Vascular smooth muscle differentiation of murine stroma: a sequential model.

Previous studies by our group showed that stromal cells from human long-term marrow cultures were mesenchymal cells following a vascular smooth muscle pathway. The present study using 58 immortalized stromal lines from different hematopoietic sites was conducted to verify whether this hypothesis also held true for murine stroma. Principal components analysis performed using cytoskeletal and extracellular matrix proteins allowed the segregation of five factors explaining more than 70% of the variance. Factor I, including osteopontin and vimentin, and factor II, laminins and fibronectins, were representative of the mesenchyme. The remaining three factors were representative of vascular smooth muscle: factor III, including alphaSM actin, SM alpha actinin, SM22alpha, EDa+ fibronectin, and thrombospondin-1; factor IV, metavinculin and h-caldesmon; and factor V, smooth muscle myosin SM1 and desmin. All lines expressed factors I and II; 53 lines expressed factor III, 35 lines expressed factor IV; and 11 lines expressed factor V. A second principal components analysis including membrane antigens indicated the cosegregration of vascular cell adhesion molecule-1 with osteopontin and that of Ly6A/E with vimentin, whereas CD34 and Thy-1 appeared to be independent factors. The heterogeneity of vascular smooth muscle markers expression suggests that harmonious maintenance of hematopoiesis depends on the cooperation between different stromal cell clones.

Retrovirus-mediated gene transfer into human CD34+38low primitive cells capable of reconstituting long-term cultures in vitro and nonobese diabetic-severe combined immunodeficiency mice in vivo.

Factors that may improve retroviral transduction of primitive human hematopoietic cells were studied using MFG-based vectors containing a LacZ gene and produced either by a murine (psi-Crip) or a human (Tasaf) cell line. Cord blood (CB) or bone marrow (BM) CD34+ cells were stimulated and transduced in the presence of three cytokines (interleukin 3 [IL-3], IL-6, and stem cell factor [SCF; c-Kit Ligand]). In the supernatant infection protocol, hematopoietic progenitor cells as measured by X-Gal staining of colony-forming unit cells (CFU-Cs) were transduced more effectively with Tasaf (20%) than with psi-Crip (8%). In contrast, there was no difference between these two cell lines in a coculture protocol. However, gene transfer into more primitive CD34+CD38- subsets and in LTC-IC-derived colonies was low. The use of a large number of cytokines including FLT3-L and PEG-rhMGDF increased the transduction efficiency into CD34+CD38(-)-derived CFU-Cs (35% by PCR) or LTC-ICs (10%). A virus pseudotyped with gibbon ape leukemia virus (GALV) envelope further improved gene transfer to 60 and 48% for LacZ+ CFU-C- and LTC-IC-derived colonies, respectively. These conditions of transduction allowed multilineage engraftment of primitive cord blood cells in NOD-SCID mice. Moreover, 10% (at least) of the human hematopoietic cells recovered from the marrow of these immunodeficient animals were transduced. These data suggest that the efficiency of transduction of human hematopoietic primitive cells can be significantly improved by judicious combinations of recombinant cytokines and high retroviral titers.

Loss of primitive hematopoietic progenitors in patients with human immunodeficiency virus infection.

A number of hematologic abnormalities, including cytopenias, have been observed in patients with human immunodeficiency virus (HIV) infection. To elucidate their mechanisms, primitive cells from bone marrow aspirates of 21 patients with HIV-1 infection were quantitated by flow cytometry. The mean percentage of CD34+ cells is not significantly altered in HIV-1-infected patients in comparison with HIV-1-seronegative controls. In contrast, two- and three-color immunofluorescence analysis showed that in all HIV-1 samples, most CD34+ cells coexpressed the CD38 antigen. The proportion of HIV-1-derived CD34+ cells that did not express the CD38 antigen was significantly lower (HIV-1+: mean, 1.73%; controls: mean, 14%; P < .0005) than in controls. Moreover, of Thy-1+ cells, the proportion of CD34+ cells was twofold lower in HIV-1-infected patients (HIV-1+: mean, 12%; controls, 25%, P < .0005), which suggests that phenotypically primitive cells are depleted in HIV-1 infection. In vitro functional analysis in long-term cultures of sorted CD34+ cells from seven HIV-1 patients showed that CD34+ cells from HIV-1 patients generated much fewer colonies both in the nonadherent and adherent layers than CD34+ cells from controls after 5 weeks of culture (10-fold and four-fold less, respectively). Precise long-term culture initiating cell (LTC-IC) frequency in the CD34+ cell population was determined in three patients by limiting dilution and was markedly decreased in comparison to that of normal controls (from twofold to > sevenfold decreased). To determine if primitive cells were infected by HIV-1, both methylcellulose colonies generated from long-term culture of CD34+ cells and various CD34+ cell fractions purified by flow cytometry were evaluated for the presence of HIV-1 by polymerase chain reaction (PCR). Progeny from long-term culture was HIV-1-negative in three samples. In addition, using a sensitive PCR technique, the HIV-1 genome could not be detected in CD34+, CD34+/CD38-, and CD34+/CD4+ cells. These data show that hematologic disorders in HIV disease may be the consequence of a deficit of primitive cells. However, direct infection of these cells by HIV-1 does not seem to be responsible for this defect.

In vitro infection of bone marrow-adherent cells by human immunodeficiency virus type 1 (HIV-1) does not alter their ability to support hematopoiesis.

As an attempt to elucidate the pathogenesis of human immunodeficiency virus type 1 (HIV-1)-related cytopenia, the effects of infection of long-term primary bone marrow culture (LTBMC)-derived adherent cells on hematopoiesis were investigated. Productive infection could then be established only when using monocytotropic strains HIV-1Ba-L, HIV-1Ada, and HIV-1JR-FL but not with lymphocytotropic strain HIV-1LAI. Culture supernatants were tested for major cytokines involved in the regulation of hematopoiesis: neither IL-3 nor GM-CSF were detectable in the infected or noninfected cultures; in contrast, TGF-beta, TNF-alpha, MIP-1 alpha, Steel Factor, and IL-6 were detected at all times in established LTBMCs, but their levels were not consistently altered by virus replication. In vitro functional analysis by colony and long-term culture assays showed that HIV-1 infection failed to alter either the kinetics or the number of hematopoietic progenitors produced by the stromal layers; it did not interfere with the clonogenicity of exogeneous CD34+ cells in semisolid assays, and no difference was observed relative to the controls when HIV-1-infected stromal layers were tested for their ability to sustain long-term hematopoiesis. These results show that productive and sustained virus replication in the macrophage component of LTBMCs does not significantly alter the profile of major cytokines involved in regulating hematopoiesis, nor is it sufficient by itself for altering in vitro hematopoiesis under the baseline conditions used.

Susceptibility of human bone marrow stromal cells to human immunodeficiency virus (HIV).

It is not known whether impaired hematopoiesis noted during human immunodeficiency virus (HIV) infection results from infection of stem/progenitor cells or of cells of the bone marrow microenvironment. Normal adherent primary stromal layers were exposed to HIV to determine which of this mixture of endothelial cells, fibroblasts, and macrophages are susceptible to the virus. Viral p24 in supernatants was noted with monocytotropic HIV-1Ada, HIV-1Ba-L, and HIV-1JR-FL but not with lymphotropic HIV-1LAI nor HIV-1MN strain, and only stromal macrophages expressed the viral antigens. Coculture of the layers with PHA-activated normal lymphocytes failed to rescue lymphotropic virus. No p24 was produced when macrophage-depleted stromal cells were exposed to either HIV-1Ba-L or HIV-1LAI; proviral DNA was then amplified by PCR in cells exposed to either virus, though coculture with lymphocytes rescued only HIV-1Ba-L. Altogether, these data indicate that macrophages are the major targets of HIV in cultured stromal layers. As virus replication in macrophages did not affect the profile of major cytokines involved in regulating hematopoiesis, HIV infection could alter hematopoiesis by other as yet unspecified mechanisms.

Expression of CD4 by human hematopoietic progenitors.

It has been recently reported that murine hematopoietic stem cells and progenitors express low levels of CD4. In this study, we have investigated by phenotypic and functional analysis whether the CD4 molecule was also present on human hematopoietic progenitors. Unfractionated marrow cells or immunomagnetic bead-purified CD34+ cells were analyzed by two-color fluorescence with an anti-CD4 and an anti-CD34 monoclonal antibody (MoAb). A large fraction (25% to 50%) of the CD34+ cells was weakly stained by anti-CD4 antibodies. Moreover, in further experiments analyzing the expression of CD4 in different subpopulations of CD34+ cells, we found that CD4 was predominantly expressed in phenotypically primitive cells (CD34+ CD38-/low CD71low Thy-1high, HLA-DR+/low). However, the presence of CD4 was not restricted to these primitive CD34+ cell subsets and was also detected in a smaller fraction of more mature CD34+ cells exhibiting differentiation markers. Among those, subsets with myelo-monocytic markers (CD13, CD33, CD14, and CD11b) have a higher CD4 expression than the erythroid or megakaryocytic subsets. In vitro functional analysis of the sorted CD34+ subsets in colony assays and long-term culture-initiating cell (LTC-IC) assays confirmed that clonogenic progenitors (colony-forming unit-granulocyte-macrophage, burst-forming unit-erythroid, and colony-forming unit-megakaryocyte) and LTC-IC were present in the CD4low population. However, most clonogenic progenitors were recovered in the CD4- subset, whereas the CD4low fraction was greatly enriched in LTC-IC. In addition, CD4low LTC-IC generated larger numbers of primitive clonogenic progenitors than did CD4- LTC-IC. These observations suggest that, in the progenitor compartment, the CD4 molecule is predominantly expressed on very early cells. The CD4 molecule present on CD34+ cells appeared identical to the T-cell molecule because it was recognized by three MoAbs recognizing different epitopes of the molecule. Furthermore, this CD4 molecule is also functional because the CD34+ CD4low cells are able to bind the human immunodeficiency virus (HIV) gp120. This observation might be relevant to the understanding of the mechanisms of HIV-induced cytopenias.