeneration and differentiation.

The maintenance of quiescence is essential for tissue homeostasis. is one of the few genes mutated in the normal urothelium of organ donors, with mutant cells undergoing positive selection . is also a major tumour suppressor gene and its inactivation is an early event in bladder carcinogenesis . However, how STAG2, a cohesin component, regulates urothelial homeostasis remains largely unknown. Here, we demonstrate that inactivation in normal murine urothelial cells interferes with differentiation programs, triggers transient cell cycle entry, and primes cells for clonal expansion under stress. Moreover, STAG2 loss enhances tumor formation in urothelial cells expressing mutant - the key oncogene in bladder cancer . We reveal that STAG2 cooperates with the DREAM transcriptional complex, a master regulator of quiescence , by binding to shared genomic sites, including cell cycle control genes. STAG2 loss alters DREAM target expression, complex composition, and chromatin distribution, and leads to rewiring of chromatin interactions involving DREAM binding motifs in genes critical for cell cycle entry. Our findings provide compelling evidence that STAG2 loss disrupts in 3D genome organization through a novel mechanism involving the DREAM complex, thereby impairing homeostatic quiescence and increasing oncogenic sensitivity.

The urothelium is a specialized stratified epithelium with unique structural and functional features. Understanding the mechanisms involved in urothelial stem cell biology and differentiation has been limited by the lack of methods for unlimited propagation. Here, we establish normal mouse urothelial organoid (NMU-o) cultures that can be maintained uninterruptedly for >1 year. Organoid growth is dependent on EGF and Wnt activators. High CD49f/ITGA6 expression features a subpopulation of organoid-forming urothelial stem cells expressing basal markers. On induction of differentiation, multilayered organoids show reduced layer number, acquire barrier function, and activate the urothelial program, including expression of uroplakins and tight junction components. Combined pharmacological modulation of PPARγ and EGFR was most potent driving cell differentiation. Transcriptome analysis of organoids widely validates the system, highlights the transcriptional networks involved, and reveals NOTCH signaling as a novel pathway required for normal urothelial organoid differentiation.

The urothelium is a specialized stratified epithelium with unique structural and functional features. Understanding the mechanisms involved in urothelial stem cell biology and differentiation has been limited by the lack of methods for unlimited propagation. Here, we establish normal mouse urothelial organoid (NMU-o) cultures that can be maintained uninterruptedly for >1 year. Organoid growth is dependent on EGF and Wnt activators. High CD49f/ITGA6 expression features a subpopulation of organoid-forming urothelial stem cells expressing basal markers. On induction of differentiation, multilayered organoids show reduced layer number, acquire barrier function, and activate the urothelial program, including expression of uroplakins and tight junction components. Combined pharmacological modulation of PPAR gamma and EGFR was most potent driving cell differentiation. Transcriptome analysis of organoids widely validates the system, highlights the transcriptional networks involved, and reveals NOTCH signaling as a novel pathway required for normal urothelial organoid differentiation.

The distinct functions of cohesin complexes carrying STAG1 or STAG2 need to be unraveled. STAG2 is commonly mutated in cancer and germline mutations have been identified in cohesinopathy patients. To better understand the underlying pathogenic mechanisms, we here report the consequence of Stag2 ablation in mice. STAG2 is largely dispensable in adults and its tissue-wide inactivation does not lead to tumors but reduces fitness and affects both hematopoiesis and intestinal homeostasis. STAG2 is also dispensable for murine embryonic fibroblasts in vitro. In contrast, null embryos die by mid gestation showing global developmental delay and heart defects. Histopathological analysis and RNA-sequencing unveiled that STAG2 is required both for proliferation and regulation of cardiac transcriptional programs and in its absence, secondary heart field progenitors fail to enter the heart tube. These results provide compelling evidence on cell- and tissue-specific roles of the two cohesin complexes and how their dysfunction contributes to disease.