Reginald Donovan Smith

Globin gene expression in correlation with G protein-related genes during erythroid differentiation

BackgroundThe guanine nucleotide binding protein (G protein)-coupled receptors (GPCRs) regulate cell growth, proliferation and differentiation. G proteins are also implicated in erythroid differentiation, and some of them are expressed principally in hematopoietic cells. GPCRs-linked NO/cGMP and p38 MAPK signaling pathways already demonstrated potency for globin gene stimulation. By analyzing erythroid progenitors, derived from hematopoietic cells through in vitro ontogeny, our study intends to determine early markers and signaling pathways of globin gene regulation and their relation to GPCR expression.ResultsHuman hematopoietic CD34+ progenitors are isolated from fetal liver (FL), cord blood (CB), adult bone marrow (BM), peripheral blood (PB) and G-CSF stimulated mobilized PB (mPB), and then differentiated in vitro into erythroid progenitors. We find that growth capacity is most abundant in FL- and CB-derived erythroid cells. The erythroid progenitor cells are sorted as 100% CD71+, but we did not find statistical significance in the variations of CD34, CD36 and GlyA antigens and that confirms similarity in maturation of studied ontogenic periods. During ontogeny, beta-globin gene expression reaches maximum levels in cells of adult blood origin (176 fmol/μg), while gamma-globin gene expression is consistently up-regulated in CB-derived cells (60 fmol/μg). During gamma-globin induction by hydroxycarbamide, we identify stimulated GPCRs (PTGDR, PTGER1) and GPCRs-coupled genes known to be activated via the cAMP/PKA (ADIPOQ), MAPK pathway (JUN) and NO/cGMP (PRPF18) signaling pathways. During ontogeny, GPR45 and ARRDC1 genes have the most prominent expression in FL-derived erythroid progenitor cells, GNL3 and GRP65 genes in CB-derived cells (high gamma-globin gene expression), GPR110 and GNG10 in BM-derived cells, GPR89C and GPR172A in PB-derived cells, and GPR44 and GNAQ genes in mPB-derived cells (high beta-globin gene expression).ConclusionsThese results demonstrate the concomitant activity of GPCR-coupled genes and related signaling pathways during erythropoietic stimulation of globin genes. In accordance with previous reports, the stimulation of GPCRs supports the postulated connection between cAMP/PKA and NO/cGMP pathways in activation of γ-globin expression, via JUN and p38 MAPK signaling.

Stimulated stromal cells induce γ-globin gene expression in erythroid cells via nitric oxide production

OBJECTIVE We have previously shown that nitric oxide (NO) is involved in the hydroxyurea-induced increase of gamma-globin gene expression in cultured human erythroid progenitor cells and that hydroxyurea increases NO production in endothelial cells via endothelial NO synthase (NOS). We have now expanded those studies to demonstrate that stimulation of gamma-globin gene expression is also mediated by NOS induction in stromal cells within the bone marrow microenvironment. MATERIALS AND METHODS Using NO analyzer, we measured NO production in endothelial and macrophage cell cultures. In coculture studies of erythroid and stromal cells, we measured globin gene expression during stimulation by NO inducers. RESULTS Hydroxyurea (30-100 microM) induced NOS-dependent production of NO in human macrophages (up to 1.2 microM). Coculture studies of human macrophages with erythroid progenitor cells also resulted in induction of gamma-globin mRNA expression (up to threefold) in the presence of hydroxyurea. NOS-dependent stimulation of NO by lipopolysaccharide (up to 0.6 microM) has been observed in human macrophages. We found that lipopolysaccharide and interferon-gamma together increased gamma-globin gene expression (up to twofold) in human macrophage/erythroid cell cocultures. Coculture of human bone marrow endothelial cells with erythroid progenitor cells also induced gamma-globin mRNA expression (2.4-fold) in the presence of hydroxyurea (40 microM). CONCLUSION These results demonstrate an arrangement by which NO and fetal hemoglobin inducers may stimulate globin genes in erythroid cells via the common paracrine effect of bone marrow stromal cells.

Pilot study assessing the impact of platelet activation electric stimulation protocols on hematopoietic and mesenchymal stem cell proliferation

Recent research has shown that pulsed electric fields can successfully activate platelets ex-vivo; activation means here the release of growth factors and clotting. Typically, platelets are in a complex biological matrix, such as platelet rich plasma (PRP), which contains a variety of cell types. While specific electric pulses can activate the platelets, the impact of electric simulation on other cell types is an open question. The pilot study presented here focuses on evaluating electric pulse effects on hematopoietic and mesenchymal stem cells when they are in a complex biological matrix also containing platelets. Experimental results indicate that stem cell proliferation at two weeks post treatment can be tuned as a function of electrical parameters. We demonstrate in this pilot study that stem cell proliferation can be either low (via conductive coupling, 8.5 kV/cm electric field amplitude) or high (via capacitive coupling, 2.5 kV/cm electric field amplitude) two weeks after stimulation, despite these two electric pulse delivery mechanisms inducing roughly similar growth factor release and immediate cell viability post treatment. These observations may open up additional ways of tuning electric pulse delivery for platelet activation and other biomedical applications.