In this issue of Blood, Rao et al reveal important insights into how hematopoietic stem cell (HSC) subpopulations contribute to myeloproliferative neoplasm (MPN) pathogenesis, and how these populations are perturbed in the setting of pegylated-interferon (pegIFN) therapy.1
The advent of pegylated forms of interferon (IFN) has provided renewed interest for use of this agent in the clinical setting. Recent studies demonstrate response rates on par with those of traditional cytoreductive therapy,2,3 and lower rates of discontinuation have been observed as a result of an improved toxicity profile in comparison with their nonpegylated counterparts. Importantly, unlike other currently available MPN therapies (including JAK inhibitors),4 IFN remains the only treatment in MPNs shown to reduce mutant clonal fraction and, in a minority of patients, induce molecular remissions,5 suggesting that pegIFN can selectively impair clonal outgrowth at the level of the mutant MPN stem cell.
In recent years, sophisticated lineage-tracing techniques and single-cell approaches have revealed the striking heterogeneity of classically defined immunophenotypic stem cell populations6 and called into question the traditional hierarchical model of human blood cell production. Megakaryocyte (Mk)-biased HSCs have emerged as an important branch point, with some data suggesting that Mk-biased HSCs can exist at the top of the hematopoietic hierarchy and retain self-renewal capability while also being able to differentiate directly into mature Mks.7-9 This suggests that even at the primitive stem cell level, HSCs are already primed for cell-type–specific lineage output. It is hypothesized that the specific lineage-primed HSC population affected by a somatic MPN driver mutation might influence the phenotypic heterogeneity observed in MPNs. Improved understanding then of how MPN driver mutations, occurring in these individual HSC subpopulations, contribute to disease development, and, more importantly, how these cell populations can be influenced by disease-modifying therapies, will likely have critical clinical implications.
In their article, Rao et al are the first to evaluate Mk-biased HSCs in the MPN context. Using JAK2V617F mouse models as well as primary MPN patient samples, they evaluate the frequency and significance of CD41hi (megakaryocytic biased) vs CD41lo HSCs. Consistent with the expanded myeloid/megakaryocytic cell populations often associated with MPNs, the authors observe increased frequencies of Mk-biased CD41hi HSC populations in JAK2V617F mice in comparison with wild-type controls. In clinical isolates, the frequency of CD41hi HSCs is highest in polycythemia vera in comparison with other MPN subtypes and correlates with a JAK2V617F mutant allele burden, lending further support to the notion that quantitative dysregulation of JAK2 signaling itself can skew HSC subpopulations toward a particular lineage. Furthermore, the authors demonstrate that, although murine CD41hi HSCs demonstrate enhanced Mk output in vitro, they lack MPN disease-initiating potential in transplantation assays. This suggests that CD41hi HSCs, at least in MPN, represent a downstream, more committed population with reduced self-renewal capacity compared with CD41lo HSCs. Consistent with this hypothesis, CD41hi HSCs were more metabolically active and showed increased propensity to exit quiescence and enter the cell cycle than CD41lo HSCs, an effect more pronounced in MPN mutant cells than those of wild-type HSCs. Critically, acute IFN pathway activation with polyinosinic:polycytidylic acid or more prolonged stimulation with pegIFN treatment resulted in a pronounced expansion of JAK2V617F CD41hi HSCs with relative reduction in CD41lo HSCs. Based on this, the authors suggest that CD41hi Mk-biased HSCs in MPNs expand at the expense of primitive CD41lo cells and, in turn, promote eventual exhaustion of MPN-sustaining CD41lo HSCs and reduction in mutant clonal fraction over time with continued pegIFN therapy.
Although this important work provides a fascinating look at how Mk-biased HSC subsets expand in the setting of MPN and are skewed in response to IFN treatment, several intriguing questions remain. In the general context of hematopoiesis, it still remains unclear how these Mk-biased cell populations expand and/or differentiate in relation to other HSC subsets, specifically CD41lo HSCs. Are preexisting CD41hi cells already primed to expand in response to IFN, or are CD41lo HSCs truly “converted” into CD41hi HSCs with chronic IFN therapy? Furthermore, over what period of time are mutant stem cells “exhausted,” and to what degree are MPN mutant stem cells preferentially sensitive to this effect? In addition, these data provide thought-provoking questions on the potential non–cell-autonomous effects of MPN mutant HSCs on wild-type CD41hi HSC fractions and megakaryocytic output. Does the presence of a JAK2V617F mutant clone influence the frequency and cell output of its surrounding wild-type HSC counterparts? Finally, despite showing that Mk-biased CD41hi HSCs are expanded in MPNs, these cell populations appearing to lose their self-renewal potential suggests that still unknown factors, operating at the primitive stem cell level, are required for the phenotypic variability observed across MPNs.
As our understanding of the cellular heterogeneity of the HSC compartment improves, so too will our understanding of how MPN mutant stem cells survive to sustain disease. In turn, hopefully, we can design improved therapeutic strategies that better target MPN clones and those mutated cells at the earliest stages of the hematopoietic hierarchy. This work, taken together with recent clinical studies of IFNs in MPNs, provides a glimpse into MPN stem cell biology with the goal of informing additional therapeutic studies in MPNs and other stem cell–derived hematopoietic malignancies.
Conflict-of-interest disclosure: R.L.L. is on the supervisory board of Qiagen and is a scientific advisor to Loxo (until 2019), Imago, C4 Therapeutics, Mana, Auron, Ajax, Kurome, Mission Bio, Prelude, Scorpion, and Isoplexis, which each include an equity interest. He receives research support from and consulted for Celgene and Roche, he has received research support from Constellation, Roche, and Prelude Therapeutics, and he has consulted for Bridge Therapeutics, BMS, Lilly, Incyte, Novartis, and Janssen. He has received honoraria from Astra Zeneca, Constellation, Lilly, and Amgen for invited lectures and from Gilead for grant reviews. A.D. declares no competing financial interests.
