Functional hematopoietic stem (HSC) and progenitor cells (HPC) are responsible for the replenishment of blood/immune cells, are a source of treatment for diseases, and when dysregulated are a source of hematological neoplasia. To identify factors that impact HSC/HPC functional competency, we performed a transcriptomic screen which revealed that human cord blood (CB) HSCs/HPCs capable of early engraftment in an NSG mouse model of transplantation exhibited enriched expression of gene programs that vary with changes in oxygen (O 2) availability compared to non-transplanted input cells. This is physiologically and clinically relevant as HSCs/HPCs and diseased hematopoietic cells such as acute myeloid leukemia (AML) are exposed to O 2 tensions ranging from <1% to 21% as they function in various anatomical sites or are harvested for clinical applications. Thus, there are translational and practical rationales for understanding the growth and functional properties that hematopoietic cells exhibit across the range of O 2 they experience physiologically or artificially, which we examined here.
First we found significantly different frequencies of HSCs/HPCs and colony forming units (CFU) in human bone marrow (BM), mobilized peripheral blood (PB), and CB, which have varied O 2 tensions, suggesting O 2 availability may impact hematopoiesis. To directly examine this, human CB CD34+ cells were split and plated in CFU assays or expanded in growth stimulating conditions at 1% O 2, 3% O 2, 5% O 2, 14% O 2 (physiologic tensions), or 21% O 2 (processing tension) . HPCs expanded best and formed more differentiated CFUs in high physiologic O 2 tensions and extra physiologic O 2 tensions, while HSCs expanded better and more potent CFUs were formed in a mid-physiologic O 2 tension (5%). This suggests that O 2 dependent pathways are critical to HSC/HPC growth but there may be a “sweet spot” for early HSCs/HPCs that allows for proliferation while maintaining self-renewal and potency to maintain a pool of primitive cells, possibly mirroring in vivo O 2 responses. In in vivo functional HSC/HPC analyses, NSG mice transplanted with CB units expanded in physiologic O 2 exhibited significantly better early neutrophil recovery and long-term myeloid reconstitution compared to input, suggesting that growth and maintenance of HSC/ myeloid HPC functional competency is better balanced in physiologic O 2 compared to extra physiologic tensions. Platelet recovery and lymphoid reconstitution were significantly better in mice receiving uncultured control CB, suggesting expansion does not affect all HSC/HPC subpopulations equally. Mechanistically, cells grown in low O 2 tensions (1-3%) had higher frequencies of early HSCs/HPCs, significantly lower intracellular ROS levels, a significantly higher percentage of cells in cell cycle G0, and lower levels of phosphorylated γH2AX than those grown in higher O 2. These data suggest that while to some extent HSCs/HPCs require O 2 to proliferate, they also exhibit properties associated with exhaustion when maintained in higher O 2.
We next examined the effects varying O 2 tensions have on diseased hematopoietic cells using primary mouse AML cells or oncogene transformed human CB CD34+ cell lines. AML cells proliferated significantly more rapidly and formed more CFUs in higher O 2 tensions, suggesting that O 2 sensing pathways may be a dependency in AML that could affect disease progression as local O 2 tensions become perturbed. AML cells grown in lower O 2 exhibited lower resting levels of phosphorylated γH2AX (measured by flow cytometry) and lower O 2 consumption rates (measured by Seahorse metabolic flux analyzer), suggesting they are less susceptible to cellular stress. In line with this, AML cells maintained in low O 2 exhibited significantly better proliferation and recovery after treatment with the chemotherapeutic cytarabine compared to those in higher O 2 tensions. Thus, diseased cells growing in lower O 2 niches may be less susceptible to treatment and therefore may be a source of chemoresistance or relapse.
These data reveal important roles for O 2 in balancing hematopoietic cell growth with normal and diseased cell function. Manipulating O 2 tension or O 2 sensing pathways could be used to improve HSC/HPC expansion for transplantation or to treat disease. Transcriptomic studies of HSCs/HPCs and AML cells are ongoing to determine the O 2 sensing mechanisms that dictate cellular function.
Disclosures
No relevant conflicts of interest to declare.
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