Abstract
Background:
Environmental factors must play a significant role in the emergence of clonal hematopoiesis since only a fraction of individuals harboring clonal hematopoiesis of indeterminate potential (CHIP) mutations develop hematologic malignancy. Mouse models of chronic inflammation have demonstrated clonal expansion of Tet2 and Dnmt3a knockout hematopoietic cells while Ppm1d mutated clones exhibit clonal dominance in response to cytotoxic DNA damaging chemotherapy stress. Epidemiologic studies have associated smoking behavior with clonal hematopoiesis but the leukemogenic effects of cigarette smoke on hematopoietic stem cells (HSCs) are poorly defined. In addition, the exploding use of electronic (e)-cigarettes has led to significant concern on their detrimental health effects plus studies of E-cigarettes on the hematopoietic system are non-existent. Here, we investigated the role of cigarette smoke and E-cigarette aerosols in promoting clonal expansion of common CHIP mutations. We hypothesize that one or more specific somatic CHIP mutation displays a fitness advantage in the presence of cigarette smoke and/or e-cigarette aerosols.
Methods:
Competitive bone marrow transplant assays were used to determine the development of clonal expansion in response to cigarette smoke and E-cigarette aerosols using Tet2 knockout (Tet2 -/-), Dnmt3a R878H and Jak2 V617F genetically modified mice. Lethally irradiated recipient mice in the CD45.1/2 background were transplanted with whole bone marrow cells from wild type (WT) (CD45.1) and mutant (CD45.2) mice. Ratio of cells transplanted were 1:10 for Tet2 -/- and WT; 1:5 for Dnmt3a R878H and WT and 1:1 for Jak2 V617F and WT. Transplanted mice were exposed to cigarette smoke or E-cigarette aerosols using a nose-only inhalation exposures system for 2 hours/day, 4 days/week for 2 or 3 months. Control mice were exposed to room air using the nose-only inhalation approach.
Results:
After 2 months of exposure, we observed that Tet2 -/- cells had significantly expanded in the smoke group (paired t-test, p<0.05) while there was no significant difference in the air group (Fig. 1A). Furthermore, this increase in Tet2 -/- cells was more pronounced in the myeloid cell subset (Fig. 1B). While the knock-in mouse model of Jak2 V617F does not display a competitive advantage in a lethally irradiated bone marrow transplant setting, we observed persisting levels of Jak2 V617F mutant cells following smoke exposure but significantly reduced levels in the air group, illustrating that the mutant cells prevail in a smoke environment (Fig. 1C). During sacrifice of the Jak2 V617F transplanted and exposed mice, long-term HSCs in the bone marrow exhibited a trend towards increased bromodeoxyuridine (BrdU) incorporation and increased DNA damage as determined by H2AX staining (Fig 1D). Meanwhile, E-cigarette aerosol exposure of mice transplanted with Dnmt3a R878H cells, displayed increased levels of circulating mutant cells compared to the air group (Fig. 1E) (repeated measures, 2-way ANOVA).
Conclusion:
In vivo exposure of mouse models of CHIP to cigarette smoke and E-cigarette aerosols promotes mutant cell expansion over time. Our data indicate that more than one mutation is selected by environmental factors in the form of tobacco products. This data is important to guide us in preventive medicine and early detection of clonal hematopoiesis. Future research is aimed at deciphering the molecular responses of WT cells to cigarette smoke and E-cigarette aerosols and strategies to preserve WT stem cell fitness in the context of smoking and E-cigarette usage.
No relevant conflicts of interest to declare.