Project description:Aberrant splicing is an important cause of cancer, and the production of noncanonical, cancer-specific, mRNA transcripts associate with transformation. Studies have focused on characterizing the effect of spliceosome mutations on disease progression. Here, we have uncovered a novel mode of regulation of the U2 complex component SF3B1 in leukemia via lysosomal degradation. Elevated levels of SF3B1 protein control splicing and active transcription via direct interaction with the general transcriptional machinery and are critical for leukemia growth due to the control of cell cycle and DNA damage response-related transcripts, such as the serine/threonine kinase CHEK2. We further exploited these findings to show that clinically-used SF3B1 inhibitors synergize with transcriptional inhibitors, CHEK2 inhibitors and chemotherapy drugs to block leukemia growth. Our study provides the proof-of-principle for post-translational regulation of the splicing machinery via the lysosome and associated splicing-dependent and -independent roles of the U2 complex in cancer, that can be exploited for therapeutic purposes.

Project description:Aberrant splicing is an important cause of cancer, and the production of noncanonical, cancer-specific, mRNA transcripts associate with transformation. Studies have focused on characterizing the effect of spliceosome mutations on disease progression. Here, we have uncovered a novel mode of regulation of the U2 complex component SF3B1 in leukemia via lysosomal degradation. Elevated levels of SF3B1 protein control splicing and active transcription via direct interaction with the general transcriptional machinery and are critical for leukemia growth due to the control of cell cycle and DNA damage response-related transcripts, such as the serine/threonine kinase CHEK2. We further exploited these findings to show that clinically-used SF3B1 inhibitors synergize with transcriptional inhibitors, CHEK2 inhibitors and chemotherapy drugs to block leukemia growth. Our study provides the proof-of-principle for post-translational regulation of the splicing machinery via the lysosome and associated splicing-dependent and -independent roles of the U2 complex in cancer, that can be exploited for therapeutic purposes.

Project description:Aberrant splicing is an important cause of cancer, and the production of noncanonical, cancer-specific, mRNA transcripts associate with transformation. Studies have focused on characterizing the effect of spliceosome mutations on disease progression. Here, we have uncovered a novel mode of regulation of the U2 complex component SF3B1 in leukemia via lysosomal degradation. Elevated levels of SF3B1 protein control splicing and active transcription via direct interaction with the general transcriptional machinery and are critical for leukemia growth due to the control of cell cycle and DNA damage response-related transcripts, such as the serine/threonine kinase CHEK2. We further exploited these findings to show that clinically-used SF3B1 inhibitors synergize with transcriptional inhibitors, CHEK2 inhibitors and chemotherapy drugs to block leukemia growth. Our study provides the proof-of-principle for post-translational regulation of the splicing machinery via the lysosome and associated splicing-dependent and -independent roles of the U2 complex in cancer, that can be exploited for therapeutic purposes.

Project description:Aberrant splicing is an important cause of cancer, and the production of noncanonical, cancer-specific, mRNA transcripts associate with transformation. Studies have focused on characterizing the effect of spliceosome mutations on disease progression. Here, we have uncovered a novel mode of regulation of the U2 complex component SF3B1 in leukemia via lysosomal degradation. Elevated levels of SF3B1 protein control splicing and active transcription via direct interaction with the general transcriptional machinery and are critical for leukemia growth due to the control of cell cycle and DNA damage response-related transcripts, such as the serine/threonine kinase CHEK2. We further exploited these findings to show that clinically-used SF3B1 inhibitors synergize with transcriptional inhibitors, CHEK2 inhibitors and chemotherapy drugs to block leukemia growth. Our study provides the proof-of-principle for post-translational regulation of the splicing machinery via the lysosome and associated splicing-dependent and -independent roles of the U2 complex in cancer, that can be exploited for therapeutic purposes.

Project description:Aberrant splicing is an important cause of cancer, and the production of noncanonical, cancer-specific, mRNA transcripts associate with transformation. Studies have focused on characterizing the effect of spliceosome mutations on disease progression. Here, we have uncovered a novel mode of regulation of the U2 complex component SF3B1 in leukemia via lysosomal degradation. Elevated levels of SF3B1 protein control splicing and active transcription via direct interaction with the general transcriptional machinery and are critical for leukemia growth due to the control of cell cycle and DNA damage response-related transcripts, such as the serine/threonine kinase CHEK2. We further exploited these findings to show that clinically-used SF3B1 inhibitors synergize with transcriptional inhibitors, CHEK2 inhibitors and chemotherapy drugs to block leukemia growth. Our study provides the proof-of-principle for post-translational regulation of the splicing machinery via the lysosome and associated splicing-dependent and -independent roles of the U2 complex in cancer, that can be exploited for therapeutic purposes.

Project description:Aberrant splicing is an important cause of cancer, and the production of noncanonical, cancer-specific, mRNA transcripts associate with transformation. Studies have focused on characterizing the effect of spliceosome mutations on disease progression. Here, we have uncovered a novel mode of regulation of the U2 complex component SF3B1 in leukemia via lysosomal degradation. Elevated levels of SF3B1 protein control splicing and active transcription via direct interaction with the general transcriptional machinery and are critical for leukemia growth due to the control of cell cycle and DNA damage response-related transcripts, such as the serine/threonine kinase CHEK2. We further exploited these findings to show that clinically-used SF3B1 inhibitors synergize with transcriptional inhibitors, CHEK2 inhibitors and chemotherapy drugs to block leukemia growth. Our study provides the proof-of-principle for post-translational regulation of the splicing machinery via the lysosome and associated splicing-dependent and -independent roles of the U2 complex in cancer, that can be exploited for therapeutic purposes.

Project description:Aberrant splicing is an important cause of cancer, and the production of noncanonical, cancer-specific, mRNA transcripts associate with transformation. Studies have focused on characterizing the effect of spliceosome mutations on disease progression. Here, we have uncovered a novel mode of regulation of the U2 complex component SF3B1 in leukemia via lysosomal degradation. Elevated levels of SF3B1 protein control splicing and active transcription via direct interaction with the general transcriptional machinery and are critical for leukemia growth due to the control of cell cycle and DNA damage response-related transcripts, such as the serine/threonine kinase CHEK2. We further exploited these findings to show that clinically-used SF3B1 inhibitors synergize with transcriptional inhibitors, CHEK2 inhibitors and chemotherapy drugs to block leukemia growth. Our study provides the proof-of-principle for post-translational regulation of the splicing machinery via the lysosome and associated splicing-dependent and -independent roles of the U2 complex in cancer, that can be exploited for therapeutic purposes.

Project description:Aberrant splicing is an important cause of cancer, and the production of noncanonical, cancer-specific, mRNA transcripts associate with transformation. Studies have focused on characterizing the effect of spliceosome mutations on disease progression. Here, we have uncovered a novel mode of regulation of the U2 complex component SF3B1 in leukemia via lysosomal degradation. Elevated levels of SF3B1 protein control splicing and active transcription via direct interaction with the general transcriptional machinery and are critical for leukemia growth due to the control of cell cycle and DNA damage response-related transcripts, such as the serine/threonine kinase CHEK2. We further exploited these findings to show that clinically-used SF3B1 inhibitors synergize with transcriptional inhibitors, CHEK2 inhibitors and chemotherapy drugs to block leukemia growth. Our study provides the proof-of-principle for post-translational regulation of the splicing machinery via the lysosome and associated splicing-dependent and -independent roles of the U2 complex in cancer, that can be exploited for therapeutic purposes.

Project description:Splicing alterations are very common in cancer and might affect disease initiation and progression. In several cancers, mutations in splicing factor genes are responsible for aberrant splicing. We show that certain aggressive cancers, such as pediatric T-cell acute lymphoblastic leukemia (T-ALL), have an alternative mechanism for aberrant splicing that involves post-translational regulation of the splicing machinery via deubiquitination. We initially demonstrated that T-ALL presents with extensive exon skipping events affecting proteasomal transcripts, cell cycle and epigenetic regulators. Performing an unbiased genetic screen study for RNA binding proteins, we showed that the serine/arginine-rich splicing factor (SRSF) proteins, controlling exon skipping are critical for T-ALL survival. In our effort to dissect mechanisms of aberrant regulation of SRSF proteins, we focused on the pro-oncogenic deubiquitinase ubiquitin-specific peptidase 7 (USP7) to show it regulates the levels of the SRSF proteins at the post-translational level via active deubiquitination. We further demonstrated that USP7 inhibitors can change the splicing landscape and block T-ALL growth. Our drug studies show that decrease of the levels of SRSF proteins splicing inhibitors sensitize cells to the clinically used splicing inhibitor H3B-8800. Driven by our molecular findings on aberrant splicing of proteasomal transcripts, we demonstrate that H3B-8800 could act synergistically with proteasome inhibitors, paving the way for new therapeutic schemes in pediatric leukemia. Collectively this study provides the proof-of-principle for regulation of splicing factors independently of mutations and via deubiquitination and suggests new therapeutic modalities and combinations in cancer.

Project description:In this study, we show that pediatric T-cell acute lymphoblastic leukemia (T-ALL) has an alternative mechanism for aberrant splicing that involves post-translational regulation of the splicing machinery via deubiquitination.