Project description:The H3K4 methyltransferase SETD1A plays an essential role in both development and cancer. However, essential components involved in SETD1A chromatin binding remain unclear. Here, we discovered that BOD1L exhibits the highest correlated co-dependency with SETD1A in human cancer cell lines. BOD1L knockout reduces leukemia cells in vitro and in vivo, and mimics the transcriptional profiles observed in SETD1A knockout cells. The loss of BOD1L immediately reduced SETD1A distribution at transcriptional start sites (TSS) and induces transcriptional elongation defect along with the increasing of RNA polymerase II at TSS, but did not cause the reduction of H3K4me3. The Shg1 domain of BOD1L has a DNA binding ability, and recruit SETD1A to chromatin through the association with SETD1A FLOS domain. In addition, the BOD1L-SETD1A complex associates with transcriptional regulators, including E2Fs. These results reveal that BOD1L mediates chromatin and SETD1A, and regulates the non-canonical function of SETD1A in transcription.

Project description:The H3K4 methyltransferase SETD1A plays a crucial role in leukemia cell survival through its non-catalytic FLOS domain mediated recruitment of cyclin K and regulation of DNA damage response genes. In this study, we identify a functional nuclear localization signal and interaction partners for the FLOS domain. Our proteomics analysis against FLOS domain-binding partners reveals that the SETD1A FLOS domain binds mitosis-associated proteins BuGZ/BUB3. Targeted inhibition of both cyclin K and BuGZ/BUB3 binding motifs on SETD1A shows synergistic anti-leukemic effects. BuGZ/BUB3 localize to SETD1A-positive promoter-TSS regions and SETD1A-negative H3K4me1-positive enhancer regions adjacent to SETD1A-target genes. The GLEBS motif and intrinsically disordered region of BuGZ are required for both SETD1A binding and the leukemia cell proliferation. Despite the role of BuGZ/BUB3 at mitotic phase, the cell-cycle specific SETD1A restoration study indicates the roles of SETD1A at G1/S phase of cell cycle. Discovery of this complex indicates the indispensable role of the SETD1A-BuGZ axis in cancer.

Project description:The H3K4 methyltransferase SETD1A plays a crucial role in leukemia cell survival through its non-catalytic FLOS domain mediated recruitment of cyclin K and regulation of DNA damage response genes. In this study, we identify a functional nuclear localization signal and interaction partners for the FLOS domain. Our proteomics analysis against FLOS domain-binding partners reveals that the SETD1A FLOS domain binds mitosis-associated proteins BuGZ/BUB3. Targeted inhibition of both cyclin K and BuGZ/BUB3 binding motifs on SETD1A shows synergistic anti-leukemic effects. BuGZ/BUB3 localize to SETD1A-positive promoter-TSS regions and SETD1A-negative H3K4me1-positive enhancer regions adjacent to SETD1A-target genes. The GLEBS motif and intrinsically disordered region of BuGZ are required for both SETD1A binding and the leukemia cell proliferation. Despite the role of BuGZ/BUB3 at mitotic phase, the cell-cycle specific SETD1A restoration study indicates the roles of SETD1A at G1/S phase of cell cycle. Discovery of this complex indicates the indispensable role of the SETD1A-BuGZ axis in cancer.

Project description:MLL/SET methyltransferases catalyze methylation of histone 3 lysine 4 and play critical roles in development and cancer. We assessed MLL/SET proteins and found that SETD1A is required for survival of acute myeloid leukemia (AML) cells. Mutagenesis studies and CRISPR-Cas9 domain screening, showed the enzymatic SET domain is not necessary for AML cell survival but that a newly identified region, termed the FLOS (Functional Location on SETD1A) domain, is indispensable. FLOS disruption suppresses DNA damage response genes and induces p53-dependent apoptosis. The FLOS domain acts as a Cyclin K-binding site that is required for chromosomal recruitment of Cyclin K, and for DNA repair-associated gene expression in S phase. These data identify a connection between the chromatin regulator SETD1A and the DNA damage response that is independent of histone methylation, and suggests that targeting SETD1A and Cyclin K complexes may represent a therapeutic opportunity for AML and potentially other cancers.

Project description:Histone methyltransferase SETD1A is critical for acute myeloid leukemia (AML) cell survival, but the molecular mechanism driving SETD1A gene regulation remains elusive. To delineate the role of SETD1A, we utilize a protein degrader technology to induce rapid SETD1A degradation in AML cell lines. SETD1A degradation results in immediate downregulation of transcripts associated with DNA repair and heme biosynthesis pathways. CRISPR-based functional analyses and metabolomics revealed an essential role of SETD1A to maintain mitochondrial respiration in AML cells. These SETD1A targets are enriched in head-to-head (H2H) genes. SETD1A degradation disturbs a non-enzymatic SETD1A domain-dependent cyclin K function, increases the mono-Ser5P RNA polymerase II (RNAP2) at TSS, and induces the promoter-proximal pausing of RNAP2 in a strand-specific manner. This study reveals a non-enzymatic role for SETD1A in transcriptional pause release and provides insight into the mechanism of RNAP2 pausing and its function in cancer.

Project description:Histone methyltransferase SETD1A is critical for acute myeloid leukemia (AML) cell survival, but the molecular mechanism driving SETD1A gene regulation remains elusive. To delineate the role of SETD1A, we utilize a protein degrader technology to induce rapid SETD1A degradation in AML cell lines. SETD1A degradation results in immediate downregulation of transcripts associated with DNA repair and heme biosynthesis pathways. CRISPR-based functional analyses and metabolomics revealed an essential role of SETD1A to maintain mitochondrial respiration in AML cells. These SETD1A targets are enriched in head-to-head (H2H) genes. SETD1A degradation disturbs a non-enzymatic SETD1A domain-dependent cyclin K function, increases the mono-Ser5P RNA polymerase II (RNAP2) at TSS, and induces the promoter-proximal pausing of RNAP2 in a strand-specific manner. This study reveals a non-enzymatic role for SETD1A in transcriptional pause release and provides insight into the mechanism of RNAP2 pausing and its function in cancer.

Project description:We performed IP-MS for identification of SETD1A FLOS domain interacting proteins. Proteins were separated by SDS-PAGE, and digested by in-gel digestion protocol.

Project description:Histone methyltransferase SETD1A is critical for acute myeloid leukemia (AML) cell survival, but the molecular mechanism driving SETD1A gene regulation remains elusive. To delineate the role of SETD1A, we utilize a protein degrader technology to induce rapid SETD1A degradation in AML cell lines. SETD1A degradation results in immediate downregulation of transcripts associated with DNA repair and heme biosynthesis pathways. CRISPR-based functional analyses and metabolomics reveal an essential role of SETD1A to maintain mitochondrial respiration in AML cells. These SETD1A targets are enriched in head-to-head (H2H) genes. SETD1A degradation disrupts a non-enzymatic SETD1A domain-dependent cyclin K function, increases the Ser5P RNA polymerase II (RNAP2) at TSS, and induces the promoter-proximal pausing of RNAP2 in a strand-specific manner. This study reveals a non-enzymatic role for SETD1A in transcriptional pause release and provides insight into the mechanism of RNAP2 pausing and its function in cancer.

Project description:As Setd1a is a methyltransferase targeting H3K4, we performed H3K4Me3 ChIP in control and Setd1a KO cell to observe the effects of Setd1a on H3K4Me3. Chromatin immunoprecipitation DNA-sequencing (ChIP-seq) for H3K4Me in control mouse UPS and Setd1a KO mouse UPS cells .

Project description:Investigation of gene expression level changes in the SETD1A depleted cancer cells (shSETD1A), compared to the GFP depleted cancer cells (shGFP) as control. This analysis was performed to gain an understanding of the transcriptional changes induced by chromation modifications through H3K4 methyltransferase SETD1A. Key Word: SETD1A, Epigenetics