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:The role and function of FLOT1 in AML

Project description:Abnormal Notch1 expression has an important role in tumorigenesis. However, upstream control mechanisms for Notch1 are still insufficiently understood. Acute myeloid leukemia (AML) is one of the most common and lethal blood malignancies with limited possibilities for treatment. Thus, new therapeutic targets are urgently needed to improve current ineffective therapies. Herein, we found high Annexin A1 (ANXA1) expression was corelated with hyperproliferation of AML cells, and then we identified ANXA1 as a novel negative regulator of Notch1 function in AML. Mechanistically, ANXA1 directly bound to the intracellular domain of Notch1 (NICD) to target this tumor suppressor for degradation. Furthermore, NICD executed its tumor suppressive function through activation of the p15 promoter. Thus, ablation of the Notch1-p15-mediated tumor suppression by ANXA1 provided a novel mechanism of AML proliferation. In human AML patients, we discovered a mutual exclusive relation existed between ANXA1 and Notch1/p15, corroborating our mechanistic discovery. On the basis of these results, we reasonably speculate that targeting ANXA1 would provide an effective approach for treatment of AML. In support of this new therapeutic paradigm, we provided proof-of-concept data by antagonizing ANXA1 using NICD inhibitory peptides.

Project description:Aberrant regulation of chromatin modifiers is a common occurrence across many cancer types, and a key priority is to determine how specific alteration of these proteins, often enzymes, can be targeted therapeutically. MOZ, a histone acyltransferase, is recurrently fused to coactivators CBP, p300, and TIF2 in cases of Acute Myeloid Leukemia (AML). Using either pharmacological inhibition or targeted protein degradation in a mouse model for MOZ-TIF2-driven leukemia, we show that KAT6 (MOZ/MORF) enzymatic activity and the MOZ-TIF2 protein are necessary for indefinite proliferation in cell culture. Interestingly, MOZ enzymatic activity is selectively required in MOZ-TIF2 cells, as murine MLL-AF9 leukemic cells show no sensitivity to the WM-1119 MOZ inhibitor. MOZ-TIF2 directly regulates a small subset of genes encoding developmental transcription factors, augmenting their high expression. Transcription levels of these genes positively correlate with enrichment of histone H3 propionylation at lysine 23 (H3K23pr), a recently appreciated histone acylation associated with gene activation. Unexpectedly, we also show that MOZ-TIF2 and MLL-AF9 regulate transcription of largely non-overlapping gene sets, and their cellular models exhibit distinct sensitivities to multiple small molecule inhibitors directed against AML pathways. This is despite the shared genetic pathways of wild-type MOZ and MLL. Overall, our data provide insight into how aberrant regulation of MOZ contributes to leukemogenesis. We anticipate these experiments will inform future work identifying targeted therapies in the treatment of AML and other diseases involving MOZ-induced transcriptional dysregulation.

Project description:Aberrant regulation of chromatin modifiers is a common occurrence across many cancer types, and a key priority is to determine how specific alteration of these proteins, often enzymes, can be targeted therapeutically. MOZ, a histone acyltransferase, is recurrently fused to coactivators CBP, p300, and TIF2 in cases of Acute Myeloid Leukemia (AML). Using either pharmacological inhibition or targeted protein degradation in a mouse model for MOZ-TIF2-driven leukemia, we show that KAT6 (MOZ/MORF) enzymatic activity and the MOZ-TIF2 protein are necessary for indefinite proliferation in cell culture. Interestingly, MOZ enzymatic activity is selectively required in MOZ-TIF2 cells, as murine MLL-AF9 leukemic cells show no sensitivity to the WM-1119 MOZ inhibitor. MOZ-TIF2 directly regulates a small subset of genes encoding developmental transcription factors, augmenting their high expression. Transcription levels of these genes positively correlate with enrichment of histone H3 propionylation at lysine 23 (H3K23pr), a recently appreciated histone acylation associated with gene activation. Unexpectedly, we also show that MOZ-TIF2 and MLL-AF9 regulate transcription of largely non-overlapping gene sets, and their cellular models exhibit distinct sensitivities to multiple small molecule inhibitors directed against AML pathways. This is despite the shared genetic pathways of wild-type MOZ and MLL. Overall, our data provide insight into how aberrant regulation of MOZ contributes to leukemogenesis. We anticipate these experiments will inform future work identifying targeted therapies in the treatment of AML and other diseases involving MOZ-induced transcriptional dysregulation.

Project description:Aberrant regulation of chromatin modifiers is a common occurrence across many cancer types, and a key priority is to determine how specific alteration of these proteins, often enzymes, can be targeted therapeutically. MOZ, a histone acyltransferase, is recurrently fused to coactivators CBP, p300, and TIF2 in cases of Acute Myeloid Leukemia (AML). Using either pharmacological inhibition or targeted protein degradation in a mouse model for MOZ-TIF2-driven leukemia, we show that KAT6 (MOZ/MORF) enzymatic activity and the MOZ-TIF2 protein are necessary for indefinite proliferation in cell culture. Interestingly, MOZ enzymatic activity is selectively required in MOZ-TIF2 cells, as murine MLL-AF9 leukemic cells show no sensitivity to the WM-1119 MOZ inhibitor. MOZ-TIF2 directly regulates a small subset of genes encoding developmental transcription factors, augmenting their high expression. Transcription levels of these genes positively correlate with enrichment of histone H3 propionylation at lysine 23 (H3K23pr), a recently appreciated histone acylation associated with gene activation. Unexpectedly, we also show that MOZ-TIF2 and MLL-AF9 regulate transcription of largely non-overlapping gene sets, and their cellular models exhibit distinct sensitivities to multiple small molecule inhibitors directed against AML pathways. This is despite the shared genetic pathways of wild-type MOZ and MLL. Overall, our data provide insight into how aberrant regulation of MOZ contributes to leukemogenesis. We anticipate these experiments will inform future work identifying targeted therapies in the treatment of AML and other diseases involving MOZ-induced transcriptional dysregulation.

Project description:Community and metagenomic dynamics reveal Bacteroidota's role in widespread enzymatic algae cell wall degradation

Project description:Acute myeloid leukemia (AML) is a hematopoietic cancer characterized by the proliferation and accumulation of aberrant immature myeloid progenitor blasts in bone marrow and peripheral blood. Venetoclax (VEN), a selective B-cell lymphoma 2 (BCL-2) inhibitor, has received FDA approval for AML treatment in combination with hypomethylating agents (HMA). However, treatment failure and therapy resistance present an urgent need for new therapies to overcome VEN resistance and enhance VEN efficacy. We propose inhibition of SUMOylation as a novel therapy with the potential to address this need. SUMOylation regulates protein function by covalently attaching Small Ubiquitin-like MOdifier (SUMO) proteins to target proteins via an enzymatic cascade. Our study aims to evaluate the effects of SUMOylation inhibition on anti-AML activity of VEN and dissert the underlying mechanism.

Project description:Non-optimal fetal environments resulting in low birth weight have epidemiologically been associated with a higher risk of adult diseases. In animal models, maternal undernutrition has successfully demonstrated that offspring owed increased risks for adult diseases. In mice, shorten life span was also demonstrated in offspring following maternal undernutrition. In the present study, we treated pregnant mice with 50% food restriction (FR), and performed global gene expression and promotor DNA methylation profiling on the fetal livers. Considering that effects of food restriction is opposite between before and after birth, we further searched genes which are regulated oppositely against adult calorie restriction (CR) and commonly against aging. Among searched genes, trib1 has already been demonstrated to contribute to a risk of cardiovascular disease, hypertriglyceridaemia and insulin resistance. The present result suggests that expression of trib1 is affected by maternal nutrition, and is one of the most responsible genes for developmental origins of metabolic syndrome. In addition, lepr was also down-regulated by maternal FR, suggested a potential role of this gene in induction of obesity and diabetes. Promotor DNA methylation profiling as well as gene expression profiling revealed that glucocorticoid receptor target genes were regulated by maternal FR. This finding supports previous studies that suggest an important role for glucocorticoid in developmental origins of metabolic syndrome. In the immune system, most of the genes related to interferon were down-regulated in their expression with up-regulation of their promoter DNA methylation. The profiling also suggested diminished NF-κB signalling. These results suggested that maternal FR affected development of the immune system. We presented here a list of genes responsible for developmental origins of health and disease, which were regulated oppositely against adult CR, and commonly against aging, and also affected their promotor DNA methylation. The present list hopefully contributes to prediction of risks for non communicable diseases, and also prediction of prenatal environment of nutrition from offspring materials. Here we carried out global gene expression profiling analysis on the fetal mouse liver following maternal 50% FR. Considering that opposite effects of nutrition between the fetus and adult, we further analyzed our fetal array data by comparing with data from their mothers, and array data on the effect of CR and aging in previous reports using adult rodent tissues. In addition, we performed global DNA methylation analysis using mouse promoter microarray, and compared the results with data of the gene expression analysis. Finally, we presented a list of candidate genes responsible for DOHaD.