Human T-cell leukemia virus type I(HTLV-I) infection of T cells bearing T-cell receptor gamma delta: effects of HTLV-I infection on cytotoxicity.

In order to clarify the cellular tropism of human T-cell leukemia virus type I (HTLV-I) and the effects of HTLV-I infection on T-cell functions, we investigated the infectiousness of HTLV-I on T cells bearing T-cell receptor (TCR) gamma delta and functional alterations of the HTLV-I-infected TCR-gamma delta + T cells. CD3+ CD4-CD8-TCR-gamma delta + T-cell clones which possessed cytotoxicity were co-cultured with a HTLV-I-producing T-cell line. After several weeks, integration of HTLV-I proviral DNA in TCR-gamma delta + T cells was detected by Southern blot analysis. During the continuous culture of HTLV-I-infected TCR-gamma delta + T-cell clones, 2 distinct phases were observed in terms of cytotoxic activity and expression of the CD3-TCR-gamma delta complex. Early after HTLV-I infection, TCR-gamma delta + T cells lost their spontaneous cytotoxicity, but this was restored by the addition of lectin. At this time, no differences were observed in the expression of various surface molecules between HTLV-I-infected and uninfected parent cells, except for increased expression of CD25 on HTLV-I-infected cells. At about 30 weeks after HTLV-I infection, the cytotoxicity of HTLV-I-infected cells was almost completely lost, even in the presence of lectin, and expression of the CD3-TCR-gamma delta complex on the cell surface was markedly decreased. Concomitant with the decreased expression of CD3-TCR-gamma delta complexes, a decrease in the elevation of cytoplasmic Ca2+ concentration induced by anti-CD3 and anti-TCR monoclonal antibodies (MAbs) was also observed. Our present findings thus show that HTLV-I can infect TCR-gamma delta + T cells, and that consequently their functions are profoundly affected through 2 distinct phases.

Human double-negative (CD4-CD8-) T cells bearing alpha beta T cell receptor possess both helper and cytotoxic activities.

Expression of CD4 or CD8 on the cell surface is an important guide for discriminating the immunological functions of T cells. However, a minor T cell subset, which lacks both CD4 and CD8 molecules but bears the usual form of T cell receptor (TCR) alpha beta (CD4-CD8-TCR alpha beta+ T cells), has recently been found not only in mice but also in humans, and its role in immune response is now of considerable interest. In order to clarify the characteristics of this newly defined T cell subpopulation, we established five IL-2-dependent CD4-CD8-TCR alpha beta+ T cell clones from the peripheral blood of a healthy individual, and examined their various biological functions. It was found that all clones not only helped B cells in immunoglobulin production, but also exerted major histocompatibility complex-unrestricted cytotoxicity. Although their CD3/TCR complexes were functionally competent, the cytotoxicity seemed to be mediated via unknown molecules other than the CD3/TCR complex, as evidenced by the failure of CD3 MoAb to inhibit the cytotoxic activity. Our present findings showed that CD4-CD8-TCR alpha beta+ T cells possess potential bifunction, i.e. helper and cytotoxic activities. Their roles in the pathogenesis of immunodeficiency are discussed.

The effect of human T cell leukaemia virus type I infection on a herpes simplex virus-specific CD8+ cytotoxic T cell clone.

In an effort to clarify the effect of human T cell leukaemia virus type I (HTLV-I) infection on virus-specific CD8+ cytotoxic T cells, a herpes simplex virus-specific CD8+ cytotoxic T cell clone was infected with HTLV-I in vitro. The cytotoxic activity of the clone was found to have declined early after HTLV-I infection when the expression of T cell receptor-CD3 complex on the cell surface still showed no difference in comparison with that of uninfected parent cells. After 16 weeks of HTLV-I infection, expression of T cell receptor-CD3 complex on HTLV-I-infected clone cells became decreased. This phenomenon is similar to the effect of HTLV-I infection on CD4+ cytotoxic T cells as we previously reported, and suggests that there are common mechanisms of declined cytotoxic activity mediated by both CD4+ and CD8+ cytotoxic T cells following infection with HTLV-I. Such functional alterations of cytotoxic effector cells might be one of the mechanisms underlying immunodeficiency caused by HTLV-I infection.

Functional heterogeneity among herpes simplex virus-specific human CD4+ T cells.

One hundred thirteen HSV-specific CD4+ T cell clones were established from the PBL of a healthy person and their functional heterogeneity was investigated. All clones proliferated in response to stimulation with HSV in the presence of autologous APC. Among those, 48 clones showed cytotoxic activity to HSV-infected autologous EBV-transformed lymphoblastoid cell line, but not to HSV-infected autologous fibroblasts, HSV-infected allogeneic cells, or K562 cells (group 1). Five clones showed cytotoxicity against HSV-infected autologous cells as well as HSV-infected allogeneic cells and K562 cells (group 2). The cytotoxicity of these clones was found to be mediated by the direct killing but not by the "innocent bystander" killing of target cells. Sixty clones showed no cytotoxic activity, however, among these, 23 revealed HLA-unrestricted and nonspecific cytotoxicity in the presence of PHA in culture (group 3), and the remaining 37 did not show any cytotoxic activity even in the presence of PHA (group 4). The cytotoxic patterns of these clones did not change in activated and resting phases, suggesting that the difference in cytotoxic ability does not depend on cell cycles. The cytotoxic activity of group 1 was inhibited by addition of anti-HLA-DR or anti-CD3 mAb to the culture, whereas these mAb had no effect on the cytotoxicity of group 2. All four groups of clones had helper activity for anti-HSV antibody production by autologous B cells. Moreover it was found that all groups of clones simultaneously produced IL-2, IL-4, and IFN-gamma after culture with APC followed by HSV Ag stimulation. The surface phenotype of all clones was uniformly CD2+, CD3+, CD4+, CD8-, CD29+, CD45RA-, but expression of Leu 8 was varied. These data therefore indicate that HSV-specific human CD4+ T cells are classified into at least four groups according to the presence and specificity of cytotoxicity, i.e., Th cells with HSV-specific and HLA-class II-restricted cytotoxicity, Th cells with HLA-unrestricted and nonspecific cytotoxicity, Th cells with lectin-dependent cytotoxicity, and Th cells without cytotoxic activity. The present finding of functional heterogeneity among virus-specific human CD4+ T cells might shed light on the pathogenesis of CD4+ T cell immunodeficiency, such as human retrovirus infections.

Differential in vitro activation of CD4+CD8- and CD8+CD4- herpes simplex virus-specific human cytotoxic T cells.

In order to clarify the differential activation of CD4+ and CD8+ HSV-specific CTL, we compared the characteristics of CTL generated by different methods of in vitro HSV stimulation by treatment of effectors with anti-CD4 and anti-CD8 mAb and C after the elimination of nonspecific cytotoxic effector cells. Cell-free HSV mainly activated CD4+ CTL precursors, whereas HSV-infected fibroblasts were more effective in activating CD8+ CTL precursors than CD4+ CTL precursors. In addition, limiting dilution analyses with enriched T cells from two HSV-seropositive donors revealed that the frequency of HSV-specific CD4+ CTL precursors responsive to stimulation with free HSV was approximately 1/4,000 to 6,000 CD4+ T cells, whereas that of precursors responsive to stimulation with HSV-infected fibroblasts was approximately 1/19,000 to 22,000 CD4+ T cells. Conversely, the frequency of CD8+ CTL precursors in peripheral blood responsive to stimulation with free HSV was approximately 1/28,000 to 30,000 CD8+ T cells, whereas that of precursors responsive to stimulation with HSV-infected fibroblasts was approximately 1/10,000 to 11,000 CD8+ T cells. The present data suggest that generalized viral infection due to cell-free viruses is fought mainly by CD4+ CTL, which have previously been reported to possess both cytotoxicity and helper function, and that localized viral infection on HLA class II-negative fibroblasts is prevented from spreading to adjacent cells mainly by CD8+ CTL. Such differential activation of CD4+ and CD8+ CTL seems probable when considering the protective mechanisms against viral infection.

Functional alterations of herpes simplex virus-specific CD4+ multifunctional T cell clones following infection with human T lymphotropic virus type I.

In an attempt to understand the mechanisms of immunodeficiency induced by human T lymphotropic virus type I (HTLV-I), HSV-specific CD4+ human multifunctional T cell clones were infected with HTLV-I in vitro. Early after HTLV-I infection, when their growth was still IL-2-dependent, clones were found to have almost completely lost their cytotoxic activity. At that time, their HSV-Ag-induced proliferative response and helper function for anti-HSV antibody production by B cells were only partially impaired. After this initial phase, the HTLV-I-infected clone became IL-2-independent, and the helper function was also completely lost. IL-2-dependent HTLV-I-infected clones showed degrees of proliferative response and elevation of intracellular free Ca2+ concentration induced by anti-CD3 mAb equivalent to those of HTLV-I-uninfected clones. On the other hand, during the IL-2-independent stage, expression of CD3-TCR complex on the cell surface was markedly decreased, and no significant elevation of intracellular free Ca2+ concentration was detected in response to anti-CD3 mAb. These data indicated that the loss of cytotoxic activity of HSV-specific T cell clones observed early after HTLV-I infection was not the result of impaired antigen recognition via the CD3-TCR complex, but might be due to dysfunction in the effector phase. On the other hand, the dysfunction of helper activity found late after HTLV-I infection might have mainly occurred in the recognition phase due to the decreased expression of CD3-TCR complex. The present data appear to suggest certain aspects of the pathogenesis of the immunodeficiency occurring in HTLV-I infection.

Age- and sex-specific cumulative rate and risk of ATLL for HTLV-I carriers.

We have surveyed the incidence of adult T-cell leukemia/lymphoma (ATLL) in an endemic area of 290,464 inhabitants for 7 years. We now revise our previous results on the basis of additional findings and estimate the age- and sex-specific cumulative rate for HTLV-I carriers, the adoption of which is recommended by current cancer epidemiology as a new age-standardized incidence rate. An unequivocal age-dependent increase in seroprevalence was observed for both sexes with a characteristic predominance in females. The age-dependent seroconversion in females may be partly explained by additional infection from infected husbands to their wives but the reason for men remains obscure. The mean annual number of incident cases of ATLL was 11.4, giving 3.9 ATLL patients annually per 10(5) inhabitants, 6.1 per 10(5) inhabitants aged over 30, and 85.0 per 10(5) seropositives aged over 30. Crude annual incidence rate of ATLL among 10(5) male seropositives aged over 30 was 145.3 and that for females was 55.2 and 95% confidence intervals of ATLL incidence rates were 34.8 to 255.7 for males and 6.4 to 104.1 for females, respectively. Although the sex ratio of 80 ATLL patients was 1.35, males are more prone to the disease (46 male patients among 4,522 male seropositives aged over 30 vs 34 female patients among 8,801 female seropositives aged over 30; p less than 0.001) for unknown reason(s). Morbidity in male seropositives aged over 30 is 2.6 times as high as that of females. Decennial incidence rates in males in their fifties and sixties were significantly higher than those in females. The remarkable male preponderance in oncogenicity of HTLV-I may be due to the fact that men are more prone to the disease and the number of female carriers in the denominator used to calculate the incidence rate is larger than that of males. The whole life span (0-79) cumulative risk for males was 6.9% and significantly higher than that of females (2.95%).

Multiphenotypic lymphoma with rearrangements of the T cell receptor beta chain and gamma chain genes.

A case of chemotherapy-resistant non-Hodgkin's lymphoma simultaneously expressing T cell (CD7)-, B cell (CD19)- and myeloid (CD13, CD33)-associated surface antigens is presented. Cytochemical analysis revealed that the lymphoma cells were positive for terminal deoxynucleotidyl transferase, but negative for myeloperoxidase and esterase. Rearrangements of both the T cell receptor beta chain and gamma chain genes were observed, but the immunoglobulin genes showed a germ line configuration. The rearrangement was not detected within the breakpoint cluster region on chromosome 22. These findings are considered to represent aberrant expressions of the B cell- and myeloid-associated antigens in early-stage T cell lineage lymphoma cells.

Antigen presentation in an HLA-DR-restricted fashion by B-cell chronic lymphocytic leukemia cells.

The ability of B-cell chronic lymphocytic leukemia (B-CLL) cells to present antigen to antigen-specific T cells was investigated. B-CLL cells present herpes simplex virus (HSV) antigen and purified protein derivative (PPD) to HSV- and PPD-specific, interleukin-2-dependent T-cell lines in an antigen-specific manner. Treatment of B-CLL cells with the phorbol ester 12-O-tetradecanoylphorbol-13-acetate (TPA) induced markedly increased levels of HLA-DR expression. TPA-treated B-CLL cells showed substantially more effective presentation, especially at low antigen concentrations, than did untreated B-CLL cells. By coculturing different allogeneic combinations of B-CLL cells and T cells and by adding anti-HLA-DR monoclonal antibody to cultures, it was found that antigen presentation by B-CLL cells was restricted by HLA-DR in the same way as for macrophages. We concluded from these experiments that B-CLL cells have a capacity to serve as antigen-presenting cells in an HLA class II-restricted fashion and that increasing the amount of HLA class II antigen and activation of B-CLL cells resulted in effective antigen presentation.

Helper activity in antigen-specific antibody production mediated by CD4+ human cytotoxic T cell clones directed against herpes simplex virus.

Three HSV type 1 (HSV-1) and HSV type 2 (HSV-2) common ("HSV-type common") and three HSV-1 specific CTL clones, which were CD3+, CD4+, CD8-, 4B4+, and 2H4-, were established. These clones proliferated in response to stimulation with HSV in the presence of autologous APC. The HSV type specificity of the proliferative response was identical with that of the cytotoxic activity of the clones. The cytotoxic activity and the proliferative response were both inhibited by addition of anti-HLA-DR mAb to the culture. After culture of these CTL clones with autologous B cells and macrophages followed by HSV Ag stimulation, anti-HSV antibody was detected in the culture supernatant. The HSV type specificity of the helper function for antibody production was identical with that of the cytotoxicity, i.e., HSV-type common clones, upon stimulation with either HSV-1, or HSV-2, and HSV-1-specific clones, upon stimulation with HSV-1 but not with HSV-2, showed helper activity for anti-HSV antibody production by autologous B cells. Moreover, it was found that these clones produced humoral factors which help autologous B cells to produce antibody. The helper factors were produced by T cell clones in an HSV-type-specific manner. These data suggest that some CD4+ T cells can simultaneously manifest both specific cytotoxicity and helper activity for Ag-specific antibody production by B cells, and that these multifunctional T cells might play an important role in protection against viral infection.

Expression of CD9 (p24) antigen on hematopoietic cells following treatment with phorbol ester.

Expression of the leukemia-associated cell surface antigen p24 (CD9) on human hematopoietic cell lines and B-cell chronic lymphocytic leukemia (B-CLL) cells was analyzed before and after treatment with the phorbol ester 12-o-tetradecanoyl-phorbol 13-acetate (TPA). Little or no expression of CD9 was detected in any of the cell lines used or in B-CLLs before treatment with TPA. After exposure to TPA, HL-60, Epstein-Barr virus-immortalized B-cell lines, Molt-3, MT-2 and B-CLLs showed markedly augmented CD9 expression. U937 and K562 showed slight increases of CD9 expression. However, no expression of CD9 was induced in CCRF-CEM or HUT-102. Although CD9 is known to be one of the most useful markers of pre-B-cell common acute lymphoblastic leukemia, the expression of CD9 does not seem to be restricted to any specific cell lineage and can be induced in various hematopoietic cell lineages by treatment with TPA.