Mycobacterium tuberculosis (Mtb) employs multiple strategies to evade host immune responses and persist within macrophages. We have previously shown that the cell envelope-associated Mtb serine hydrolase, Hip1, prevents robust macrophage activation and dampens host pro-inflammatory responses, allowing Mtb to delay immune detection and accelerate disease progression. We now provide key mechanistic insights into the molecular and biochemical basis of Hip1 function. We establish that Hip1 is a serine protease with activity against protein and peptide substrates. Further, we show that the Mtb GroEL2 protein is a direct substrate of Hip1 protease activity. Cleavage of GroEL2 is specifically inhibited by serine protease inhibitors. We mapped the cleavage site within the N-terminus of GroEL2 and confirmed that this site is required for proteolysis of GroEL2 during Mtb growth. Interestingly, we discovered that Hip1-mediated cleavage of GroEL2 converts the protein from a multimeric to a monomeric form. Moreover, ectopic expression of cleaved GroEL2 monomers into the hip1 mutant complemented the hyperinflammatory phenotype of the hip1 mutant and restored wild type levels of cytokine responses in infected macrophages. Our studies point to Hip1-dependent proteolysis as a novel regulatory mechanism that helps Mtb respond rapidly to changing host immune environments during infection. These findings position Hip1 as an attractive target for inhibition for developing immunomodulatory therapeutics against Mtb.
In the last decade, large-scale genomic studies in patients with hematologic malignancies identified recurrent somatic alterations in epigenetic modifier genes. Among these, the de novo DNA methyltransferase DNMT3A has emerged as one of the most frequently mutated genes in adult myeloid as well as lymphoid malignancies and in clonal hematopoiesis. In this review, we discuss recent advances in our understanding of the biochemical and structural consequences of DNMT3A mutations on DNA methylation catalysis and binding interactions and summarize their effects on epigenetic patterns and gene expression changes implicated in the pathogenesis of hematologic malignancies. We then review the role played by mutant DNMT3A in clonal hematopoiesis, accompanied by its effect on immune cell function and inflammatory responses. Finally, we discuss how this knowledge informs therapeutic approaches for hematologic malignancies with mutant DNMT3A.
Mutations in the DNA methyltransferase 3A (DNMT3A) gene are recurrent in de novo acute myeloid leukemia (AML) and are associated with resistance to standard chemotherapy, disease relapse, and poor prognosis, especially in advanced-age patients. Previous gene expression studies in cells with DNMT3A mutations identified deregulation of cell cycle-related signatures implicated in DNA damage response and replication fork integrity, suggesting sensitivity to replication stress. Here we tested whether pharmacologically-induced replication fork stalling creates a therapeutic vulnerability in cells with DNMT3A(R882) mutations. We observed increased sensitivity to nucleoside analogs such as cytarabine in multiple cellular systems expressing mutant DNMT3A, ectopically or endogenously, in vitro and in vivo. Analysis of DNA damage signaling in response to cytarabine revealed persistent intra-S phase checkpoint activation, accompanied by accumulation of DNA damage in the DNMT3A(R882) overexpressing cells, which was only partially resolved after drug removal and carried through mitosis, resulting in micronucleation. Pulse-chase double-labeling experiments with EdU and BrdU after cytarabine wash-out demonstrated that cells with DNMT3A(mut) were able to restart replication but showed a higher rate of fork collapse. Gene expression profiling by RNA-seq identified deregulation of pathways associated with cell cycle progression and p53 activation, as well as metabolism and chromatin. Together, our studies show that cells with DNMT3A mutations have a defect in recovery from replication fork arrest and subsequent accumulation of unresolved DNA damage, which may have therapeutic tractability. These results demonstrate that, in addition to its role in epigenetic control, DNMT3A contributes to preserving genome integrity during DNA replication.
Purpose: In acute myeloid leukemia (AML), recurrent DNA methyltransferase 3A (DNMT3A) mutations are associated with chemoresistance and poor prognosis, especially in advanced-age patients. Gene-expression studies in DNMT3A-mutated cells identified signatures implicated in deregulated DNA damage response and replication fork integrity, suggesting sensitivity to replication stress. Here, we tested whether pharmacologically induced replication fork stalling, such as with cytarabine, creates a therapeutic vulnerability in cells with DNMT3A(R882) mutations. Experimental Design: Leukemia cell lines, genetic mouse models, and isogenic cells with and without DNMT3A(mut) were used to evaluate sensitivity to nucleoside analogues such as cytarabine in vitro and in vivo, followed by analysis of DNA damage and signaling, replication restart, and cell-cycle progression on treatment and after drug removal. Transcriptome profiling identified pathways deregulated by DNMT3A(mut) expression. Results: We found increased sensitivity to pharmacologically induced replication stress in cells expressing DNMT3A(R882)-mutant, with persistent intra–S-phase checkpoint activation, impaired PARP1 recruitment, and elevated DNA damage, which was incompletely resolved after drug removal and carried through mitosis. Pulse-chase double-labeling experiments with EdU and BrdU after cytarabine washout demonstrated a higher rate of fork collapse in DNMT3A(mut)-expressing cells. RNA-seq studies supported deregulated cell-cycle progression and p53 activation, along with splicing, ribosome biogenesis, and metabolism. Conclusions: Together, our studies show that DNMT3A mutations underlie a defect in recovery from replication fork arrest with subsequent accumulation of unresolved DNA damage, which may have therapeutic tractability. These results demonstrate that, in addition to its role in epigenetic control, DNMT3A contributes to preserving genome integrity during replication stress. See related commentary by Viny, p. 573
Mutations in the DNA methyltransferase 3A (DNMT3A) gene are recurrent in de novoacute myeloid leukemia (AML) and are associated with poor prognosis. Although studies demonstrated survival benefit of induction chemotherapy dose intensification, outcomes remain unsatisfactory in most patients due to advanced age, comorbidities, and hence inability to tolerate treatment. Clinical trials of low-intensity regimens combining cytarabine and cladribine, nucleoside analog chain terminators that stall DNA replication, appear to be safe and effective, and tend to particularly benefit patients with DNMT3Amutations. Consistently, we observe increased sensitivity to cytarabine, fludarabine, and cladribine in multiple cellular systems harboring mutant DNMT3Ain vitro (Figure 1A, B). Differential sensitivity to cytarabine was confirmed in normal and leukemic primary bone marrow cells derived from mice with and without Dnmt3a mutations ex vivo (Figure 1C). Dynamic chromatin organization plays a pivotal role in DNA-associated cellular processes including DNA replication and damage repair. We previously found altered chromatin remodeling in cells expressing mutant DNMT3A after genotoxic stress. Gene expression studies by us and others demonstrated negative enrichment of cell cycle related signatures including G2/M checkpoint adaptation, in cells with DNMT3A mutations. These signatures are implicated in DNA damage response and replication fork integrity and suggest sensitivity to replication stress. To investigate the mechanism of differential sensitivity to cytarabine-induced DNA damage, we overexpressed wildtype (WT) or R882 mutant (MUT) forms of DNMT3A in U2OS cells, a well-established model for DNA damage studies. Analysis of the DNA damage signaling proficiency in response to cytarabine revealed persistent intra-S phase checkpoint activation (phospho-CHK1), accompanied by accumulation of DNA damage visualized by γH2A.X foci and by Comet assay in the DNMT3A(mut) overexpression cells (Figure 1D). This damage was only partially resolved after drug had been removed and cells were allowed to repair the DNA (Figure 1E), and was carried through mitosis, resulting in increased rate of micronucleation.At the same time, DNMT3A mutant cells remained proficient in initiating homology-directed repair (HDR) and non-homologous end joining (NHEJ) pathways, evidenced by RAD51 and 53BP-1 foci formation, respectively. These data demonstrate enhanced sensitivity to cytarabine in cells expressing mutant DNMT3A is due to increased susceptibility to DNA damage during replication, rather than defects in double-strand DNA break repair. In support of this, cells with mutant DNMT3Awere characterized by accentuated replication stress as evidenced by high levels of phospho-RPA, which persisted after drug wash-out (Figure 1F). Consistently, DNMT3A-mutant cells treated with cytarabine were characterized by a higher number and a larger area of PCNA foci. Pulse-chase double-labeling experiments with EdU and BrdU after cytarabine wash-out demonstrated that while the overall kinetics of replication restart remained unchanged, cells with DNMT3A(mut) showed higher rate of fork collapse and increased reliance on latent replication origins (Figure 1G). Gene expression profiling by RNA-seq identified dysregulation of pathways associated with cell cycle progression, specifically G1/S phase transition, DNA replication, DNA integrity checkpoint, and chromatin. Our studies show cells with DNMT3A mutations have a defect in recovery from replication fork arrest and subsequent accumulation of unresolved DNA damage, which may have therapeutic tractability. These results demonstrate, in addition to its role in epigenetic control, DNMT3A contributes to preserving genome integrity during DNA replication and suggest that cytarabine-induced replication fork stalling may further synergize with other agents aimed at DNA damage and replication. Figure 1 Disclosures No relevant conflicts of interest to declare.
Clonal hematopoiesis (CH) is defined as clonal expansion of mutant hematopoietic stem cells absent diagnosis of a hematologic malignancy. Presence of CH in solid tumor patients, including colon cancer, correlates with shorter survival. We hypothesized that bone marrow-derived cells with heterozygous loss-of-function mutations of DNMT3A, the most common genetic alteration in CH, contribute to the pathogenesis of colon cancer. In a mouse model that combines colitis-associated colon cancer with experimental CH driven by Dnmt3a(+/del), we found higher tumor penetrance and increased tumor burden compared to controls. Histopathological analysis revealed accentuated colonic epithelium injury, dysplasia and adenocarcinoma formation. Transcriptome profiling of colon tumors identified enrichment of gene signatures associated with carcinogenesis, including angiogenesis. Treatment with the angiogenesis inhibitor axitinib eliminated the colon tumor-promoting effect of experimental CH driven by Dnmt3a haploinsufficiency. This study provides conceptually novel insights into non-tumor-cell-autonomous effect of hematopoietic alterations on colon carcinogenesis and identifies potential therapeutic strategies.
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