Project description:Ribosomopathies constitute a range of disabling conditions associated with defective protein synthesis mainly affecting hematopoietic stem cells (HSCs) and erythroid development. Here we demonstrate that deletion of Polypyrimidine Tract Binding Protein 1 (PTBP1) in the hematopoietic compartment led to the development of a ribosomopathy-like condition. Specifically, loss of PTBP1 was associated with a decrease in HSC self-renewal, erythroid differentiation and protein synthesis. Consistent with its function as a splicing regulator, PTBP1 deficiency led to splicing defects in hundreds of genes and we demonstrate that the up-regulation of a specific isoform of CDC42 could partly mimic the protein synthesis defect associated with loss of PTBP1. Furthermore, PTBP1 deficiency was associated with a marked defect in ribosome biogenesis and a selective reduction in the translation of mRNAs encoding ribosomal proteins. Collectively, this work identifies PTBP1 as a key integrator of ribosomal functions and highlights the broad functional repertoire of RNA binding proteins.

Project description:RNA binding proteins play an important role in regulating alternative pre-mRNA splicing and in turn cellular gene expression. Polypyrimidine tract binding proteins, PTBP1 and PTBP2, are paralogous RNA binding proteins that play a critical role in the process of neuronal differentiation and maturation; changes in the concentration of PTBP proteins during neuronal development direct splicing changes in many transcripts that code for proteins critical for neuronal differentiation. How the two related proteins regulate different sets of neuronal exons is unclear. The distinct splicing activities of PTBP1 and PTBP2 can be recapitulated in an in vitro splicing system with the differentially regulated N1 exon of the c-src pre-mRNA. Here, we conducted experiments under these in vitro splicing conditions to identify PTBP1 and PTBP2 interacting partner proteins.

Project description:Ribosomopathies constitute a range of disorders associated with defective protein synthesis mainly affecting hematopoietic stem cells (HSCs) and erythroid development. Here we demonstrate that deletion of Polypyrimidine Tract Binding Protein 1 (PTBP1) in the hematopoietic compartment led to the development of a ribosomopathy-like condition. Specifically, loss of PTBP1 was associated with decreases in HSC self-renewal, erythroid differentiation and protein synthesis. Consistent with its function as a splicing regulator, PTBP1 deficiency led to splicing defects in hundreds of genes, and we demonstrate that the up-regulation of a specific isoform of CDC42 could partly mimic the protein synthesis defect associated with loss of PTBP1. Furthermore, PTBP1 deficiency was associated with a marked defect in ribosome biogenesis and a selective reduction in the translation of mRNAs encoding ribosomal proteins. Collectively, this work identifies PTBP1 as a key integrator of ribosomal functions and highlights the broad functional repertoire of RNA binding proteins.

Project description:Radiotherapy is a curative arsenal for prostate cancer (PCa), but radioresistance seriously compromises its effectiveness. Dysregulated RNA splicing factors are extensively involved in tumor progression. Nonetheless, the role of splicing factors in radioresistance remains largely unexplored in PCa. Here, we identified 23 splicing factors that are differentially expressed between PCa and adjacent normal tissues across multiple public PCa databases. Among those genes, polypyrimidine tract binding protein 1 (PTBP1) was significantly upregulated in PCa and was positively associated with advanced clinicopathological features and poor prognosis. Gain- and loss-of-function experiments demonstrated that PTBP1 markedly reinforced genomic DNA stability to desensitize PCa cells to irradiation in vitro and in vivo. Mechanistically, PTBP1 interacted with the HnRNP associated with lethal yellow protein homolog (RALY) and regulated exon 5 splicing of methyltransferase 3b (DNMT3B) from DNMT3B-S to DNMT3B-L. Furthermore, upregulation of DNMT3B-L induced promoter methylation of dual-specificity phosphatase-2 (DUSP2) and subsequently inhibited DUSP2 expression, thereby increasing radioresistance in PCa. Our findings highlight the role of splicing factors in inducing aberrant splicing events in response to radiotherapy and the potential role of PTBP1 and DNMT3B-L in reversing radioresistance in PCa.

Project description:The intestinal epithelial regeneration is driven by intestinal stem cells under homeostatic conditions. Differentiated intestinal epithelial cells, such as Paneth cells, are capable of acquiring multipotency and contributing to regeneration upon loss of intestinal stem cells. Paneth cells also support intestinal stem cell survival and regeneration. We report here that depletion of an RNA-binding protein named polypyrimidine tract binding protein 1 (PTBP1) in mouse intestinal epithelial cells causes intestinal stem cell death and epithelial regeneration failure. Mechanistically, we show that PTBP1 inhibits neuronal-like splicing programs in intestinal crypt cells, which is critical for maintaining intestinal stem cell stemness. This function is achieved at least in part through promoting the non-productive splicing of its paralog PTBP2. Moreover, PTBP1 inhibits the expression of an AKT inhibitor PHLDA3 in Paneth cells and permits AKT activation, which presumably maintains Paneth cell plasticity and function in supporting intestinal stem cell niche. We show that PTBP1 directly binds to a CU-rich region in the 3’ UTR of Phlda3, which we demonstrate to be critical for downregulating the mRNA and protein levels of Phlda3. Our results thus reveal the multifaceted in vivo regulation of intestinal epithelial regeneration by PTBP1 at the post-transcriptional level.

Project description:We examined the role of PTBP1 in regulation of co-transcriptional splicing process by depleting this RNA-binding protein from embryonic stem cells using the auxin-inducible degron technology and analysing the total and chromatin-associated RNA fractions by RNA-seq. We also performed mNET-seq and ChIP-seq analyses using RNA polymerase II- and PTBP1-specific antibodies, respectively. Our data suggest that PTBP1 activates co-transcriptional splicing of hundreds of introns, a surprising effect given that PTBP1 is better known as a splicing repressor. Importantly, some co-transcriptionally activated introns fail to be spliced post-transcriptionally without PTBP1. In a striking example of this regulation, lasting retention of a PTBP1-dependent intron triggers nonsense-mediated decay of mRNAs encoding DNA methyltransferase DNMT3B, explaining their natural expression dynamics in development. Our further analyses suggest that this mechanism may protect differentiation-specific genes from aberrant methylation. We conclude that PTBP1-activated co-transcriptional splicing underlies biologically important decisions.

Project description:Rattus norvegicus Ptbp1, polypyrimidine tract binding protein 1 [Source:RGD Symbol;Acc:62047], is expressed in 8 baseline experiment(s);

Project description:Rattus norvegicus Ptbp1, polypyrimidine tract binding protein 1 [Source:RGD Symbol;Acc:62047], is differentially expressed in 29 experiment(s);

Project description:Cells sense and respond to mechanical cues from their environment. Mechanical cues have been shown to be important for many biological processes, including embryonic development, aging, cellular homeostasis, and diseases. Cells translate mechanical cues into cellular biochemical signals that govern cellular behaviour like proliferation or migration, via a process called mechanotransduction. However this process and the proteins involved remain incompletely understood. Here, we present an unbiased and large scale screen approach to identify proteins involved in mechanotransduction. The screen revealed that the splicing factor PTBP1 is a novel mechanotransducer. We show that the nuclear localisation of PTBP1 depends on the extracellular matrix stiffness, cell density, and the actomyosin-based contractility of the cell. Furthermore, we demonstrate that PTBP1 promotes the mechanosensitive splicing of the adapter protein Numb, and that alternative splicing of Numb is crucial for matrix stiffness-induced proliferation. Our results support the idea that changes in alternative splicing are an integral part of mechanotransduction and provide a mechanism by which matrix stiffness regulates cell proliferation and the formation of a mechanomemory in cells.

Project description:To investigate the effect of IGFRIL/PTBP1 in HCC, we established HepG2 cell lines in which IGFRIL/PTBP1 mRNA has been degraded using siRNA.