E-Cigarette Exposure Decreases Bone Marrow Hematopoietic Progenitor Cells.

Electronic cigarettes (E-cigs) generate nicotine containing aerosols for inhalation and have emerged as a popular tobacco product among adolescents and young adults, yet little is known about their health effects due to their relatively recent introduction. Few studies have assessed the long-term effects of inhaling E-cigarette smoke or vapor. Here, we show that two months of E-cigarette exposure causes suppression of bone marrow hematopoietic stem and progenitor cells (HSPCs). Specifically, the common myeloid progenitors and granulocyte-macrophage progenitors were decreased in E-cig exposed animals compared to air exposed mice. Competitive reconstitution in bone marrow transplants was not affected by two months of E-cig exposure. When air and E-cig exposed mice were challenged with an inflammatory stimulus using lipopolysaccharide (LPS), competitive fitness between the two groups was not significantly different. However, mice transplanted with bone marrow from E-cigarette plus LPS exposed mice had elevated monocytes in their peripheral blood at five months post-transplant indicating a myeloid bias similar to responses of aged hematopoietic stem cells (HSC) to an acute inflammatory challenge. We also investigated whether E-cigarette exposure enhances the selective advantage of hematopoietic cells with myeloid malignancy associated mutations. E-cigarette exposure for one month slightly increased JAK2V617F mutant cells in peripheral blood but did not have an impact on TET2-/- cells. Altogether, our findings reveal that chronic E-cigarette exposure for two months alters the bone marrow HSPC populations but does not affect HSC reconstitution in primary transplants.

N-acetylcysteine inhibits thrombosis in a murine model of myeloproliferative neoplasm.

Thrombosis is a major cause of mortality in patients with myeloproliferative neoplasms (MPNs), though there is currently little to offer patients with MPN beyond aspirin and cytoreductive therapies such as hydroxyurea for primary prevention. Thrombogenesis in MPN involves multiple cellular mechanisms, including platelet activation and neutrophil-extracellular trap formation; therefore, an antithrombotic agent that targets one or more of these processes would be of therapeutic benefit in MPN. Here, we treated the JAK2V617F knockin mouse model of polycythemia vera with N-acetylcysteine (NAC), a sulfhydryl-containing compound with broad effects on glutathione replenishment, free radical scavenging, and reducing disulfide bonds, to investigate its antithrombotic effects in the context of MPN. Strikingly, NAC treatment extended the lifespan of JAK2V617F mice without impacting blood counts or splenomegaly. Using an acute pulmonary thrombosis model in vivo, we found that NAC reduced thrombus formation to a similar extent as the irreversible platelet inhibitor aspirin. In vitro analysis of platelet activation revealed that NAC reduced thrombin-induced platelet-leukocyte aggregate formation in JAK2V617F mice. Furthermore, NAC reduced neutrophil extracellular trap formation in primary human neutrophils from patients with MPN as well as healthy controls. These results provide evidence that N-acetylcysteine inhibits thrombosis in JAK2V617F mice and provide a pre-clinical rationale for investigating NAC as a therapeutic to reduce thrombotic risk in MPN.

Defective negative regulation of Toll-like receptor signaling leads to excessive TNF-α in myeloproliferative neoplasm.

Patients with myeloproliferative neoplasms (MPN) have high levels of inflammatory cytokines, some of which drive many of the debilitating constitutional symptoms associated with the disease and may also promote expansion of the neoplastic clone. We report here that monocytes from patients with MPN have defective negative regulation of Toll-like receptor (TLR) signaling that leads to unrestrained production of the inflammatory cytokine tumor necrosis factor α (TNF-α) after TLR activation. Specifically, monocytes of patients with MPN are insensitive to the anti-inflammatory cytokine interleukin 10 (IL-10) that negatively regulates TLR-induced TNF-α production. This inability to respond to IL-10 is a not a direct consequence of JAK2 V617F , as the phenotype of persistent TNF-α production is a feature of JAK2 V617F and wild-type monocytes alike from JAK2 V617F -positive patients. Moreover, persistent TNF-α production was also discovered in the unaffected identical twin of a patient with MPN, suggesting it could be an intrinsic feature of those predisposed to acquire MPN. This work implicates sustained TLR signaling as not only a contributor to the chronic inflammatory state of MPN patients but also a potential predisposition to acquire MPN.

JAK2(V617I) results in cytokine hypersensitivity without causing an overt myeloproliferative disorder in a mouse transduction-transplantation model.

A germline JAK2(V617I) point mutation results in hereditary thrombocytosis and shares some phenotypic features with myeloproliferative neoplasm, a hematologic malignancy associated with a somatically acquired JAK2(V617F) mutation. We established a mouse transduction-transplantation model of JAK2(V617I) that recapitulated the phenotype of humans with germline JAK2(V617I). We directly compared the phenotypes of JAK2(V617I) and JAK2(V617F) mice. The JAK2(V617I) mice had increased marrow cellularity with expanded myeloid progenitor and megakaryocyte populations, but this phenotype was less severe than that of JAK2(V617F) mice. JAK2(V617I) resulted in cytokine hyperresponsiveness without constitutive activation in the absence of ligand, whereas JAK2(V617F) resulted in constitutive activation. This may explain why JAK2(V617I) produces a mild myeloproliferative phenotype in the mouse model, as well as in humans with germline JAK2(V617I) mutations.