Brahmananda R. Chitteti

Dipeptidylpeptidase 4 negatively regulates colony-stimulating factor activity and stress hematopoiesis

Enhancement of hematopoietic recovery after radiation, chemotherapy, or hematopoietic stem cell (HSC) transplantation is clinically relevant. Dipeptidylpeptidase (DPP4) cleaves a wide variety of substrates, including the chemokine stromal cell-derived factor-1 (SDF-1). In the course of experiments showing that inhibition of DPP4 enhances SDF-1–mediated progenitor cell survival, ex vivo cytokine expansion and replating frequency, we unexpectedly found that DPP4 has a more general role in regulating colony-stimulating factor (CSF) activity. DPP4 cleaved within the N-termini of the CSFs granulocyte-macrophage (GM)-CSF, G-CSF, interleukin-3 (IL-3) and erythropoietin and decreased their activity. Dpp4 knockout or DPP4 inhibition enhanced CSF activities both in vitro and in vivo. The reduced activity of DPP4-truncated versus full-length human GM-CSF was mechanistically linked to effects on receptor-binding affinity, induction of GM-CSF receptor oligomerization and signaling capacity. Hematopoiesis in mice after radiation or chemotherapy was enhanced in Dpp4−/− mice or mice receiving an orally active DPP4 inhibitor. DPP4 inhibition enhanced engraftment in mice without compromising HSC function, suggesting the potential clinical utility of this approach.

Impact of interactions of cellular components of the bone marrow microenvironment on hematopoietic stem and progenitor cell function

Hematopoietic stem (HSC) and progenitor (HPC) cell fate is governed by intrinsic and extrinsic parameters. We examined the impact of hematopoietic niche elements on HSC and HPC function by analyzing the combined effect of osteoblasts (OBs) and stromal cells (SCs) on Lineage(-)Sca-1(+)CD117(+) (LSK) cells. CFU expansion and marrow repopulating potential of cultured Lineage(-)Sca-1(+)CD117(+) cells were significantly higher in OB compared with SC cultures, thus corroborating the importance of OBs in the competence of the hematopoietic niche. OB-mediated enhancement of HSC and HPC function was reduced in cocultures of OBs and SCs, suggesting that SCs suppressed the OB-mediated hematopoiesis-enhancing activity. Although the suppressive effect of SC was mediated by adipocytes, probably through up-regulation of neuropilin-1, the OB-mediated enhanced hematopoiesis function was elaborated through Notch signaling. Expression of Notch 2, Jagged 1 and 2, Delta 1 and 4, Hes 1 and 5, and Deltex was increased in OB cultures and suppressed in SC and OB/SC cultures. Phenotypic fractionation of OBs did not segregate the hematopoiesis-enhancing activity but demonstrated that this function is common to OBs from different anatomic sites. These data illustrate that OBs promote in vitro maintenance of hematopoietic functions, including repopulating potential by up-regulating Notch-mediated signaling between HSCs and OBs.

Enhancing Hematopoietic Stem Cell Transplantation Efficacy by Mitigating Oxygen Shock

Hematopoietic stem cells (HSCs) reside in hypoxic niches within bone marrow and cord blood. Yet, essentially all HSC studies have been performed with cells isolated and processed in non-physiologic ambient air. By collecting and manipulating bone marrow and cord blood in native conditions of hypoxia, we demonstrate that brief exposure to ambient oxygen decreases recovery of long-term repopulating HSCs and increases progenitor cells, a phenomenon we term extraphysiologic oxygen shock/stress (EPHOSS). Thus, true numbers of HSCs in the bone marrow and cord blood are routinely underestimated. We linked ROS production and induction of the mitochondrial permeability transition pore (MPTP) via cyclophilin D and p53 as mechanisms of EPHOSS. The MPTP inhibitor cyclosporin A protects mouse bone marrow and human cord blood HSCs from EPHOSS during collection in air, resulting in increased recovery of transplantable HSCs. Mitigating EPHOSS during cell collection and processing by pharmacological means may be clinically advantageous for transplantation.

Differential Stem and Progenitor Cell Trafficking by Prostaglandin E2

To maintain lifelong production of blood cells, haematopoietic stem cells (HSCs) are tightly regulated by inherent programs and extrinsic regulatory signals received from their microenvironmental niche. Long-term repopulating HSCs reside in several, perhaps overlapping, niches that produce regulatory molecules and signals necessary for homeostasis and for increased output after stress or injury. Despite considerable advances in the specific cellular or molecular mechanisms governing HSC–niche interactions, little is known about the regulatory function in the intact mammalian haematopoietic niche. Recently, we and others described a positive regulatory role for prostaglandin E2 (PGE2) on HSC function ex vivo. Here we show that inhibition of endogenous PGE2 by non-steroidal anti-inflammatory drug (NSAID) treatment in mice results in modest HSC egress from the bone marrow. Surprisingly, this was independent of the SDF-1–CXCR4 axis implicated in stem-cell migration. Stem and progenitor cells were found to have differing mechanisms of egress, with HSC transit to the periphery dependent on niche attenuation and reduction in the retentive molecule osteopontin. Haematopoietic grafts mobilized with NSAIDs had superior repopulating ability and long-term engraftment. Treatment of non-human primates and healthy human volunteers confirmed NSAID-mediated egress in other species. PGE2 receptor knockout mice demonstrated that progenitor expansion and stem/progenitor egress resulted from reduced E-prostanoid 4 (EP4) receptor signalling. These results not only uncover unique regulatory roles for EP4 signalling in HSC retention in the niche, but also define a rapidly translatable strategy to enhance transplantation therapeutically.

Osteoblast lineage cells expressing high levels of Runx2 enhance hematopoietic progenitor cell proliferation and function

Although osteoblasts (OB) play a key role in the hematopoietic stem cell (HSC) niche, little is known as to which specific OB lineage cells are critical for the enhancement of stem and progenitor cell function. Unlike hematopoietic cells, OB cell surface phenotypic definitions are not well developed. Therefore, to determine which OB lineage cells are most important for hematopoietic progenitor cell (HPC) function, we characterized OB differentiation by gene expression and OB function, and determined whether associations existed between OB and HPC properties. OB were harvested from murine calvariae, used immediately (fresh OB) or cultured for 1, 2, or 3 weeks prior to their co‐culture with Lin−Sca1+c‐kit+ (LSK) cells for 1 week. OB gene expression, alkaline phosphatase activity, calcium deposition, hematopoietic cell number fold increase, CFU fold increase, and fold increase of Lin−Sca1+ cells were determined. As expected, HPC properties were enhanced when LSK cells were cultured with OB compared to being cultured alone. Initial alkaline phosphatase and calcium deposition levels were significantly and inversely associated with an increase in the number of LSK progeny. Final calcium deposition levels and OB culture duration were inversely associated with all HPC parameters, while Runx2 levels were positively associated with all HPC properties. Since calcium deposition is associated with OB maturation and high levels of Runx2 are associated with less mature OB lineage cells, these results suggest that less mature OB better promote HPC proliferation and function than do more mature OB. J. Cell. Biochem. 111: 284–294, 2010.

The Changing Balance Between Osteoblastogenesis and Adipogenesis in Aging and its Impact on Hematopoiesis

Osteoblasts (OBs) and adipocytes (APs) share a common mesenchymal ancestor. It is now clear that mesenchymal stem cell (MSC) maturation along the OB lineage comes at the expense of adipogenesis and vice versa. During aging, this balance increasingly favors the formation of APs. Hematopoiesis also slowly declines during the aging process. The role of OB lineage cells in hematopoiesis has been studied, but less is known about how APs regulate hematopoiesis. A few studies have demonstrated a negative relationship between APs and hematopoiesis; however, there is also evidence that brown adipose tissue (BAT) may promote hematopoiesis. This review will examine the current knowledge of how adipogenesis and osteogenesis change with aging and the implications of this changing environment on hematopoeisis.

Hierarchical organization of osteoblasts reveals the significant role of CD166 in hematopoietic stem cell maintenance and function.

The role of osteoblasts (OB) in maintaining hematopoietic stem cells (HSC) in their niche is well elucidated, but the exact definition, both phenotypically and hierarchically of OB responsible for these functions is not clearly known. We previously demonstrated that OB maturational status influences HSC function whereby immature OB with high Runx2 expression promote hematopoietic expansion. Here, we show that Activated Leukocyte Cell Adhesion Molecule (ALCAM) or CD166 expression on OB is directly correlated with Runx2 expression and high hematopoiesis enhancing activity (HEA). Fractionation of OB with lineage markers: Sca1, osteopontin (OPN), CD166, CD44, and CD90 revealed that Lin-Sca1-OPN+CD166+ cells (CD166+) and their subpopulations fractionated with CD44 and CD90 expressed high levels of Runx2 and low levels of osteocalcin (OC) demonstrating the relatively immature status of these cells. Conversely, the majority of the Lin-Sca1-OPN+CD166- cells (CD166-) expressed high OC levels suggesting that CD166- OB are more mature. In vitro hematopoietic potential of LSK cells co-cultured for 7days with fresh OB or OB pre-cultured for 1, 2, or 3 weeks declined precipitously with increasing culture duration concomitant with loss of CD166 expression. Importantly, LSK cells co-cultured with CD166+CD44+CD90+ OB maintained their in vivo repopulating potential through primary and secondary transplantation, suggesting that robust HEA activity is best mediated by immature CD166+ OB with high Runx2 and low OC expression. These studies begin to define the hierarchical organization of osteoblastic cells and provide a more refined definition of OB that can mediate HEA.

Impact of maturational status on the ability of osteoblasts to enhance the hematopoietic function of stem and progenitor cells.

Osteoblasts (OBs) exert a prominent regulatory effect on hematopoietic stem cells (HSCs). We evaluated the difference in hematopoietic expansion and function in response to co‐culture with OBs at various stages of development. Murine calvarial OBs were seeded directly (fresh) or cultured for 1, 2, or 3 weeks prior to seeding with 1000 Lin‐Sca1 + cKit+ (LSK) cells for 1 week. Significant increases in the following hematopoietic parameters were detected when comparing co‐cultures of fresh OBs to co‐cultures containing OBs cultured for 1, 2, or 3 weeks: total hematopoietic cell number (up to a 3.4‐fold increase), total colony forming unit (CFU) number in LSK progeny (up to an 18.1‐fold increase), and percentage of Lin‐Sca1+ cells (up to a 31.8‐fold increase). Importantly, these studies were corroborated by in vivo reconstitution studies in which LSK cells maintained in fresh OB co‐cultures supported a significantly higher level of chimerism than cells maintained in co‐cultures containing 3‐week OBs. Characterization of OBs cultured for 1, 2, or 3 weeks with real‐time PCR and functional mineralization assays showed that OB maturation increased with culture duration but was not affected by the presence of LSK cells in culture. Linear regression analyses of multiple parameters measured in these studies show that fresh, most likely more immature OBs better promote hematopoietic expansion and function than cultured, presumably more mature OBs and suggest that the hematopoiesis‐enhancing activity is mediated by cells present in fresh OB cultures de novo.

Pyk2 regulates megakaryocyte-induced increases in osteoblast number and bone formation

Preclinical and clinical evidence from megakaryocyte (MK)‐related diseases suggests that MKs play a significant role in maintaining bone homeostasis. Findings from our laboratories reveal that MKs significantly increase osteoblast (OB) number through direct MK‐OB contact and the activation of integrins. We, therefore, examined the role of Pyk2, a tyrosine kinase known to be regulated downstream of integrins, in the MK‐mediated enhancement of OBs. When OBs were co‐cultured with MKs, total Pyk2 levels in OBs were significantly enhanced primarily because of increased Pyk2 gene transcription. Additionally, p53 and Mdm2 were both decreased in OBs upon MK stimulation, which would be permissive of cell cycle entry. We then demonstrated that OB number was markedly reduced when Pyk2−/− OBs, as opposed to wild‐type (WT) OBs, were co‐cultured with MKs. We also determined that MKs inhibit OB differentiation in the presence and absence of Pyk2 expression. Finally, given that MK‐replete spleen cells from GATA‐1–deficient mice can robustly stimulate OB proliferation and bone formation in WT mice, we adoptively transferred spleen cells from these mice into Pyk2−/− recipient mice. Importantly, GATA‐1–deficient spleen cells failed to stimulate an increase in bone formation in Pyk2−/− mice, suggesting in vivo the important role of Pyk2 in the MK‐induced increase in bone volume. Further understanding of the signaling pathways involved in the MK‐mediated enhancement of OB number and bone formation will facilitate the development of novel anabolic therapies to treat bone loss diseases.

Nonmarrow hematopoiesis occurs in a hyaluronic-acid-rich node and duct system in mice.

A hyaluronic-acid-rich node and duct system (HAR-NDS) was found on the surface of internal organs of mice, and inside their blood and lymph vessels. The nodes (HAR-Ns) were filled with immune cells of the innate system and were especially enriched with mast cells and histiocytes. They also contained hematopoietic progenitor cells (HPCs), such as granulocyte-macrophage, erythroid, multipotential progenitors, and mast cell progenitors (MCPs). MCPs were the most abundant among the HPCs in HAR-Ns. Their frequency was fivefold higher than that of the MCPs in bone marrow. In addition, the system contained pluripotent stem cells (PSCs) capable of producing CD45(-)Flk1(+) hemangioblast-like cells, which subsequently generated various types of HPCs and differentiated blood cells. Although HAR-Ns did not appear to harbor enough number of cells capable of long-term reconstitution or short-term radioprotection of lethally irradiated recipients, bone marrow cells were able to engraft in the HAR-NDS and reconstitute hematopoietic potentials of the system. PSCs and HPCs were consistently found in intravenous, intralymphatic, and intestinal HAR-ND. We infer that PSCs and HPCs reside in the HAR-ND and that this novel system may serve as an alternative means to traffic immature and mature blood cells throughout the body.