Single cell multiomics reveal divergent effects of DNMT3A and TET2 mutant clonal hematopoiesis in inflammatory response.

Publication date: Dec 04, 2024

DNMT3A and TET2 are epigenetic regulator genes commonly mutated in age-related clonal hematopoiesis (CH). Despite having opposed epigenetic functions, these mutations are associated with increased all-cause mortality and a low risk for progression to hematological neoplasms. While individual impacts on the epigenome have been described using different model systems, the phenotypic complexity in humans remains to be elucidated. Here we make use of a natural inflammatory response occurring during coronavirus disease 2019 (COVID-19), to understand the association of these mutations with inflammatory morbidity (acute respiratory distress syndrome-ARDS) and mortality. We demonstrate the age-independent, negative impact of DNMT3A mutant CH on COVID-19-related ARDS and mortality. Using single cell (sc-) proteogenomics we show that DNMT3A mutations involve myeloid and lymphoid lineage cells. Using single cell multiomics sequencing, we identify cell-specific gene expression changes associated with DNMT3A mutations, along with significant epigenomic deregulation affecting enhancer accessibility, resulting in overexpression of IL32, a proinflammatory cytokine that can result in inflammasome activation in monocytes and macrophages. Finally, we show with single cell resolution that the loss of function of DNMT3A is directly associated with increased chromatin accessibility in mutant cells. Hence, we demonstrate the negative prognostic impact of DNMT3Amt CH on COVID-19 related ARDS and mortality. DNMT3Amt CH in the context of COVID-19, was associated with inflammatory transcriptional priming, resulting in overexpression of IL32. This overexpression was secondary to increased chromatic accessibility, specific to DNMT3Amt CH cells. DNMT3Amt CH can thus serve as a potential biomarker for adverse outcomes in COVID-19.

Concepts Keywords
Coronavirus Accessibility
Hematopoiesis Ards
Il32 Cells
Mutant Covid
Proteogenomics Dnmt3a
Dnmt3amt
Increased
Inflammatory
Mortality
Multiomics
Mutant
Mutations
Overexpression
Related
Single

Semantics

Type Source Name
disease IDO cell
disease MESH clonal hematopoiesis
disease MESH hematological neoplasms
disease MESH coronavirus disease 2019
disease MESH morbidity
disease MESH acute respiratory distress syndrome

Original Article

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