Project description:SETD2 is a methyltransferase responsible for depositing histone H3 lysine 36 trimethylation (H3K36me3). Loss of its enzymatic activity occurs in some cancers, including renal cell carcinoma. SETD2 mutations have been linked to delayed transcription termination, but have not been explored in depth. Here, using nascent transcriptomics in SETD2 knockout and patient-derived cells, we reveal a dichotomy in SETD2 functions depending on the affected protein-coding gene. The majority of genes, named class I, are dependent on SETD2 function for transcription initiation, yet terminate transcription in the usual locations. In contrast, for class II genes, corresponding to 15-25% of active protein-coding genes, transcription initiation is robust in absence of SETD2 activity; however, widespread transcriptional readthrough occurs. Defective termination following SETD2 loss/mutation is associated with increased cryptic transcription initiation and impaired 3′ pre-mRNA cleavage. Additionally, alternative polyadenylation upon SETD2 activity loss is highly cell type specific, and no relationship with transcription readthrough was observed. We demonstrate that methyltransferase activity of SETD2 stimulates proper initiation, prevents cryptic initiation and promotes efficient 3′ end processing, however it does so indirectly. This SuperSeries is composed of the SubSeries listed below.

Project description:SETD2 is a key histone methyltransferase responsible for depositing histone H3 lysine 36 trimethylation (H3K36me3). Loss of its enzymatic activity has been implicated in various cancers, including renal cell carcinoma (RCC). In RCC, SETD2 mutations have been linked to defects in transcription termination, though the underlying mechanism remains unclear. Here, using nascent transcriptomics in SETD2 knockouts and RCC patient-derived cells, we show that SETD2 loss leads to delayed transcription termination, but only in a subset of genes. POINT-seq analysis reveals widespread transcriptional readthrough beyond canonical termination sites upon SETD2 loss/mutation, affecting 15–24% of genes. We demonstrate that defective termination following SETD2 loss/mutation is driven by a combination of increased cryptic transcription initiation and impaired 3′ pre-mRNA cleavage. In contrast, genes that maintain proper termination show significant downregulation. Additionally, we find that SETD2 ensures proper termination independently of alternative polyadenylation, underscoring the distinction between transcription termination and 3′ end processing. Our findings highlight that methyltransferase activity of SETD2 is a crucial regulator of transcriptional integrity, preventing cryptic initiation and promoting efficient 3′ end processing

Project description:SETD2 is a key histone methyltransferase responsible for depositing histone H3 lysine 36 trimethylation (H3K36me3). Loss of its enzymatic activity has been implicated in various cancers, including renal cell carcinoma (RCC). In RCC, SETD2 mutations have been linked to defects in transcription termination, though the underlying mechanism remains unclear. Here, using nascent transcriptomics in SETD2 knockouts and RCC patient-derived cells, we show that SETD2 loss leads to delayed transcription termination, but only in a subset of genes. POINT-seq analysis reveals widespread transcriptional readthrough beyond canonical termination sites upon SETD2 loss/mutation, affecting 15–24% of genes. We demonstrate that defective termination following SETD2 loss/mutation is driven by a combination of increased cryptic transcription initiation and impaired 3′ pre-mRNA cleavage. In contrast, genes that maintain proper termination show significant downregulation. Additionally, we find that SETD2 ensures proper termination independently of alternative polyadenylation, underscoring the distinction between transcription termination and 3′ end processing. Our findings highlight that methyltransferase activity of SETD2 is a crucial regulator of transcriptional integrity, preventing cryptic initiation and promoting efficient 3′ end processing

Project description:SETD2 is a key histone methyltransferase responsible for depositing histone H3 lysine 36 trimethylation (H3K36me3). Loss of its enzymatic activity has been implicated in various cancers, including renal cell carcinoma (RCC). In RCC, SETD2 mutations have been linked to defects in transcription termination, though the underlying mechanism remains unclear. Here, using nascent transcriptomics in SETD2 knockouts and RCC patient-derived cells, we show that SETD2 loss leads to delayed transcription termination, but only in a subset of genes. POINT-seq analysis reveals widespread transcriptional readthrough beyond canonical termination sites upon SETD2 loss/mutation, affecting 15–24% of genes. We demonstrate that defective termination following SETD2 loss/mutation is driven by a combination of increased cryptic transcription initiation and impaired 3′ pre-mRNA cleavage. In contrast, genes that maintain proper termination show significant downregulation. Additionally, we find that SETD2 ensures proper termination independently of alternative polyadenylation, underscoring the distinction between transcription termination and 3′ end processing. Our findings highlight that methyltransferase activity of SETD2 is a crucial regulator of transcriptional integrity, preventing cryptic initiation and promoting efficient 3′ end processing

Project description:SETD2 is a key histone methyltransferase responsible for depositing histone H3 lysine 36 trimethylation (H3K36me3). Loss of its enzymatic activity has been implicated in various cancers, including renal cell carcinoma (RCC). In RCC, SETD2 mutations have been linked to defects in transcription termination, though the underlying mechanism remains unclear. Here, using nascent transcriptomics in SETD2 knockouts and RCC patient-derived cells, we show that SETD2 loss leads to delayed transcription termination, but only in a subset of genes. POINT-seq analysis reveals widespread transcriptional readthrough beyond canonical termination sites upon SETD2 loss/mutation, affecting 15–24% of genes. We demonstrate that defective termination following SETD2 loss/mutation is driven by a combination of increased cryptic transcription initiation and impaired 3′ pre-mRNA cleavage. In contrast, genes that maintain proper termination show significant downregulation. Additionally, we find that SETD2 ensures proper termination independently of alternative polyadenylation, underscoring the distinction between transcription termination and 3′ end processing. Our findings highlight that methyltransferase activity of SETD2 is a crucial regulator of transcriptional integrity, preventing cryptic initiation and promoting efficient 3′ end processing

Project description:SETD2 is a key histone methyltransferase responsible for depositing histone H3 lysine 36 trimethylation (H3K36me3). Loss of its enzymatic activity has been implicated in various cancers, including renal cell carcinoma (RCC). In RCC, SETD2 mutations have been linked to defects in transcription termination, though the underlying mechanism remains unclear. Here, using nascent transcriptomics in SETD2 knockouts and RCC patient-derived cells, we show that SETD2 loss leads to delayed transcription termination, but only in a subset of genes. POINT-seq analysis reveals widespread transcriptional readthrough beyond canonical termination sites upon SETD2 loss/mutation, affecting 15–24% of genes. We demonstrate that defective termination following SETD2 loss/mutation is driven by a combination of increased cryptic transcription initiation and impaired 3′ pre-mRNA cleavage. In contrast, genes that maintain proper termination show significant downregulation. Additionally, we find that SETD2 ensures proper termination independently of alternative polyadenylation, underscoring the distinction between transcription termination and 3′ end processing. Our findings highlight that methyltransferase activity of SETD2 is a crucial regulator of transcriptional integrity, preventing cryptic initiation and promoting efficient 3′ end processing

Project description:SETD2 is a key histone methyltransferase responsible for depositing histone H3 lysine 36 trimethylation (H3K36me3). Loss of its enzymatic activity has been implicated in various cancers, including renal cell carcinoma (RCC). In RCC, SETD2 mutations have been linked to defects in transcription termination, though the underlying mechanism remains unclear. Here, using nascent transcriptomics in SETD2 knockouts and RCC patient-derived cells, we show that SETD2 loss leads to delayed transcription termination, but only in a subset of genes. POINT-seq analysis reveals widespread transcriptional readthrough beyond canonical termination sites upon SETD2 loss/mutation, affecting 15–24% of genes. We demonstrate that defective termination following SETD2 loss/mutation is driven by a combination of increased cryptic transcription initiation and impaired 3′ pre-mRNA cleavage. In contrast, genes that maintain proper termination show significant downregulation. Additionally, we find that SETD2 ensures proper termination independently of alternative polyadenylation, underscoring the distinction between transcription termination and 3′ end processing. Our findings highlight that methyltransferase activity of SETD2 is a crucial regulator of transcriptional integrity, preventing cryptic initiation and promoting efficient 3′ end processing

Project description:SETD2 methyltransferase activity promotes correct transcription initiation and termination

Project description:SETD2 methyltransferase activity promotes correct transcription initiation and termination

Project description:CDK7 regulates RNA polymerase II (RNAPII) initiation, elongation, and termination through incompletely understood mechanisms. Because contaminating kinases precluded CDK7 analysis with nuclear extracts, we completed biochemical assays with purified factors. Reconstitution of RNAPII transcription initiation showed CDK7 inhibition slowed and/or paused RNAPII promoterproximal transcription, which reduced re-initiation. These CDK7-regulatory functions were suppressing RNAPII activity at promoters, consistent with reduced initiation and/or re-initiation. Moreover, widespread 3'-end readthrough transcription was observed in CDK7-inhibited cells; mechanistically, this occurred through rapid nuclear depletion of RNAPII elongation and termination factors, including high-confidence CDK7 targets. Collectively, these results define how CDK7 governs RNAPII function at gene 5'-ends and 3'-ends, and reveal that nuclear abundance of elongation and termination factors is kinase-dependent. Because 3'-readthrough transcription is commonly induced during stress, our results further suggest regulated suppression of CDK7 activity may enable this RNAPII transcriptional response.