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: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: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:IMR90 ER:RAS cells were stably transduced with either an empty vector or 2 deconvoluted shRNAs targeting PTBP1. Following selection with puromycin, the cells were treated with 4OHT to induce senescence. 6 days later the cells were collected for total mRNA analysis. PTBP1 is a regulator of alternative splicing. Our previous experiments had shown that PTBP1 depletion inhibits the expression of pro-inflammatory genes without affecting other senescence-associated phenotypes. By performing RNA-seq we confirmed those observations at a global level and analysed how PTBP1 knockdown alters alternative splicing as a potential mechanism of action.

Project description:Analysis of effects of Ptbp1 deletion on RNA splicing and expression in aortic endothelial cells

Project description:Changing splicing factors leads to abnormal alternative splicing (AS), which results in tumor progression.Splicing factor polypyrimidine tract binding proteins (PTBP1) facilitate cancer progression by modulating oncogenic variants. However, its role and mechanism in hepatocellular carcinoma (HCC) remains unclear. Our findings confirm that PTBP1 is highly expressed in HCC cells lines and tissues. Moreover, its expression correlated negatively with overallanddisease-freesurvivalrates, but inversely with tumor grade and stage. PTBP1 knockdown decreases HCC cell proliferation, migration, and invasion in vitro and inhibits hepatoma xenograft growth and infiltration in vivo. We identified PTBP1-mediated AS events and PTBP1 functionally promoted cell proliferation, invasion, and migration by altering the AS of the protein tau (MAPT) gene and promoting the oncogene expression. Strikingly, the dysregulation of MAPT splicing was paralleled by the increased expression of PTBP1 in HCC, which predicted the poor prognosis of the patients. According to additional research, AS of the MAPT gene guided by PTBP1 increases tumorigenicity in HCC by activating the MAPK/ERK pathways. In summary, our results suggest that PTBP1 plays an oncogenic role in HCC partially through the regulation of MAPT's AS, which could be a promising treatment target.

Project description:Neuronal reprogramming of astrocytes poses a promising therapeutic approach to replace degenerating cells with newly converted neurons. Recent studies reported depletion of polyprimidine tract binding protein PTBP1, a repressor of neuronal alternative splicing, could induce astrocyte to neuron conversion and rescue functional deficits in models of neurodegenerative disease, while others disputed the astrocytic origin of converted neurons. Mechanistic understanding of the conversion, or the lack thereof, requires investigating the transcriptomic effects of Ptbp1 loss of function in mature astrocytes on RNA splicing, in conjunction with lineage tracing, which have not yet been examined. Here, we used genetic depletion of Ptbp1 in adult Aldh1l1-Cre/ERT2 reporter mice to determine whether lineage traced Ptbp1 knockout astrocytes exhibited RNA splicing alterations underlying potential neuronal transdifferentiation. Our analysis employed an alternative genetic Ptbp1 knockout mouse model and an extended 12-week window of Ptbp1 knockout to match previous reports of positive conversion. We found no widespread induction of neuronal identity, despite detecting a minuscule fraction of Cre-positive cells with neuronal transcriptomic features following Ptbp1 deletion. Importantly, PTBP1 depletion in mature astrocytes induces splicing alternations unlike neuronal features of alternative splicing. These findings highlight the challenge of targeting astrocytes for neuronal conversion via Ptbp1 knockout and underscore the importance of cellular gene expression profiling and genetic lineage tracing for in vivo studies of cell type conversion.

Project description:Neuronal reprogramming of astrocytes poses a promising therapeutic approach to replace degenerating cells with newly converted neurons. Recent studies reported depletion of polyprimidine tract binding protein PTBP1, a repressor of neuronal alternative splicing, could induce astrocyte to neuron conversion and rescue functional deficits in models of neurodegenerative disease, while others disputed the astrocytic origin of converted neurons. Mechanistic understanding of the conversion, or the lack thereof, requires investigating the transcriptomic effects of Ptbp1 loss of function in mature astrocytes on RNA splicing, in conjunction with lineage tracing, which have not yet been examined. Here, we used genetic depletion of Ptbp1 in adult Aldh1l1-Cre/ERT2 reporter mice to determine whether lineage traced Ptbp1 knockout astrocytes exhibited RNA splicing alterations underlying potential neuronal transdifferentiation. Our analysis employed an alternative genetic Ptbp1 knockout mouse model and an extended 12-week window of Ptbp1 knockout to match previous reports of positive conversion. We found no widespread induction of neuronal identity, despite detecting a minuscule fraction of Cre-positive cells with neuronal transcriptomic features following Ptbp1 deletion. Importantly, PTBP1 depletion in mature astrocytes induces splicing alternations unlike neuronal features of alternative splicing. These findings highlight the challenge of targeting astrocytes for neuronal conversion via Ptbp1 knockout and underscore the importance of cellular gene expression profiling and genetic lineage tracing for in vivo studies of cell type conversion.

Project description:The RNA-binding protein Ptbp1 has been proposed as a master regulator of neuronal fate, repressing neurogenesis through its effects on alternative splicing and miRNA maturation. While prior studies using RNA interference suggested that Ptbp1 loss promotes neurogenesis, recent genetic studies have failed to replicate glia-to-neuron conversion following Ptbp1 loss of function. To evaluate the role of Ptbp1 in developmental neurogenesis in vivo, we conditionally disrupted Ptbp1 in retinal progenitors. Ptbp1 was robustly expressed in both retinal progenitors and Müller glia but absent from postmitotic neurons, and efficient loss of function in mutant animals was confirmed using immunostaining for Ptbp1. Furthermore, bulk RNA-Seq at E16 revealed accelerated expression of late-stage progenitor and photoreceptor-specific genes and altered splicing patterns in Ptbp1 mutants, including increased inclusion of neuron- and retina-specific exons. However, we observed no defects in retinal lamination, progenitor proliferation, or cell fate specification in mature retina. ScRNA-Seq of mature mutant retinas revealed only modest transcriptional changes limited to Müller glia, recapitulating alterations seen following selective deletion of Ptbp1 in mature glia. Our findings demonstrate that Ptbp1 is fully dispensable for retinal development and suggest that its proposed role as a central repressor of neurogenesis should be reevaluated

Project description:The RNA-binding protein Ptbp1 has been proposed as a master regulator of neuronal fate, repressing neurogenesis through its effects on alternative splicing and miRNA maturation. While prior studies using RNA interference suggested that Ptbp1 loss promotes neurogenesis, recent genetic studies have failed to replicate glia-to-neuron conversion following Ptbp1 loss of function. To evaluate the role of Ptbp1 in developmental neurogenesis in vivo, we conditionally disrupted Ptbp1 in retinal progenitors. Ptbp1 was robustly expressed in both retinal progenitors and Müller glia but absent from postmitotic neurons, and efficient loss of function in mutant animals was confirmed using immunostaining for Ptbp1. Furthermore, bulk RNA-Seq at E16 revealed accelerated expression of late-stage progenitor and photoreceptor-specific genes and altered splicing patterns in Ptbp1 mutants, including increased inclusion of neuron- and retina-specific exons. However, we observed no defects in retinal lamination, progenitor proliferation, or cell fate specification in mature retina. ScRNA-Seq of mature mutant retinas revealed only modest transcriptional changes limited to Müller glia, recapitulating alterations seen following selective deletion of Ptbp1 in mature glia. Our findings demonstrate that Ptbp1 is fully dispensable for retinal development and suggest that its proposed role as a central repressor of neurogenesis should be reevaluated