Chemokines as inhibitors of hematopoietic progenitors

Simulated microgravity affects stroma-dependent ex vivo myelopoiesis

Microgravity is known negatively affect physiology of living beings, including hematopoiesis. Dysregulation of hematopoietic cells and supporting stroma relationships in bone marrow niche may be in charge. We compared the efficacy of ex vivo expansion of hematopoietic stem and progenitor cells (HSPCs) in presence of native or osteocommitted MSCs under simulated microgravity (Smg) using Random Positioning Machine (RPM). In comparison with 1 g, a decrease of MSC-associated HSPCs and an increase of floating HSPCs was observed after 7 days of Smg exposure. Among floating HSPCs, primitive progenitors were presented by late CD34⁺/133^-. Total CFUs as well as erythroid (BFU-E) and granulocytic (CFU-G) numbers were lower. MSC-associated primitive HSPCs demonstrated increased proportion of late CD34⁺/133^- in expense of early CD34^-/133⁺. Osteo-MSCs preferentially supported late primitive CD34⁺ and more committed HSPCs as followed from increase of CFUs, and CD235a⁺ erythroid progenitors. Under Smg, an increased VEGF, eotaxin, and GRO-a levels, and a decrease in RANTES were found in the osteo-MSC-HSPC co-cultures. IL-6,-8, -13, G-CSF, GRO-a, MCP-3, MIP-1b, VEGF increased in co-culture with osteo-MSCs vs intact MSCs. Based on the findings, the misbalance between primitive/committed HSPCs and a decrease in hematopoiesis-supportive activity of osteocommitted cells are supposed to underline hematopoietic disorders during space flights.

Bone Marrow Clonogenic Capability, Cytokine Production, and Thymic Output in Patients with Common Variable Immunodeficiency

In patients with primary Ab deficiencies, hematological and immunological abnormalities are frequently observed. A regenerative failure of hemopoietic stem/progenitor cells has been hypothesized. We evaluated in the bone marrow (BM) of 11 patients with common variable immunodeficiency, the phenotype of BM progenitors and their in vitro growth by colony-forming cell (CFC) and long-term culture (LTC) assays. A significant decrease in erythroid and mixed CFC and, to a greater extent, in primitive LTC-CFC progenitors was observed in patients compared with healthy controls. The frequency of BM pre-B and pro-B cells correlated directly with the absolute number of CD19+ lymphocytes. BM cells cultured in vitro produced spontaneously lower amounts of IL-2 and elevated levels of TNF-alpha compared with controls, indicating a skewing toward a proapoptotic cytokine pattern. In addition, stromal cells generated after BM LTC secreted less IL-7 and displayed by immunohistochemistry an altered phenotype. These findings were associated with a significant decrease in naive Th cells coexpressing CD31 in the peripheral blood. These results indicate an impaired growth and differentiation capacity of progenitor cells in patients with common variable immunodeficiency.

Improvement of interleukin 2 production, clonogenic capability and restoration of stromal cell function in human immunodeficiency virus-type-1 patients after highly active antiretroviral therapy

Haematological abnormalities frequently occur in patients infected by human immunodeficiency virus-type 1 (HIV-1). Increasing evidence indicates that bone marrow suppression (BM) results from viral infection of accessory cells, with impaired stromal function and alteration of haematopoietic growth factor network. We have investigated the effects of antiretroviral therapy on cytokine and chemokine production by BM cells and stromal cells in a group of HIV-1-infected subjects before and during treatment. Compared with uninfected controls, an altered cytokine and chemokine production by BM cells was observed before treatment, characterized by decreased interleukin 2 (IL-2) and elevated tumour necrosis factor-alpha, macrophage inflammatory protein (MIP)-1alpha, MIP-1beta, and RANTES (regulated on activation, normal T cell-expressed and secreted) levels, along with a defective BM clonogenic activity. Antiretroviral therapy showed increased BM clonogenic capability, associated with normalization of IL-2 production and chemokine receptors expression on CD34+ cells. Pre-therapy, BM accessory cells were represented by macrophage-like cells, in some cases positive for HIV-1 DNA, suggesting that these cells are the main target of HIV-1 infection. During therapy, the stromal cells became predominantly fibroblastoid-like, as observed in normal controls, and were negative for HIV-1 DNA. Controlling HIV-1 replication may produce amelioration of stem cell activity, and restoration of stromal cell pattern and functions, with increased IL-2 production at BM level.

Limitin: An interferon-like cytokine that preferentially influences B-lymphocyte precursors

We have identified an interferon-like cytokine, limitin, on the basis of its ability to arrest the growth of or kill lympho-hematopoietic cells. Limitin strongly inhibited B lymphopoiesis in vitro and in vivo but had little influence on either myelopoiesis or erythropoiesis. Because limitin uses the interferon alpha/beta receptors and induces interferon regulatory factor-1, it may represent a previously unknown type I interferon prototype. However, preferential B-lineage growth inhibition and activation of Janus kinase 2 in a myelomonocytic leukemia line have not been described for previously known interferons.

Novel chicken CXC and CC chemokines

Upon stimulation with lipopolysaccharide (LPS) the chicken macrophage cell line HD-11 secretes factors with cytokine activity. To characterize these molecules, representational difference analysis with RNA of LPS-induced and uninduced HD-11 cells was performed. Two cDNA clones were isolated that code for polypeptides with structural features of chemokines. cDNA K60 codes for a novel CXC chemokine of 104 residues including a putative signal peptide of 20 amino acids at the N-terminus. It is 67% identical to the previously cloned chicken chemokine 9E3/CEF4. K60 exhibits a similar degree of sequence identity to human interleukin 8 and other related CXC chemokines (about 50%), rendering straight-forward predictions of its biological properties difficult. cDNA K203 codes for a novel CC chemokine of 89 amino acids including a putative N-terminal signal peptide of 21 residues. It is 43% identical to a previously characterized chicken protein with homology to mammalian macrophage inflammatory protein 1beta (MIP-1beta). K203 exhibits about 50% sequence identity to human MIP-1beta and other related CC chemokines.

WECHE: a novel hematopoietic regulatory factor

Previously, we described AGM-derived endothelial cell lines that either inhibited or permitted the development of erythroid or B cells. We utilized a differential gene expression method to isolate a chemokine, termed WECHE, from one of these cell lines. WECHE inhibited the formation of erythroid cells but had no effect on either myeloid or B cell formation. WECHE repressed BFU-E development from either mouse fetal liver or bone marrow progenitor cells but had no effect on colony formation induced by IL-3 or IL-7. WECHE reduced HPP-CFC production from fetal liver-derived stem cells. WECHE hindered the growth of yolk sac-derived endothelial cells. WECHE was also chemotactic for bone marrow cells. Thus, WECHE is a novel chemokine that regulates hematopoietic differentiation.

Enhanced Myeloid Progenitor Cell Cycling and Apoptosis in Mice Lacking the Chemokine Receptor, CCR2

Chemokines regulate hematopoiesis in part by influencing the proliferative status of myeloid progenitor cells (MPC). Human MCP-1/murine JE, a myelosuppressive chemokine, specifically binds C-C chemokine receptor 2 (CCR2). Transgenic mice containing a targeted disruption in CCR2 that prevents expression of CCR2 mRNA and protein and have MPC that are insensitive to inhibition by MCP-1 and JE in vitro were assessed for potential abnormalities in growth of bone marrow (BM) and spleen MPC. MPC in both unseparated and c-kit+lin− populations of BM from CCR2-deficient (−/−) mice were in a greatly increased proliferation state compared with CCR2 littermate control (+/+) mice, an effect not apparent with progenitors from spleens of CCR2 (−/−) mice. Increased cycling status of CCR2 (−/−) BM MPC did not result in increased numbers of nucleated cells or MPC in BM or spleens of CCR2 (−/−) mice. Possible reasons for this apparent discrepancy were highlighted by flow cytometric analysis of c-kit+lin− BM cells and colony formation by MPC subjected to delayed addition of growth factors. The c-kit+lin− population of BM cells from CCR2 (−/−) mice had a significantly higher percentage of apoptotic cells than those from CCR2 (+/+) BM. However, elevated apoptosis was not associated with decreased numbers of c-kit+lin− cells. The increased percentage of apoptotic c-kit+lin− cells was due to elevated apoptosis within the c-kitdimlin−, but not the c-kitbrightlin−, subpopulations of cells. Consistent with enhanced apoptosis of phenotypically defined cells, MPC from CCR2 (−/−) BM and purified c-kit+lin− cells demonstrated decreased cell survival in vitro upon delayed addition of growth factors. The data suggest that signals received by CCR2 limit proliferation of progenitor cells in the BM, but also enhance survival of these cells.

Enhanced Myeloid Progenitor Cell Cycling and Apoptosis in Mice Lacking the Chemokine Receptor, CCR2

Chemokines regulate hematopoiesis in part by influencing the proliferative status of myeloid progenitor cells (MPC). Human MCP-1/murine JE, a myelosuppressive chemokine, specifically binds C-C chemokine receptor 2 (CCR2). Transgenic mice containing a targeted disruption in CCR2 that prevents expression of CCR2 mRNA and protein and have MPC that are insensitive to inhibition by MCP-1 and JE in vitro were assessed for potential abnormalities in growth of bone marrow (BM) and spleen MPC. MPC in both unseparated and c-kit+lin− populations of BM from CCR2-deficient (−/−) mice were in a greatly increased proliferation state compared with CCR2 littermate control (+/+) mice, an effect not apparent with progenitors from spleens of CCR2 (−/−) mice. Increased cycling status of CCR2 (−/−) BM MPC did not result in increased numbers of nucleated cells or MPC in BM or spleens of CCR2 (−/−) mice. Possible reasons for this apparent discrepancy were highlighted by flow cytometric analysis of c-kit+lin− BM cells and colony formation by MPC subjected to delayed addition of growth factors. The c-kit+lin− population of BM cells from CCR2 (−/−) mice had a significantly higher percentage of apoptotic cells than those from CCR2 (+/+) BM. However, elevated apoptosis was not associated with decreased numbers of c-kit+lin− cells. The increased percentage of apoptotic c-kit+lin− cells was due to elevated apoptosis within the c-kitdimlin−, but not the c-kitbrightlin−, subpopulations of cells. Consistent with enhanced apoptosis of phenotypically defined cells, MPC from CCR2 (−/−) BM and purified c-kit+lin− cells demonstrated decreased cell survival in vitro upon delayed addition of growth factors. The data suggest that signals received by CCR2 limit proliferation of progenitor cells in the BM, but also enhance survival of these cells.

Current understanding of chemokine involvement in allograft transplantation

Multiple studies have demonstrated that chemokines play an essential role in regulating and co-ordinating the infiltration of leucocytes into allografts. Chemokines are expressed in skin, liver, heart, and kidney allografts following initial engraftment, ischemic injury, viral infection, and acute and chronic rejection. To date, most of our understanding of chemokine biology has been generated from studies of animal models of transplantation and little is known about the role of chemokines in human allograft rejection. Chemokines may play important mechanistic roles in transplant rejection, in the development of graft arteriosclerosis, and in chronic sclerosing cholangiopathy. Furthermore, these molecules may serve as sensitive diagnostic indicators for the analysis of rejection, including chronic rejection or other forms of graft dysfunction. Lastly, it is possible that chemokine-targeted therapy might become a feasible option for the treatment of allograft rejection.

Chemokines and leukocyte traffic

Over the past ten years, numerous chemokines have been identified as attractants of different types of blood leukocytes to sites of infection and inflammation. They are produced locally in the tissues and act on leukocytes through selective receptors. Chemokines are now known to also function as regulatory molecules in leukocyte maturation, traffic and homing of lymphocytes, and the development of lymphoid tissues.