Analysis of lymphocytes, monocytes, and neutrophils from human immunodeficiency virus (HIV)-infected persons for HIV DNA

The human immunodeficiency virus (HIV) infects and depletes or alters the function of cells involved in immune responsiveness. While both T helper lymphocytes and monocyte/macrophages can be infected via cell-surface CD4 in vitro, previous studies showed that few blood cells express HIV RNA in vivo. This study used DNA amplification to determine the levels of HIV DNA in purified lymphocytes, monocytes, and neutrophils from HIV-infected asymptomatic individuals and persons with AIDS. The average numbers of HIV DNA copies in lymphocytes from AIDS patients and asymptomatic individuals were similar (approximately 100-140 copies/150,000 cells). However, when expressed on the basis of numbers of CD4+ T cells, AIDS patients' cells contained approximately 2.5 times more HIV DNA. While HIV DNA was present in lymphocytes from all 27 subjects, little or no HIV DNA was observed in monocytes or neutrophils. Only 1 asymptomatic person contained levels of HIV DNA in monocytes (125 proviral copies/150,000 cells) that were comparable to levels expressed in lymphocytes (160/150,000). While expression of monocyte HIV DNA in this person was persistent over at least 8 months, it was not observed in neutrophils, suggesting that monocyte HIV DNA did not originate in myeloid precursors. This study shows that in AIDS or asymptomatic HIV infection, lymphocytes are the predominant infected cell found in blood.     

Molecular characterization of T-cell antigen receptor expression by subsets of CD4- CD8- murine thymocytes.

Precursors of all T-lineage cells are found in a population of thymocytes that lack the CD4 and CD8 surface glycoproteins. These "double-negative" thymocytes are markedly heterogeneous in their expression of other surface markers and include cells at various stages of development. In this study, CD4- CD8- adult murine thymocytes were separated into subsets based on the expression of the "heat stable antigen" (HSA) and of Ly 1 (CD5). The sorted subsets were analyzed directly (without prior expansion in culture) for T-cell antigen receptor (TcR) gene rearrangement and mRNA expression and for TcR and CD3 cell-surface protein expression. Very little surface CD3 or TcR expression was detected on the major HSA+ Ly 1low subset. However, the HSA+ Ly 1high, HSA- Ly 1high, and HSA- Ly 1low subsets all contained cells with surface expression of CD3 and TcR. In contrast to previous studies, we found no subset that exclusively expressed either the alpha beta or gamma delta heterodimer, although the ratio of alpha beta+ to gamma delta+ varied widely. Two of these three subsets (HSA- Ly 1low and HSA- Ly 1high) showed very high usage of V beta 8 gene products in the alpha beta heterodimer, but nevertheless included approximately equal to 15% non-V beta 8 alpha beta forms. All CD4- CD8- subsets were found to have extensively rearranged their TcR gamma genes and to express gamma mRNA. Expression of a high ratio of mature [1.3 kilobases (kb)] to truncated (1.0 kb) beta message and presence of alpha message was largely restricted to subsets with TcR alpha beta surface expression.     

The functional characterization of interleukin-10 receptor expression on human natural killer cells

Human natural killer (NK) cells are large granular lymphocytes that constitutively express functional forms of the interleukin-2 receptor (IL-2R) and lyse tumor and virally infected cells without prior sensitization. NK cells with high density expression of CD56 (CD56bright) express the high affinity IL-2R and proliferate in response to low (picomolar) concentrations of IL-2. CD56dim NK cells express the intermediate affinity IL-2R and demonstrate enhanced cytotoxic activity without proliferation in response to high (nanomolar) concentrations of IL-2. In the present study, we characterized IL-10R expression on human NK cells and the functional consequences of IL-10 binding directly to highly purified subsets of CD56bright and CD56dim NK cells. Binding studies using 125I-IL-10 indicated that resting human NK cells constitutively express the IL-10 receptor protein at a surface density of approximately 90 receptor sites per cell, with a kd of approximately 1 nmol/L. Alone, IL-10 did not induce proliferation of CD56bright or CD56dim NK cell subsets. However, at low concentrations (0.5 to 5 ng/mL), IL-10 significantly augmented IL-2-induced proliferation of the CD56bright NK cell subset mediated via the high-affinity IL-2R. In the absence of IL-2, IL-10 was able to induce significant NK cytotoxic activity against NK-resistant tumor cell targets in both subsets of NK cells in a dose-dependent fashion. Furthermore, the combination of IL-10 and IL-2 had an additive effect on NK cytotoxic activity, whereas that of IL-10 and IL-12 did not. Production of interferon-gamma, tumor necrosis factor-alpha, and granulocyte-macrophage colony-stimulating factor by IL-2-activated NK cells was also significantly enhanced by IL-10. Neither resting nor activated human NK cells appear to produce human IL-10 protein. In summary, NK cells constitutively express the IL-10R protein in low density, and the functional consequences of IL-10 binding directly to human NK cell subsets appear to be stimulatory and dose-dependent. In contrast to its direct effects on human T cells and monocytes/macrophages, IL-10 potentiates cytokine production by human NK cells.     

Differential expression of HLA-DR antigens in subsets of human CFU-GM

Expression of HLA-DR surface antigens by granulocyte/monocyte colony- forming cells (CFU-GM) may be important in the regulation of proliferation of these cells. Using immunological techniques to enrich for progenitor cells, we investigated the expression of HLA-DR in subsets of CFU-GM. "Early" (day 14) CFU-GM express higher levels of HLA- DR than do "late" (day 7) CFU-GM. Among late CFU-GM, cells destined to form monocyte (alpha-naphthyl acetate esterase-positive) colonies express higher levels of HLA-DR than do CFU-GM destined to form granulocyte (chloroacetate esterase-positive) colonies. Because high- level expression of DR antigen was a marker for monocyte differentiation, we examined several lymphokines for their effects on both DR expression and in vitro commitment to monocyte differentiation by myeloid precursor cells. DR antigen density could be increased by more than twofold over 48 hours upon exposure to gamma-interferon (gamma-IFN), whereas colony-stimulating factors had no effect. This was associated with a dose-dependent inhibition of total CFU-GM number, and a relative, but not absolute, increase in the ratio of monocyte colonies to granulocyte colonies. Similarly, in day 7 suspension cultures of purified myeloid precursor cells, gamma-IFN inhibited cell proliferation and increased the ratio of monocytes to granulocytes. Thus, despite the induction of high levels of HLA-DR antigen on precursor cells (a marker of monocyte commitment), the dominant in vitro effect of gamma-IFN was inhibition of granulocyte differentiation.     

CD16- CD56+ natural killer cells after bone marrow transplantation.

Natural killer (NK) cells are phenotypically defined as lymphocytes expressing the antigens CD56 and mostly CD16 (Fc gamma RIII), but lacking CD3. A small CD3- CD16- CD56+ NK cell subset has been described in normal individuals representing less than 2% of peripheral blood lymphocytes. We analyzed here 70 patients for their reconstitution of the immune system during follow-up after autologous or allogeneic bone marrow transplantation. In 35% of these patients, two different NK cell subsets, namely CD56+dim and CD56+bright cells, were observed. The mean duration of these two subsets after transplant was 4 months. Sixty-five percent of the patients exhibited an increased number of NK cells, but only the typical CD16+ CD56+dim population. The CD56+bright subpopulation represented a particular CD3- CD16- NK subset, with posttransplant frequencies up to 70% of all NK cells and 40% of peripheral blood lymphocytes, respectively. In contrast to normal CD56+dim NK cells, CD56+bright cells coexpressed the activation antigens p75 beta-chain of interleukin-2 receptor (IL-2R), CD2R, and CD26, but were negative for CD16. NK and antibody-dependent cellular cytotoxicity activity of CD56+bright cells was low compared with CD56+dim NK cells. But using IL-2 and interferon gamma, their cytotoxicity could be enhanced even more than in CD56+dim lymphocytes. These different subsets may reflect distinct activation or differentiation steps of NK cells during reconstitution of the immune system. Their differential response to IL-2 may be of functional importance for posttransplant cytokine therapy.     

Differential expression of receptors for interleukin-3 on subsets of CD34-expressing hematopoietic cells of rhesus monkeys

The target cell specificity of interleukin-3 (IL-3) was examined by flow cytometric analysis of IL-3 receptor (IL-3R) expression on rhesus monkey bone marrow (BM) cells using biotinylated IL-3. Only 2% to 5% of unfractionated cells stained specifically with the biotinylated IL-3 and most of these cells were present within the CD34+ subset. IL-3Rs were detected on small CD34dull/RhLA-DRbright/CD10+/CD27+/CD2-/++ +CD20- cells, which probably represent B-cell precursors. IL-3R+ CD34- BM cells, which were detected at low frequencies, consisted of small CD20dull/surface-IgM+/RhLA-DR+ cells. These cells represented immature B lymphocytes, whereas CD20bright mature B cells were IL-3R-. The highest IL-3R levels were detected on CD34dull/RhLA-DRbright blast-like cells. These cells differentiated into monocytes, neutrophils, and basophils after IL-3 and/or granulocyte-macrophage colony-stimulating factor (GM-CSF) stimulation in vitro. The CD34bright/IL-3R- subset contained all clonogenic erythroid and myeloid progenitors (burst- forming unit-erythroid and colony-forming unit-culture), whereas CD34bright/IL-3Rdull cells differentiated into monocytes, neutrophils, and erythroid cells after shorter culture periods. This finding showed that IL-3R expression increases during monocyte and granulocyte differentiation. Results of three-color experiments indicated that IL- 3Rs are expressed on CD34bright/RhLA-DRbright cells as well as on CD34bright/RhLA-DRdull cells, with the latter population expression approximately twofold to threefold lower IL-3R levels. A large fraction (> 30%) of single-cell/well-sorted CD34bright/RhLA-DRdull cells formed multilineage colonies after 2 to 4 weeks of stimulation with IL-3, GM- CSF, Kit ligand, and IL-6. Individual colonies contained cells that still expressed CD34 as well as differentiated monocytes, granulocytes, and erythroid cells. These results confirmed that the CD34bright/RhLA- DRdull subset was enriched for immature, multipotent progenitor cells, whereas the CD34bright/RhLA-DRbright population mainly contained lineage-committed precursors. The results are consistent with the concept that IL-3Rs are induced at very early stages of hematopoiesis, as identified by high expression of CD34 and low expression of RhLA-DR. IL-3R expression continues to be low during differentiation into lineage-committed progenitors; gradually increases on differentiating progenitor cells for B cells, granulocytes, monocytes, and, possibly also, erythrocytes; but finally declines to undetectable levels during terminal differentiation into mature cells of all lineages in peripheral blood, with the exception of basophils.(ABSTRACT TRUNCATED AT 400 WORDS)     

Flow cytometric assessment of human MIC2 expression in bone marrow, thymus, and peripheral blood

The cell-surface expression of the MIC2 antigen defined by the monoclonal antibody 12E7 was investigated on human leukocytes in bone marrow (BM), thymus, and peripheral blood (PB) using multiparameter flow cytometry and cell sorting. In contrast to preceding reports, we found that the MIC2 antigen is not restricted to T cells and monocytes. We show that it is also expressed in the B cell and in the granulocytic lineage, the levels of expression being related to distinct maturational stages. CD34+ cells of BM were found to express the antigen at high levels. Along the granulocytic maturation pathway from CD34+CD33+ blasts to mature granulocytes, MIC2 densities appeared progressively reduced with a considerable decline at the myelocyte stage. In B lymphopoiesis, the earliest CD34+ CD10+ B-cell precursor (BCP) cells, further subdivided by expression of CD19, displayed the highest MIC2 density of BM leukocytes. All later BCP stages showed lower MIC2 expression levels, with a remarkable reduction concomitant with loss of the CD34 antigen at the CD10+CD20- surface mu-chain- stage, and a subsequent slight upregulation along with maturation to CD10-CD20high surface mu-chain+ BCPs. The brightest MIC2 expression of all cells tested was displayed by the most immature thymic T-lineage cells characterized by the antigenic profile CD34weakor- CD7++ surface CD3-CD1a(weak) CD4weak CD8-or weak. Common thymocytes stained slightly less intense with 12E7, whereas all subsequent stages of T-lineage cells in thymus, PB, or BM showed markedly reduced MIC2 levels. Mature peripheral CD4+ as well as CD8+ T cells displayed a bimodal distribution of MIC2. In the CD4+ population, the distinct MIC2 levels were related to the well-studied functional subdivision by differential expression of CD45 isoforms, the helper-inducer/memory subset showing higher MIC2 expression than helper-suppressor/naive CD4+ T cells. Similarly high MIC2 densities were found on CD16+ natural killer cells and on CD14+ monocytes, whereas mature peripheral B cells exhibited low or intermediate expression, and granulocytes exhibited no or only dim expression. These results document that the MIC2 antigen (1) is expressed on all leukocyte lineages; (2) is differentially expressed during T- and B-lymphoid, as well as granulocytic maturation; (3) shows highest expression in the most immature lymphocytic and granulocytic developmental stages; and (4) is also differentially expressed on functional T-cell subsets. We speculate that these observations imply a functional significance of MIC2 in the network of hematopoietic adhesion pathways.     

Decreased expression of the membrane inhibitor of complement-mediated cytolysis CD59 on T-lymphocytes of HIV-infected patients.

OBJECTIVE: To study the expression of the membrane inhibitor of complement-mediated cytolysis, CD59, on peripheral blood mononuclear cells (PBMC) from HIV-infected individuals. METHODS: CD59 membrane expression was investigated by double immunofluorescent staining on purified PBMC from HIV-infected patients and seronegative controls. RESULTS: CD59 expression was decreased on peripheral blood T-lymphocytes from HIV-infected patients. Decreased expression of CD59 antigen did not correlate with clinical stage of disease. Low CD59 expression on T-lymphocytes was mediated by several mechanisms, including: (1) decrease in number of CD4+ cells which normally express high amounts of the antigen; (2) relative increase in CD8+ cells, more specifically in CD8+ CD57+ cells expressing a low density of the antigen; (3) loss of or decreased CD59 expression on a subpopulation of CD3+ belonging either to the CD4+ or to the CD8+ subset. Decreased CD59 expression was consistently observed on CD8+ lymphocytes. CD59 expression was normal on patient red blood cells, monocytes and B-lymphocytes. CONCLUSIONS: HIV infection is associated with a T-cell-specific defect in CD59 membrane expression. Decreased CD59 expression may result in increased susceptibility of T-lymphocytes from HIV-infected patients to complement-mediated lysis.     

Characterization of the in vitro maturation of monocytes and the susceptibility to HIV infection.

The in vitro maturation of peripheral blood monocytes to macrophages can be followed morphologically, and by measurement of cell surface antigens (CD4, HLA-DR, and FcR III) and lysozyme production. We used these markers to correlate monocyte maturation with susceptibility to human immunodeficiency virus (HIV) infection. Maturation of peripheral blood monocytes is associated with a decrease in membrane CD4, while HLA-DR and FcR III expression increase along with lysozyme secretion. Cells at all stages of maturation were susceptible to HIV infection, even mature macrophages without CD4 detectably by immunofluorescent staining. Maximal replication was observed in 7-day-old cells.     

Normal human bone marrow precursors that express terminal deoxynucleotidyl transferase include T-cell precursors and possible lymphoid stem cells

To compare the differentiation of early B- and T-lymphoid precursors, we have used immune adherence combined with analytical flow cytometric techniques to enrich and characterize subsets of the small population of bone marrow mononuclear cells that express the enzyme terminal deoxynucleotidyl transferase (TdT) but lack the CD19 B-lymphoid marker. Two percent to five percent of bone marrow TdT + mononuclear cells belong to the T-lymphoid lineage by virtue of expression of CD7 or CD5. Three-color immunofluorescence studies showed that, like early B-lymphoid precursors, most bone marrow TdT + T cells express HLA-DR and the progenitor cell antigen CD34, and about half express CD10. All CD5 + TdT + cells express surface CD3 and T-cell receptor alpha, beta, while a subset of CD7 + TdT + cells lack these "mature" T cell features. CD2 is low or absent on CD5 + TdT + cells. Examination of isolated CD34 + cells showed that approximately 70% of CD34 + TdT + cells expressed neither CD19, CD22, CD7, nor CD5, and 15% to 50% also lacked CD10. Thus, a major subset of CD34 + TdT + cells lack lineage-specific surface antigens. TdT expression may be the earliest available marker of lymphoid differentiation, and CD34 + TdT + cells are likely to include progenitor cells for both the B and T lineages.     

Dynamics of provirus load and lymphocyte subsets after interleukin 2 treatment in HIV-infected patients

The association of antiretroviral agents plus interleukin 2 (IL-2) represents an efficient approach to the treatment of HIV+ subjects. While the effects of IL-2 on the immune system have been investigated, little is known concerning its impact on HIV dynamics. Two antiretroviral drugs control HIV viremia, but have minimal effects on the proviral load, a predictor of disease progression and response to therapy. The aim of this study was to define the effect of rIL-2 on HIV proviral copy numbers and its relationship to changes in CD4+ and CD8+ subsets. Twelve HIV+ patients with CD4 cell counts between 200 and 500 cells/mm3 were treated with six cycles of subcutaneous rIL-2, in combination with zidovudine and didanosine. This regimen resulted in a rapid and durable decrease in proviral load in the peripheral blood, in an increase in CD8+ lymphocytes, and in the emergence of a CD4+CD45RA+ T subset. These results demonstrate that the rationale for IL-2 administration to HIV+ patients may depend not only on its effects on the immune system, but also on the reduction of the number of infected cells, reinforcing the notion that IL-2 can have a favorable impact on the natural history of HIV infection.     

Heterogeneity of Human Monocytes: An Optimized Four-Color Flow Cytometry Protocol for Analysis of Monocyte Subsets

Monocytes are central mediators in the development of atherosclerotic plaques. They circulate in blood and eventually migrate into tissue including the vessel wall where they give rise to macrophages and dendritic cells. The existence of monocyte subsets with distinct roles in homeostasis and inflammation suggests specialization of function. These subsets are identified based on expression of the CD14 and CD16 markers. Routinely applicable protocols remain elusive, however. Here, we present an optimized four-color flow cytometry protocol for analysis of human blood monocyte subsets using a specific PE-Cy5–conjugated monoclonal antibody (mAb) to HLA-DR, a PE-Cy7-conjugated mAb to CD14, a FITC-conjugated mAb to CD16, and PE-conjugated mAbs to additional markers relevant to monocyte function. Classical CD14⁺CD16⁻ monocytes (here termed “Mo1” subset) expressed high CCR2, CD36, CD64, and CD62L, but low CX₃CR1, whereas “nonclassical” CD14^loCD16⁺ monocytes (Mo3) essentially showed the inverse expression pattern. CD14⁺CD16⁺ monocytes (Mo2) expressed high HLA-DR, CD36, and CD64. In patients with stable coronary artery disease (n = 13), classical monocytes were decreased, whereas “nonclassical” monocytes were increased 90% compared with healthy subjects with angiographically normal coronary arteries (n = 14). Classical monocytes from CAD patients expressed higher CX₃CR1 and CCR2 than controls. Thus, stable CAD is associated with expansion of the nonclassical monocyte subset and increased expression of inflammatory markers on monocytes. Flow cytometric analysis of monocyte subsets and marker expression may provide valuable information on vascular inflammation. This may translate into the identification of monocyte subsets as selective therapeutic targets, thus avoiding adverse events associated with indiscriminate monocyte inhibition.     

PCR analysis of HIV-1 sequences and differential immunological features in seronegative and seropositive haemophiliacs

We have compared the immunological features of two matched groups of seronegative and seropositive haemophilia A individuals. Both groups were exposed from 1981 to 1985 to comparable amounts and batches of FVIII concentrates not subjected to virus inactivation procedures, and had therefore a 100% probability of receiving HIV-contaminated material. The presence of proviral HIV-1 sequences was evaluated by PCR in the DNA from peripheral blood lymphocytes and/or monocytes. After hybridization with specific probes, DNA from all seropositive haemophiliacs revealed HIV sequences; no HIV sequences were observed from the DNA of seronegative patients, even after two rounds of amplification, thus suggesting that these patients were not affected by a latent HIV infection. Seronegative/PCR- and seropositive/PCR+ patients showed a normal and reduced number of CD4+ lymphocytes, and a slight and marked increase of CD8+ cells respectively. Activated T cells expressing the HLA-DR antigen were elevated in both groups. Interestingly, a significant reduction of circulating CD56+/CD3- NK lymphocytes was observed only in seropositive haemophiliacs, whereas NK lymphocytes with CD56+/CD3+ phenotype were within normal levels in both groups. In seropositive patients no correlation was found between the number of CD4+ and CD56+/CD3- lymphocytes. The marked reduction of CD56+/CD3- lymphocytes observed in seropositive haemophiliacs in addition to the CD4+ cell depletion may represent a key pathogenetic factor which facilitates the onset and/or the progression of HIV-1 infection in haemophiliacs, and is related to the capacity of HIV to infect NK cells.     

Expression of CD4 by human hematopoietic progenitors [see comments]

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.     

Immunophenotypical changes of T lymphocytes in the elderly

BACKGROUND: Substantial changes in both representation and function of T lymphocyte subsets have been reported with advancing age. However, till now, no systematic studies focused on age-dependent changes in the expression intensity of the major T lymphocyte surface receptors. OBJECTIVE: The present study was undertaken in order to establish age-related differences in lymphocyte subpopulations by simultaneously measuring three surface antigens in young and elderly people. METHOD: Peripheral blood T cell subsets from 20 healthy elderly individuals and 15 healthy young adult donors were examined by means of a quantitative three-color flow cytometry method. RESULTS: Activated (HLA-DR+) and memory (CD45RO+) T cells, CD3+CD7- T lymphocytes, and cells expressing natural killer (NK) markers (CD3-CD56+ NK cells and CD3+CD56+ T lymphocytes) were expanded, whereas T lymphocytes expressing the adhesion molecule CD62L were lower in elderly compared with young donors. In addition to alterations in the percentages of T cell subsets during senescence, several changes in the intensity expression of T cell antigens were also detected. CD3 antigen expression was downregulated on total T lymphocytes as well as on the memory T cell subset, while CD56+ T cells exhibited increased CD3 levels. Moreover, CD2 expression, unchanged on NK cells, was upregulated on T lymphocytes from elderly subjects. CD3+CD7- T cells exhibited increased expression of CD8 antigen, while the intensity expression of HLA-DR on activated T cells and CD7 on both T and NK lymphocytes was decreased. T cells from elderly subjects also exhibited higher expression of CD50 and CD62L adhesion molecules as compared with young ones. CONCLUSION: These T cell antigen expression modulations during senescence, in addition to the alteration in the frequency of the various T lymphocyte subsets, could contribute to the complex remodeling of the immune function characteristic of the elderly.     

Identification and characterization of a novel monocyte subpopulation in human peripheral blood

With the aid of two-color immunofluorescence and flow cytometry, a new subset of cells coexpressing CD14 and CD16 antigens can be identified in human peripheral blood. Using the monoclonal antibody My4, these CD14+/CD16+ cells account for 2.2% of the mononuclear cells and form about 13% of all cells identified by the monocyte-specific CD14 monoclonal antibody. The CD14+/CD16+ cells can be assigned to the monocyte lineage based on typical morphology, on expression of additional monocyte-associated molecules, on the ability to form reactive oxygen intermediates and on the expression of monocyte-specific NaF-sensitive esterase. Light scatter analysis revealed lower forward angle and right angle light scatter for the CD14+/CD16+ cells compared with the regular monocytes, and the average cell size was determined to be 13.8 and 18.4 microns, respectively. Expression of class II antigens on these "small monocytes" was twofold higher compared with the regular monocytes. By contrast, the capacity to perform adherence to plastic surfaces, as well as the ability to phagocytize antibody-coated erythrocytes was clearly reduced in the CD14+/CD16+ monocyte subset as compared with the regular monocytes. Hence the CD14+/CD16+ cells appear to represent a new monocyte subset with a distinct functional repertoire. A survey of various tissues revealed that a large proportion of the alveolar macrophages, but not of the peritoneal macrophages, express the CD14+/CD16+ phenotype.     

CD34+/CD33- cells reselected from macrophage inflammatory protein 1 alpha+interleukin-3--supplemented "stroma-noncontact" cultures are highly enriched for long-term bone marrow culture initiating cells

Human hematopoietic stem cells are thought to express the CD34 stem cell antigen, low numbers of HLA-DR and Thy1 antigens, but no lineage commitment antigens, CD38, or CD45RA antigens. However, fluorescence- activated cell sorted CD34+ subpopulations contain not more than 1% to 5% primitive progenitors capable of initiating and sustaining growth in long-term bone marrow culture initiating cells (LTBMC-ICs). We have recently shown that culture of fresh human marrow CD34+/HLA-DR- cells separated from a stromal layer by a microporous membrane ("stroma- noncontact" culture) results in the maintenance of 40% of LTBMC-ICs. We hypothesized that reselection of CD34+ subpopulations still present after several weeks in stroma-noncontact cultures may result in the selection of cells more highly enriched for human LTBMC-ICs. Fresh marrow CD34+/HLA-DR- cells were cultured for 2 to 3 weeks in stroma- noncontact cultures. Cultured progeny was then sorted on the basis of CD34, HLA-DR, or CD33 antigen expression, and sorted cells evaluated for the presence of LTBMC-ICs by limiting dilution analysis. We show that (1) LTBMC-ICs are four times more frequent in cultured CD34+/HLA- DR- cells (4.6% +/- 1.7%) than in cultured CD34+/HLA-DR- cells (1.3% +/- 0.4%). This suggests that HLA-DR antigen expression may depend on the activation status of primitive cells rather than their lineage commitment. We then sorted cultured cells on the basis of the myeloid commitment antigen, CD33. (2) These studies show that cultured CD34+/CD33- cells contain 4% to 8% LTBMC-ICs, whereas cultured CD34+/CD33+bright cells contain only 0.1% +/- 0.03% LTBMC-ICs. Because LTBMC-ICs are maintained significantly better in stroma-noncontact cultures supplemented with macrophage inflammatory protein 1 alpha (MIP- 1 alpha) and interleukin-3 (IL-3) (Verfaillie et al, J Exp Med 179:643, 1994), we evaluated the frequency of LTBMC-ICs in CD34+/CD33- cells present in such cultures. (3) CD34+/CD33- cells present in MIP-1 alpha + IL-3-supplemented cultures contain up to 30% LTBMC-ICs. The increased frequency of LTBMC-ICs in cultured CD34+ subpopulations may be the result of terminal differentiation of less primitive progenitors, loss of cells that fail to respond to the culture conditions or recruitment of quiescent LTBMC-ICs. The capability to select progenitor populations containing up to 30% LTBMC-ICs should prove useful in studies examining the growth requirements, self-renewal, and multilineage differentiation capacity of human hematopoietic stem cells at the single-cell level.     

老年人外周血单核细胞表面HLA-DR和T淋巴细胞亚群的改变

目的通过对健康老年人与健康年轻人外周血单核细胞人类白细胞抗原(HLA-DR)和T淋巴细胞亚群表达水平的比较,探讨HLA-DR和T淋巴细胞亚群的表达与衰老的关系。方法采用免疫荧光标记流式细胞技术测定20例健康老年人和20例健康年轻人外周血单核细胞HLA-DR和CD3、CD4、CD8的水平。结果老年组外周血单核细胞HLA-DR的表达稍高于年轻组,但统计学上差异不明显(P>0.05),老年人CD4 T细胞、CD4/CD8低于年轻组,两者之间统计学差异明显(P<0.05或P<0.01)。结论老年组单核细胞HLA-DR的表达稍高于年轻组,但功能降低,CD4 T淋巴细胞和CD4/CD8较年轻组下降,是老年人免疫功能减退的原因之一。     

Quantitative immunocytofluorographic analysis of CD4 surface antigen expression and HIV infection of human peripheral blood monocyte/macrophages

HIV infection of CD4-bearing lymphocytes alone does not fully explain the immune dysfunction of AIDS. Monocyte/macrophages infected with HIV may serve as a reservoir of HIV, may function abnormally and may transmit infection to other susceptible cells, thus playing a central role in the development of the immunodeficiency of AIDS. Quantitative analysis of surface antigens and measurement of HIV antigens in infected cells have been difficult using the conventional approach of immunofluorescent staining of cells on slides. We have developed a system that maintains monocyte/macrophages in suspension culture for at least four months. Through immunocytofluorographic single cell analysis we have shown that CD4 antigen is present on monocytes, and that a tenfold increase in expression occurs during the first two weeks in culture. In contrast, LeuM3 antigens decreased to background levels in the course of long-term culture. Using anti-HIV p24 antibody, we have demonstrated that monocyte/macrophages can be infected with HIV. Up to 70% of cells from individual donors could be infected. The techniques herein described allow in vitro quantitation of some of the mechanisms by which HIV infection of monocyte/macrophages may contribute to the immunodeficiency states associated with AIDS.