A subset of OKT4+ peripheral T cells can generate colonies containing mixed progeny with OKT4+ helper and OKT8+ suppressor cells

The membrane phenotype of human T cell colony progenitors and that of their clonal progeny was studied for expression of the T4 and T8 determinants. Using clonal culture conditions, the colonies were grown in semi-solid agar medium from peripheral blood cells. Clonality was assessed using the glucose-6-phosphate-dehydrogenase isoenzyme marker. Combination of this marker with the culture of sorted cell fractions allowed us to ascribe the colony progenitors to a subset of OKT4+ lymphocytes. The progeny consisted of the mixture of single OKT4+, single OKT8+ and double OKT4+8+ cells, as determined by double staining. Double staining was performed on mass-harvested colony cells and on individual colonies expanded in liquid culture with fresh interleukin 2. Expression of the OKT8 positivity on colony cells deriving from OKT4+ progenitors required an interaction with radioresistant OKT8+ cells that were co-cultured with these progenitors. Furthermore, the functional capacities of the cell progeny were assayed on the pokeweed mitogen-driven immunoglobulin production by B cells. It was found that OKT4+ colony cells were helper whereas OKT8+ colony cells were suppressor cells. It is concluded that a subset of OKT4+ peripheral blood T lymphocytes can generate colonies containing both helper OKT4+ cells and suppressor OKT8+ cells.     

T-cell colony formation from murine thymocyte subpopulations and pre-T cells.

Murine thymocytes are able to proliferate on clonal basis as colonies in the semisolid medium methylcellulose. It has previously been shown that the colony-forming cells are predominantly rather mature thymocytes and presumably exclusively single positive CD8+ cells. The results of the present study point to that also immature CD4-CD8- (DN = double negative) thymocytes and pre-T cells from nude mice are able to form colonies in methylcellulose culture. The numbers of colonies are increased by the presence of phorbolester, and it is shown by the addition of various interleukins to the culture that IL-2 is the essential interleukin in colony formation. It is further shown that all colony cells derived from DN thymocytes are of the CD4-CD8+ phenotype, while nude mouse precursors give rise to either CD8+ or DN colony cells. Thus, no CD4+ T cells were able to proliferate as colonies by the present culture method, even after exposure to a number of different interleukins or phorbolesters. This makes the method a reliable tool for clonal growth of both immature and mature CD8+ thymocytes and T cells.     

CD69, HLA-DR and the IL-2R identify persistently activated T cells in psoriasis vulgaris lesional skin: blood and skin comparisons by flow cytometry

Many lymphocyte-activation-associated molecules are observed by immunohistochemistry in psoriasis vulgaris lesional skin. Non-T cells in lesional skin also express these molecules. We quantitatively measured the number of T cells expressing cell surface activation-associated molecules (CD69, CD25, CD122, HLA-DR) and co-stimulatory molecules (CD28, CTLA-4, CD80, CD86), including a Type 2 T cell marker (CD30) and CD11b, by flow cytometry of skin and peripheral blood. T cells in single cell suspensions of psoriatic lesional-epidermis-expressed HLA-DR (86%), CD69 (59%), CD25 (55%), CD122 (44%), and CD28 (91%). Dermal T cells showed similar percentages except for CD69 (17%). CD69 was found directly in lesional skin biopsies by immunohistochemistry. Both CD4 and CD8 subsets from lesional skin contained large populations of CD25+ cells with a bias towards CD8 activation in the epidermis and towards CD4 activation in the dermis. CD86, CD80, CTLA-4, CD30 and CD11b were expressed by less than 23% of the T cell populations from both the epidermis and dermis. CD30+CD4+ cells were found two-fold over CD8+ T cells. These results show that the majority of lesional lymphocytes are persistently activated. We also found the majority of Type 2 associated markers primarily on the CD4+ epidermal T cell population. Psoriatic blood contained elevated levels of T cells expressing CD25, primarily within the CD8+ subset. Thus the majority of lesional T cells expressed the three primary activation markers, while psoriatic blood T cells were distinguished by an increase in CD25, specifically within the CTL population.     

The T-lymphocyte colony-forming cell (T-CFC): in vitro studies of progenitors and progeny.

The lineage of T-lymphocyte colony-forming cells (T-CFC) and the phenotype of the progeny of T-CFC have not yet been well-defined. To characterize the progenitor cells and progeny of the T-CFC, we separated normal human peripheral blood lymphocytes into enriched lymphocyte subpopulations, stimulated with various mitogens and cultured in a semisolid agar system. After 5 days, the number of colonies was counted, and the presence of CD4+ and CD8+ cells was determined in situ with FITC-conjugated monoclonal antibodies. Plating of B cells provided the lowest, T cells an intermediate and null cells the highest number of T-cell colonies (P less than 0.05). CD4+ and CD8+ cells produced equivalent numbers of T-cell colonies. T-cell colonies consisted of either CD4+ or CD8+ cells; mixed-cell colonies were rarely present. Plating of CD4+ or CD8+ cells produced both CD4+ and CD8+ colonies. We conclude that T-CFC exist in the CD4+, CD8+ and null-cell populations. In addition, T-CFC give rise to T-cell colonies possessing either CD4+ or CD8+ determinants.     

Activation by PHA of CD8 lymphocytes into clonal colony forming cells: Role of interleukin-1

Monoclonal T cell colonies can be grown in agar culture from quiescent T lymphocytes under PHA stimulation, provided that (1) a low number of T lymphocytes (5 × 10⁴/ml) is seeded, (2) IL-2 is added to the culture, and (3) a high number of accessory B cells (5 × 10⁵/ml) is present in contact with the T lymphocytes. Under these culture conditions the colony progenitors can be ascribed to the CD4 subset, whereas CD8 lymphocytes do not generate colonies. This finding is surprising since both CD4 and CD8 lymphocytes may be cloned in liquid culture. We now report the appropriate conditions required to grow cytotoxic CD8 lymphocyte colonies in agar. CD8 colony growth is dependent upon IL-2-IL-2 receptor interaction and is inhibited by anti-IL-2 receptor antibodies. In addition to PHA, accessory B cells and IL-2, an additional signal provided by recombinant IL-1 is necessary for CD8 colony formation. Exogenous IL-1 can be replaced by irradiated CD4 lymphocytes which stimulate the expression of membrane IL-1 activity in the accessory B cells. In addition, colony growth from quiescent but not preactivated CD8 lymphocytes is inhibited by anti-IL-1 antibodies. Altogether, the data show that an IL-1 signal is required for the induction of IL-2 responsive IL-2 receptors on quiescent CD8 colony forming cells.     

CD8+ T cells have an essential role in pulmonary clearance of nontypeable Haemophilus influenzae following mucosal immunization

A rodent respiratory experimental model has proved useful for investigating the immune mechanisms responsible for clearance of bacteria from the lungs. Immunohistochemical studies in immune and nonimmune rats have identified the cellular kinetics of response to bacterial pulmonary infection for CD8+, CD4+, and gammadelta+ T cells; B cells; and the expression of major histocompatibility complex class II (MHC-II). During the course of bacterial clearance, there was no apparent proliferation or extravasation of lymphocytes, nor was there increased expression of MHC-II in nonimmune animals despite an influx of polymorphonuclear leukocytes, whereas in immunized animals there was an early influx of CD8+ and gammadelta+ T cells, followed by enhanced expression of the MHC-II marker, cellular infiltration by polymorphonuclear leukocytes, and finally an increased number of CD4+ T cells. Depletion of CD8+ T cells confirmed their vital contribution in the preprimed immune response to pulmonary infection by significantly decreasing the animals' ability to clear bacteria following challenge.     

Phenotype and function of peripheral blood and bone marrow T-cell colonies: identification of DC3-, 4-, 8-autoreactive T cells

The existence of immature autoreactive T cells has been examined in peripheral blood (PB) and bone marrow (BM) derived T-lymphocyte colonies (TLC) that have previously been shown to be potentially generated from CD3-negative BM-T cells. An extensive phenotypical analysis of total and T-depleted TLC showed that both PB- and BM-derived TLC contained a mean of 5% immature T lymphocytes (ITL), which were negative for the CD3, CD4, and CD8 antigens but displayed the CD2 and CD7 antigens. The only detectable immune functions of these isolated ITL were an allo- and an autoreactivity without cytolytic activity. The self-reactivity of ITL was not detected in bulk non T-depleted TLC cells and seemed to be actively suppressed by autologous mature T cells. In addition, the auto-MLR of ITL was totally inhibited by anti-HLA class II but not by anti-class I monoclonal antibody (MoAb) and only partially by anti-CD4 moAb, whereas the anti-CD3 and anti-CD2 MoAbs gave no inhibition. Once activated, ITL could acquire in culture a mature T cell CD3 + CD4 + phenotype. The CD3-, 4-, 8-auto-reactive T cells present in T colonies could represent pre- or post-thymic cells that have not yet undergo or that have escaped the thymic selection.     

Mucosal T-cell phenotypes in persistent atopic and nonatopic rhinitis show an association with mast cells

Background: Allergic rhinitis is characterized by selective expansion of T cell subsets with a CD4+ phenotype. Recently, we identified a subpopulation of nonallergic rhinitis subjects with increased epithelial mast cell and eosinophil populations, suggestive of local mucosal allergy. Previously, T cell subsets have not been characterized in this subselection of nonallergic subjects and furthermore, their relationship to mast cell and basophil effector cells remain unidentified. Objective: To determine if a subpopulation of nonallergic subjects with idiopathic rhinitis (IR) have localized allergy confined to their nasal mucosa by comparing the T cell subsets and major histocompatibility complex (MHC) II expressing cells to persistent allergic rhinitis (PAR). Furthermore, the relationship between T cell subsets and mast cells/basophils was investigated. Methods: None of the symptomatic patients in this study were clinically allergen‐challenged. Nasal turbinate mucosa was removed from patients with PAR, IR and normal controls. Morphometry was performed on immunostained sections for T cell subset populations including CD3+, CD4+, CD8+, CD25+, CD45RA+, CD45RO+, human leucocyte antigen (HLA)‐DRα (MHC class II), mast cell tryptase and for basophils. Results: Subjects with persistent allergic rhinitis differed to normal controls in showing significantly increased numbers of total (CD3+), activated (CD25+) and allergen‐naïve (CD45RA+) T lymphocytes in their nasal mucosa (P < 0.025). The naïve CD45RA+ memory T cells correlated to mucosal mast cells in PAR (P = 0.03). IR patients differ to allergic subjects in showing significantly reduced numbers of epithelial HLA‐DRα+ cells (P = 0.007), but increased numbers of CD8+ lymphocytes (P = 0.02). The CD8+ T cells correlated with mucosal mast cell numbers (P = 0.02). In both rhinitis groups, basophils were present in very low numbers obviating the need for statistical analysis. Conclusion: PAR is characterized by increased numbers of CD3+, CD25+ and CD45RA+ T lymphocytes compared with normal mucosa. Allergic and nonallergic rhinitis groups can be separated by significant differences in the number of epithelial antigen presenting cells (APCs) (HLA‐DRα+) and sub‐epithelial activated (CD25+) T cells. Moreover, IR patients do not significantly differ to their allergic counterparts with respect to total (CD3+) and naïve (CD45RA+) T cell numbers, or numbers of epithelial activated (CD25+) lymphocytes. IR subjects show significantly increased numbers of CD8+ lymphocytes compared with control mucosa and although our findings suggest that the initiating inflammatory events may differ, both rhinitis groups show a similarity in pathology involving mucosal mast cells with an association to infiltrating T cells.     

Contribution of NK, NK T, gamma delta T, and alpha beta T cells to the gamma interferon response required for liver protection against Trypanosoma cruzi

In the present work, we show that intracellular Trypanosoma cruzi is rarely found in the livers of acutely infected mice, but inflammation is commonly observed. The presence of numerous intrahepatic amastigotes in infected gamma interferon (IFN-gamma)-deficient mice corroborates the notion that the liver is protected by an efficient local immunity. The contribution of different cell populations was suggested by data showing that CD4- and CD8-deficient mice were able to restrain liver parasite growth. Therefore, we have characterized the liver-infiltrating lymphocytes and determined the sources of IFN-gamma during acute T. cruzi infection. We observed that natural killer (NK) cells increased by day 7, while T and B cells increased by day 14. Among CD3+ cells, CD4+, CD8+, and CD4- CD8- cell populations were greatly expanded. A large fraction of CD3+ cells were positive for PanNK, a beta1 integrin expressed by NK and NK T cells. However, these lymphocytes were not classic NK T cells because they did not express NK1.1 and showed no preferential usage of Vbeta8. Otherwise, liver NK T (CD3+ NK1.1+) cells were not increased in acutely infected mice. The majority of PanNK+ CD4+ and PanNK+ CD8+ cells expressed T-cell receptor alphabeta (TCRalphabeta), whereas PanNK+ CD4- CD8- cells were positive for TCRgammadelta. In fact, gammadelta T cells showed the most remarkable increase (40- to 100-fold) among liver lymphocytes. Most importantly, intracellular analysis revealed high levels of IFN-gamma production at day 7 by NK cells and at day 14 by CD4+, CD8+, and CD4- CD8- TCRgammadelta+ cells. We concluded that NK cells are a precocious source of IFN-gamma in the livers of acutely infected mice, and, as the disease progresses, conventional CD4+ and CD8+ T cells and gammadelta T cells, but not classic NK-T cells, may provide the IFN-gamma required for liver protection against T. cruzi.     

BHV-1-Specific CD4+, CD8+, and gammadelta T cells in calves vaccinated with one dose of a modified live BHV-1 vaccine

Expression of the high-affinity interleukin 2 receptor alpha chain (CD25) was used to monitor antigen-specific activation of T lymphocyte subsets (CD4+, CD8+, and gammadelta T cells) from cattle immunized with modified live bovine herpesvirus-1 (BHV-1). Calves seronegative for BHV-1 were either vaccinated with one dose of modified live vaccine containing BHV-1 or not vaccinated to serve as negative controls. Two animals vaccinated 7 and 5 weeks before the start of the experiment with two doses of modified live vaccine containing BHV-1 served as positive controls. Blood samples were taken from the nonvaccinate group, the positive control group, and the vaccinate group at 0, 21, 35, 60, and 90 days postinoculation (PI). Isolated peripheral blood mononuclear cells from immunized and control animals were incubated for 5 days with and without live BHV-1 ISU99. Compared to the nonvaccinates, a significant (p < 0.05) increase in expression of CD25 by CD4+, CD8+, and gammadelta T lymphocytes from the vaccinate group was detected following in vitro exposure to live BHV-1 after vaccination. This is apparently the first report using live BHV-1 to stimulate lymphocytes in vitro and showing CD8+ T cell activation. Peripheral blood from the positive control animals was depleted of CD4+, CD8+, or gammadelta T lymphocytes prior to incubation with BHV-1 to assess bystander activation in the CD25 expression assay. When incubated with live BHV-1, depletion of CD4+ T cells depressed the expression of CD25 by CD8+ T cells, but not gammadelta T cells. Depleting CD8+ or gammadelta T cells prior to in vitro culture with BHV-1 did not affect the expression of CD25 by the remaining T lymphocyte subsets. Vaccinates were protected from challenge with virulent BHV-1 at 110 days postvaccination compared to nonvaccinates. Expression of CD25 appears to be a useful marker for evaluating induction of antigen-specific T lymphocyte subset responses following vaccination.     

Membranes of activated CD4+ T cells expressing T cell receptor (TcR) alpha beta or TcR gamma delta induce IgE synthesis by human B cells in the presence of interleukin-4.

In the present study it is demonstrated that human B cells can be induced to switch to IgE production following a contact-mediated signal provided by activated T cell receptor (TcR) gamma delta+, CD4+ and TcR alpha beta+, CD4+ T cell clones and interleukin (IL)-4. The signal provided by these T cell clones was antigen nonspecific, indicating that the TcR alpha beta/CD3 or TcR gamma delta/CD3 complexes were not involved in these T-B cell interactions. Activated TcR alpha beta+, CD8+, and TcR gamma delta+, CD4-CD8-, or resting CD4+ T cell clones were ineffective. Intact TcR alpha beta+ or TcR gamma delta+, CD4+ T cell clones could be replaced by plasma membrane-enriched fractions isolated from these activated CD4+ T cell clones. In contrast, membranes isolated from resting TcR alpha beta+, CD4+, TcR gamma delta+, CD4+ T cell clones or an Epstein-Barr virus (EBV)-transformed B cell line (EBV-LCL) failed to provide the costimulatory signal that, in addition to IL-4, is required for induction of IgE synthesis. As described for intact CD4+ T cells, CD4+ T cell membranes induced purified surface IgM+ B cells to switch to IgG4- and IgE- but not to IgA-producing cells, excluding the possibility of a preferential outgrowth of IgG4- and IgE-committed B cells. The membrane activity was inhibited by protease or heat treatment. Induction of IgE synthesis by B cells co-cultured with both TcR alpha beta+, CD4+ and TcR gamma delta+, CD4+ T cell clones and membrane preparations of these cells was blocked by anti-class II major histocompatibility complex (MHC) monoclonal antibodies (mAb), whereas various anti-CD4 mAb had differential blocking effects. Murine L cells, or EBV-LCL transfected with CD4 could not replace CD4+ T cell clones. These results indicate that, although CD4 and class II MHC antigens are required for productive CD4+ T cell clone-B cell interactions, an additional signal, provided by a membrane associated (glyco)protein that is induced by activation of both TcR alpha beta and TcR gamma delta, CD4+ T cells, is needed for induction of IgE production in the presence of IL-4.     

Multiple myeloma: ecto-5'' nucleotidase deficiency of suppressor/cytotoxic (CD8) lymphocytes is a marker for the expansion of suppressor T cells.

In this study, 5'NT activity was investigated by radiochemical and cytochemical assays in T cell subpopulations of patients with multiple myeloma (MM). Cytotoxic/suppressor (CD8) and helper/inducer (CD4) lymphocytes were separated from peripheral blood by the panning technique, or sorted with a fluorescein activated cell sorter. 5'NT activity was significantly decreased in MM CD8 lymphocytes compared with the controls. By contrast, it was comparably low in CD4 subpopulations of normal controls and MM patients. The cytochemical assay indicated that a decreased number of 5'NT+ cells rather than a decreased activity per cell was responsible for 5'NT deficiency in MM CD8 lymphocytes. CD8 lymphocytes with the suppressor phenotype (OKMI+, granular cells) were significantly increased in MM. These data provide a phenotypic explanation for the enhanced suppressor activity displayed by T lymphocytes in MM. A significant correlation was found between the increase of suppressor cells and the decrease of 5'NT+ cells. 5'NT deficiency of CD8 lymphocytes can be a biochemical marker for the expansion of suppressor T cells.     

Absence of Epstein-Barr virus-specific, HLA class II-restricted CD4+ cytotoxic T lymphocytes in infectious mononucleosis.

Cytotoxic T lymphocytes (CTL) with the CD4+ phenotype that recognize major histocompatibility complex (MHC) class II antigens are detectable very frequently in cultures of human alloreactive or virus-specific T cells. The significance of these CD4+ CTL for an immune reaction in vivo is not clear. Since Epstein-Barr virus (EBV) transformed B cells express HLA-class I and class II antigens equally well both CD8+ and CD4+ CTL should be stimulated during an acute EBV infection. We analysed the MHC specificity and the phenotype of EBV-specific CTL from patients with infectious mononucleosis (IM). When tested directly without any previous culture, T cells from patients in the acute phase of IM showed specific MHC-restricted cytotoxicity against the autologous B cell line. Addition of a HLA class I specific monoclonal antibody (MoAb) but not of a HLA class II specific MoAb resulted in a complete blocking of the lytic activity. Cell sorting revealed that the entire cytotoxic activity was present in the CD8+ fraction whereas no specific CTL were detectable in the CD4+ fraction. The absence of cytotoxicity in CD4+ cells was not due to a lack of activation of these cells since both CD8+ and CD4+ cells were activated in situ, showing spontaneous growth in interleukin-2 (IL-2) and expressing the activation marker TP103. Frequency estimation revealed that 1/300-1/600 CD8+ but only 1/2000-1/4000 CD4+ T cells gave rise to a specific CTL colony after 10 days. If CD4+ colonies were tested repeatedly for cytotoxicity we found that CD4+ CTL acquired their cytotoxicity during in vitro culture. In addition, we isolated EBV-specific CD4+ T cell clones able to lyse their stimulator cells in the presence but not in the absence of lectin, even after a long period of culture. Taken together our results show that cytotoxicity mediated by CD4+ T cells does not play a role in an anti-viral immune response.     

Non-random migration of CD4+, CD8+, gamma delta + T19+, and B cells between blood and lymph draining ileal and prescapular lymph nodes in the sheep fetus

We have examined the circulation of CD5+, CD4+, CD8+, gamma delta + T19+, and B cells through ileal and prescapular lymph nodes in the sheep fetus in an environment uninfluenced by foreign antigen and ongoing immune responses or circulating immunoglobulins, and have contrasted this circulation with that occurring through the same tissue in 1-year-old sheep. The vast majority of lymphocytes circulating through fetal prescapular lymph nodes and fetal ileal lymph were T cells; however, there was a significantly higher concentration of B cells in ileal lymph compared to prescapular lymph. Furthermore, in contrast to 1-year-old sheep, there was an imbalance in the distribution of CD4+ cells and CD8+ cells in fetal prescapular and ileal lymph, with CD4+ cells enriched in prescapular lymph relative to other T cell subsets and CD8+ cells enriched in ileal lymph. Our results suggest that in the fetus either there is preferential migration of CD4+ cells through peripheral lymph nodes and/or CD8+ lymphocytes through the ileal gut, or newly formed CD8+ lymphocytes are being released from the ileum or ileal lymph node directly into ileal lymph.     

T lymphocyte regeneration after transplantation of T cell depleted allogeneic bone marrow

The regeneration of T cell subsets was studied with double immunofluorescence marker methods in 37 patients who received HLA matched T lymphocyte depleted bone marrow transplants (BMT) as part of the treatment for their haematological disease. A cocktail of anti-pan-T (CD6: MBG6) and anti-suppressor/cytotoxic-T cell (CD8: RFT8) monoclonal antibodies was used with rabbit serum as a source of cytolytic complement to achieve selective T cell lysis. The T8+ cells reached low normal values around 60 days post-transplant and remained within the normal range throughout the study (greater than 150 days). This observation is in contrast to our previously published results in patients who, after receiving BMT without efficient T cell depletion, had increased numbers of circulation T8+ cells from 60 days post-transplant. In the present study Leu-7+, RFT8- cells reached normal values rapidly but the reconstitution of T4+ lymphocytes was slow: low normal levels were reached only around day 150 following BMT. The degree of graft-versus-host disease (GVHD) seemed to be related to the number of residual T cells infused: two of the three patients who received the highest numbers of T cells developed Grade II III; otherwise GVHD was minimal. Among the clinical parameters studied cytomegalovirus (CMV) immune status moderately influenced reconstitution: at 55-90 days post-transplant T8+ cells were present at the upper normal levels in seven out of 15 patients receiving BMT from CMV seronegative donors, but in none of the 16 individuals receiving BMT from seropositive donors. CMV related complications were relatively uncommon. Thus the most significant factor in preventing 'T8+ cell overshoot' and T cell imbalance during regeneration appears to be the depletion of T (including T8+) lymphocytes from marrow. The differences of T8+ cell reconstitution in this and previous studies may reflect a different regeneration pattern from T cell precursors as opposed to inoculated mature T cells.     

Proliferative heterogeneity in the human prostate: evidence for epithelial stem cells

Clonal analysis of human prostate epithelial cells was undertaken in order to identify stem cells. Two types of colony were distinguished, termed type I and type II. Type I colonies were relatively small and irregular and contained a loose mixture of differentiated and undifferentiated cells. In contrast, type II colonies were large, round, and homogeneous, consisting almost exclusively of small undifferentiated and dividing cells. The colony-forming efficiency was 5.8% +/- 1.8 for freshly isolated epithelial cells. There were approximately 10 times as many type I as type II colonies and about 1 in 200 of the plated cells was capable of forming a type II colony. In three-dimensional culture on Matrigel, the type II colonies produced structures reminiscent of prostate epithelium, with luminal cells expressing markers of prostate epithelial differentiation, including the androgen receptor. On the basis of their proliferative characteristics and pluripotency, the type II colonies may be the progeny of stem cells and the type I colonies of a more differentiated transit-amplifying population.     

Cell cycling in HIV infection: analysis of in vivo activated lymphocytes.

Infection with HIV results in increased circulating levels of T lymphocytes expressing phenotypic markers of immune activation. In the present study, using three-colour immunofluorescence, we examined the cell cycle status of these activated cells. Activated (HLA-DR+, CD25+ and CD38+) CD4+ and CD8+ T lymphocytes in peripheral blood were analysed for DNA content in 15 HIV+ patients and 10 healthy age- and sex-matched control subjects. As expected, all HIV+ patients had elevated percentage levels of activated CD4+ HLA-DR+, CD4+ CD25+, CD8+ HLA-DR+, CD8+ CD25+ and CD8+ CD38+ T lymphocytes compared with control subjects (P < 0.001 for all). Percentage levels of CD4+ HLA-DR+ and CD8+ HLA-DR+T lymphocytes in the 'proliferative' (S-G2M) phase of the cell cycle were also higher in the HIV+ patients compared with controls (P < 0.001 for both). The percentage levels of proliferative CD4+ CD25+, CD8+ CD25+ and CD8+ CD38+ lymphocytes were, however, similar in HIV+ patients and controls, indicating that the proliferative fraction of cells in vivo was confined to the HLA-DR+ subset and absent from the CD25+ and CD38+ populations. Four HIV+ patients had grossly elevated levels of CD8+ lymphocytes which were CD38+ (> 95%) and confined to the pre-G0-G1 phase of the cell cycle, suggesting these may be cells committed to apoptosis. These observations indicate an increase in the proliferative capacity of HLA-DR+ T lymphocytes in HIV infection in vivo. The reduced DNA content in other populations (e.g. CD38+ CD8+ lymphocytes) of some patients with advanced HIV disease suggests that these cells are apoptotic. Thus our results define both proliferative and apoptotic processes as a spectrum of activation-related events in HIV infection.     

Difference in the cell proliferation and colony-forming ability of normal human T lymphocytes.

Cell transfer experiments were carried out with phytohaemagglutinin-induced normal human T lymphocyte colonies after 2--10 days of primary colony growth. The cells gave a cloning efficiency of 15% after 2 days of incubation and this decreased to 0.2% with the progressive growth of the colonies. The primary colonies had a proliferative capacity to give about 240 cells after 10 days of incubation, but only contained 0.5 to one cell per colony that could form a new colony. This number of colony-forming cells per colony did not change with an increase in colony size. These results indicate that colonies maintained the same number of colony-forming cells that they started with and that the other cells could proliferate but not form colonies. It is suggested that this ability to distinguish between colony-forming and proliferative T cells may be useful for determining specific deficiencie in either cell type in various diseases.     

Bone marrow T cell colony-forming cells: studies of their origin and use in monitoring T cell-depleted bone marrow grafts.

Peripheral blood T cell colony forming cells (T-CFC) are mature T cells. When blood was fractionated into sheep red blood cell receptor positive (E+) and negative (E-) fractions, T cell colony growth was largely restricted to the E+ population. When bone marrow was similarly fractionated, many colonies grew from the E- cells but myeloid colonies also grew making interpretation of colony numbers difficult. We have, therefore, also assessed T cell proliferation during culture as an expansion index (EI) by determining the absolute number of T cells pre and post culture. This data shows that T cell expansion is on average nine times greater in the E- marrow fraction than in the E+ fraction. Studies are presented suggesting that this is because marrow E- cells contain appropriate accessory cells and that high numbers of T cells inhibit T cell growth. The cells giving rise to bone marrow T cell colonies thus appear to be contaminating mature T cells rather than pre-thymic progenitor cells. We have measured T cell expansion in culture as a sensitive assay of T cell contamination following procedures to remove T cells from bone marrow grafts for the prevention of graft versus host disease (GVHD).     

IL-10 enhances expression of the IL-2 receptor alpha chain on T cells.

Interleukin-10 (IL-10) has various immunomodulatory actions depending on the target cell type. Some of these effects have been shown to be owing to its ability to down-regulate surface expression of markers, for example HLA-DR on macrophages and CD25 (IL-2 receptor alpha chain) on B cells. In this report we show that preincubation of IL-10 for 24 hr up-regulates expression of the activation marker CD25, but not HLA-DR on cloned T cells of various phenotypes such as CD4+, CD8+, CD4- CD8- alpha beta and gamma delta T-cell receptor (TCR)-expressing cells. This up-regulation of CD25 was accompanied by an increase in the T cells IL-2-dependent proliferative response in 63% of the CD4+ clones and 100% of the CD8+, CD4-, CD8- alpha beta and gamma delta TCR+ clones analysed. IL-10 was also shown to be at least partly responsible for the up-regulation of CD25 on mitogen-activated peripheral blood mononuclear cells, suggesting that IL-10 has this CD25 modulatory effect within a more physiological environment. Our data suggest that IL-10 can have a multitude of effects on human T cells, and should not be considered exclusively as an immunoinhibitory cytokine.