Tumor necrosis factor production in patients with leprosy.

The spectrum of host responses to Mycobacterium leprae provides a model for investigating the role of cytokines in the pathogenesis of mycobacterial disease. Of particular interest is tumor necrosis factor (TNF), a cytokine which may have both antimycobacterial and immunopathologic effects. To evaluate the potential role of TNF in leprosy, we measured TNF production in response to M. leprae and its defined constituents by peripheral blood mononuclear cells from patients across the spectrum of disease. The levels of TNF induced through the stimulation of cells with M. leprae or its dominant "lipopolysaccharide," lipoarabinomannan, were higher in patients with the tuberculoid form of the disease than in those with the lepromatous form. In patients with erythema nodosum leprosum (ENL), a reactional state of lepromatous leprosy, the levels of TNF release by peripheral blood mononuclear cells were higher than in any other form of the disease. Treatment of ENL patients with thalidomide reduced TNF secretion by more than 90%. The mycolylarabinogalactan-peptidoglycan complex of Mycobacterium species, the protein-peptidoglycan complex, and muramyl dipeptide all elicited significant TNF release. Therefore, TNF release appears to be triggered by at least two major cell wall structural constituents of M. leprae, lipoarabinomannan and segments of the cell wall skeleton. The prominent TNF release in patients with the paucibacillary tuberculoid form of the disease compared with that in patients with the multibacillary lepromatous form suggests that this cytokine contributes to a resistant immune response to mycobacterial infection. However, the marked TNF release in patients with ENL indicates that TNF may also mediate immunopathologic effects, such as fever and tissue damage.     

Studies on T cell subsets and functions in leprosy.

T cell subsets and T cell functions were explored in 31 leprosy patients with the following methods: determination of the percentages of the different T cell subpopulations defined by monoclonal antibodies directed at total T cells, helper T cells and suppressor/cytotoxic T cells; measurement of the in vitro proliferative responses to mitogens; study of the concanavalin A-induced suppressive activity, assessed on MLC; measurement of delayed-type hypersensitivity by skin testing. The confrontation between immunological lepromatous patients without type-2 reaction (erythema nodosum leprosum), (2) lepromatous patients without ENL (erythema nodosum leprosum), (2) lepromatous patients was recent ENL and (3) tuberculoid patients. Unexpectedly, groups 1 and 3, although differing strongly in their clinical status and their sensitivity to lepromin (absent in group 1 and strong in group 3), showed a similar immunological profile with a normal percentage of T cells and a normal distribution of T cells among the major T cell subset contrasting with a moderate decrease of proliferative responses to mitogens and impaired delayed-type hypersensitivity reactions. Concanavalin A-induced suppressive activity was type-2 reaction) strongly differed from both other groups, showing striking abnormalities other groups, showing striking abnormalities of the repartition of the T cell subsets, with increased percentages of helper T cells and decreased percentages of suppressor T cells, and elevated proliferative responses to mitogens. Concanavalin A-induced suppressive activity was reduced in most patients of this group. It is suggested that this imbalance between T cell subsets contributes to the occurrence of ENL reactions in lepromatous patients.     

Studies on the Defect in Cell-Mediated Immunity in Lepromatous Leprosy using HLA-D-Identical Siblings

Sixteen healthy siblings were identified as HLA-D-identical to 12 borderline lepromatous or polar lepromatous leprosy patients by the absence of a mixed lymphocyte reaction (MLR). The peripheral blood mononuclear cells (PBM) of the healthy siblings showed a lymphoproliferative response (delta cpm) to Mycobacterium leprae antigens which was about fivefold or more greater than that of the lepromatous patients. Lepromatous PBM, with or without mitomycin C treatment, were co-cultured with a constant number of normal PBM. In other experiments the two cell types were co-cultured in various proportions, with the total cell number kept constant. Neither approach revealed suppressor cells in lepromatous PBM capable of suppressing the lymphoproliferative response to M. leprae. On the contrary, we found that lepromatous PBM can respond to M. leprae antigens if the sensitized lymphocyte is provided by mitomycin-C treated normal PBM. Additionally, experiments in which isolated adherent cells and non-adherent cells of sibling pairs were recombined failed to reveal a defect in the M. leprae antigen-presenting function of lepromatous adherent cells. Since we found no evidence that sensitized cells are present in lepromatous PBM with their function unexpressed (due to a monocyte defect) or suppressed (due to suppressor cells), we conclude that lepromatous patients simply lack sufficient numbers of antigen-specific T lymphocytes to initiate a lymphoproliferative response to M. leprae antigens. The reason for their absence remains an important unanswered question.     

C-reactive protein and apoB containing lipoproteins are associated with Mycobacterium leprae in lesions of human leprosy.

Skin biopsies from patients with leprosy across the spectrum from tuberculoid (TT) to lepromatous (LL), including histoid lepromas and erythema nodosum leprosum (ENL) reactions, were stained immunohistochemically for the presence of C-reactive protein (CRP) and the apolipoprotein, apoB. Mycobacterium leprae bacillary material comprising cell walls, cytoplasmic and soluble components was present with increasing abundance towards the lepromatous end of the spectrum and always stained positively with anti-CRP. M. leprae from armadillos did not stain with anti-human CRP indicating that the staining of M. leprae in human tissues was not due to a cross-reaction between anti-CRP and the organism itself. When CRP was present in large amounts apoB was also demonstrated in the same distribution. CRP was detected on bacilli and their degradation products within the cytoplasm of macrophages even in the absence of a raised serum CRP level in some ENL patients and also in two cases of advanced resolving lepromas. These findings demonstrate remarkable persistence of CRP in association with M. leprae in vivo, and raise intriguing questions about the possible role of CRP in relation to the handling of leprosy bacilli.     

Thalidomide Does not Perturb Cd2, Cd4, Cd5, Cd8, Hla-Dr, or HLA-A, B, C Molecules in Vitro on the Membranes of Cells with Immune Potential

Thalidomide dramatically relieves the signs and symptoms of erythema nodosum leprosum (ENL). ENL is an acute inflammatory complication of lepromatous leprosy. the cause(s) of ENL as well as the mechanism of action of thalidomide in arresting ENL are unknowns.

It has been suggested that ENL is the consequence of a transient activation of a cell-mediated-immune (CMI) response to Mycobacterium leprae. to initiate a CMI response, an interaction between adhesion and/or signal transducing molecules on T-cells and molecules on antigen presenting cells would occur. An alteration, induced by thalidomide, of one or more of the molecules on T-cells or antigen presenting cells that are essential to maintaining the reactive state of ENL, could explain Thalidomide's ability to attenuate ENL.

Thalidomide did not modify: (a) adhesion and/or signal transducing molecules such as CD2, CD4, CD5 and CD8, or (b) molecules that facilitate antigen presentation such as HLA-DR, HLA-A, HLA-B, or HLA-C.     

Polymorphonuclear cell function in the various polar types of leprosy and erythema nodosum leprosum.

Polymorphonuclear leukocyte motility, both in vivo and in vitro, and reduction of Nitro Blue Tetrazolium was studied in tuberculoid and lepromatous leprosy patients and a group of lepromatous patients with erythema nodosum leprosum (ENL). A profound defect in random migration, chemotaxis, and chemokinesis was found in lepromatous patients with and without complicating ENL, and marked depletion of skin window migration confirmed these in vitro findings. Tuberculoid patients exhibited a mild defect in polymorphonuclear leukocyte motility. Serum inhibitors of normal polymorphonuclear leukocyte chemotaxis were found in all types of leprosy, but sera from lepromatous and ENL patients were most inhibitory. Resting levels of Nitro Blue Tetrazolium reduction were normal in all three groups. Reconstitution of polymorphonuclear leukocyte cells from normal and ENL patients with ENL serum, however, showed increased Nitro Blue Tetrazolium reduction well above the normal range, whereas reconstitution with normal, lepromatous, and tuberculoid sera failed to increase Nitro Blue Tetrazolium reduction above the normal values.     

Natural emergence of antigen-reactive T cells in lepromatous leprosy patients during erythema nodosum leprosum.

Fifteen lepromatous leprosy (LL) patients undergoing erythema nodosum leprosum (ENL) reactions were compared with 13 stable, uncomplicated, anergic individuals of the same leprosy background. ENL patients showed significant antigen-induced leukocyte migration inhibition (migration index = 0.058 +/- 0.01), paralleling the values obtained with a responder tuberculoid leprosy population (migration index = 0.04 +/- 0.004). Both phytohemagglutinin-induced general T-cell proliferation and, more significantly, antigen-induced lymphoproliferation were enhanced during the acute phase of the reaction. Suppressor cell activity, monitored by a costimulant assay, showed enhanced antigen-stimulated suppression of mitogen responses. Interestingly, the improvement in in vitro T-cell responses was not reflected in dermal reactivity, since 48-h delayed-type hypersensitivity responses after intradermal injection of soluble Mycobacterium leprae antigens continued to be poor. After subsidence of reactional lesions, leukocyte migration inhibition, lymphoproliferation, and suppressor cell activity were reduced to the unresponsive state seen in stable LL patients. Significantly, perturbations of T-cell reactivity are detectable in ENL reactions, indicating the natural but transient emergence of antigen-induced T cells in LL.     

Reduced suppressor cell response to Mycobacterium leprae in lepromatous leprosy.

We have previously shown that concanavalin A (ConA) induction of suppressor cell activity is impaired in patients with lepromatous leprosy (LL). In this study, we demonstrated that the proportion of cells bearing the Leu8 antigen (associated with suppressor-inducer cells) is low in LL patients and tends to normalize during the erythema nodosum leprosum (ENL) episode. Antigen-induced suppressor cell function was evaluated by a two-stage assay. In the first stage, peripheral blood mononuclear cells (PBMC) were cultured for 5 days either in the presence of gamma-irradiated Mycobacterium leprae or in tissue culture medium as a control. In the second stage, mitomycin C-treated suppressor or control cells were added to phytohemagglutinin (PHA)- or ConA-stimulated autologous PBMC. The results indicate that the ability of M. leprae to induce suppressor activity was lower in LL patients than in patients with tuberculoid (TT) and intermediate clinical (BB, BL, BT) forms and Mycobacterium bovis BCG-immunized normal controls. In ENL patients, the percent suppression was between that of TT and normal individuals. M. leprae-induced suppression was more effective on ConA- than on PHA-triggered T-cell proliferation in all groups. In contrast, normal PBMC cultured for 5 days in RPMI 1640 medium (N-C) and cells from patients with leprosy (TT-C and LL-C) had effects of their own on PHA- or ConA-induced proliferation. LL-C depressed the response to ConA and enhanced PHA-induced proliferation of autologous cells. Conversely, TT-C reduced PHA-induced proliferation and increased the ConA response. Suppression of proliferation could not be overcome with exogenous interleukin-2 and was not related to the induction of the Tac antigen. The abilities of LL, TT, ENL, and normal cells to proliferate upon PHA or ConA stimulus were similar, indicating that the defect in the generation of in vitro suppression by M. leprae in LL patients occurred during the induction period (step 1 of assay).     

Sera of leprosy patients with type 2 reactions recognize selective sequences in Mycobacterium leprae recombinant LSR protein.

Type 2 reactions (erythema nodosum leprosum [ENL]) are episodic, reactional states causing significant morbidity in lepromatous leprosy patients. With a view to defining the immunological differences between the stable and reactional forms of lepromatous leprosy, we determined antibody responses to LSR, a recombinant protein of Mycobacterium leprae previously described by us (S. Laal, Y.D. Sharma, H.K. Prasad, A. Murtaza, S. Singh, S. Tangri, R. S. Mishra, and I. Nath, Proc. Natl. Acad. Sci. USA 88:1054-1058, 1991), as well as to 10- to 15-mer overlapping peptides synthesized on the basis of the LSR amino acid sequence. We report here the selective recognition of B cell epitopes by sera from patients with ENL as compared with a control group with nonreactional lepromatous leprosy. Peptides 2 and 3, with the sequences GVTYEIDLTNKNAA and IDLTNKNAAKLRGD, respectively, were recognized by > 95% of sera from patients with active ENL. Peptide 3 in addition showed reactivity with sera taken from 91.6% of lepromatous leprosy patients who were apparently stable but who were recorded to have had ENL several weeks before or after the sample collection. The core sequence IDLTNKNAA common to both these peptides may be a major target of humoral responses in ENL. In addition, the RGD motif at the C terminus appeared to influence the antigenicity of peptide 3 in enzyme-linked immunosorbent assay. It would appear that humoral responses during ENL are directed to selective antigenic determinants of the leprosy bacillus. The use of such serological markers to identify lepromatous leprosy patients with a high risk for developing ENL would be of clinical and predictive value.     

Autoantibodies in lepromatous leprosy

Lepromatous leprosy patients often develop erythema nodusum leprosum (ENL) reactions mainly during treatment of the disease. Hence, this study sought to investigate correlation between the prevalence of certain autoantibodies and ENL reactions in these patients. The patients included in the study were fifty patients with lepromatous leprosy and a similar number of normal controls. Sera were collected from the patients and normal controls and the prevalence of circulating rheumatoid factor antinuclear and antismooth muscle antibodies was determined. The prevalence of autoantibodies was increased in lepromatous leprosy as compared with normal controls. The prevalence of these autoantibodies were affected differently by the ENL reactions. ENL lepromatous leprosy showed a slight decrease in prevalence of antinuclear and antismooth muscle antibodies, whereas there was a slight increase in the prevalence of rheumatoid factor in ENL lepromatous leprosy. The levels of serum immunoglobulins tended to show a decline towards ENL lepromatous patients compared with the uncomplicated lepromatous patients. The significance of these finding is discussed in relation to their possible role in the pathogenesis of ENL reaction. It is concluded that some of these autoantibodies and immunoglobulins may be utilized during ENL reactions in the formation of immune complexes.     

Cellular immunity in lepromatous and tuberculoid leprosy

The depression of cellular immunity in lepromatous patients is not understood. While the blood monocytes of leprosy patients appear to be activated normally by lymphokines, T cell proliferation and production of lymphokines in response to Mycobacterium leprae are impaired in lepromatous patients. Attempts to restore responsiveness in cells from these patients have been unsuccessful in our hands. The addition of exogenous IL-2 to leukocyte cultures does not appear to restore responsiveness to M. leprae in cells from nonresponder patients. Rather, some enhancement, often not antigen specific, is observed in cells from patients with a preexisting response. Similarly, depletion of monocytes does not restore responsiveness to M. leprae in non-responder patients, but a nonspecific enhancement of proliferation is observed in monocyte-free cultures from patients that do respond to M. leprae. Thus, the defect in lepromatous non-responder patients does not result from a simple lack of IL-2 production or suppression by monocytes and/or their products. Possibly, there is a low level or lack of M. leprae responsive T cells in the circulation of these patients.     

Mechanism of immunosuppression in leprosy: presence of suppressor factor(s) from macrophages of lepromatous patients.

Human peripheral blood mononuclear cell proliferation induced by Mycobacterium leprae could be inhibited by the suppressor factor in the lysate of the macrophages of lepromatous leprosy patients. Macrophages from normal subjects and tuberculoid patients did not show production of a suppressor factor. Inhibition occurred only when the factor was present in the initial stages of lymphocyte culture. The factor is heat stable and nondialyzable. Proliferation induced by some mycobacteria and concanavalin A could also be blocked by the factor. Interestingly, blastogenic response by a few other antigens and phytohemagglutinin could not be inhibited by the suppressor factor. Mononuclear cells pretreated with such lysate from lepromatous macrophages for 24 h could induce suppressive activity in the cells in vitro in an autologous system. Treatment of these cells with carbonyl iron after the induction phase, to remove phagocytic cells, did not abolish their suppressive activity. The lepromatous macrophage lysate also generated suppressive activity in a T-lymphocyte-enriched population of normal subjects. These studies are interpreted to indicate that immunosuppression in lepromatous patients is produced by both macrophages and T lymphocytes. The exact phase in which either of these cells acts as a suppressor may be different. Specific suppression by macrophages to M. leprae can be an early event, and nonspecific suppression by T lymphocytes may be a later event in the course of lepromatous leprosy.     

A transient rise in agalactosyl IgG correlating with free interleukin 2 receptors, during episodes of erythema nodosum leprosum.

The proportion of oligosaccharide chains on the Fc fragment of IgG which terminate with N-acetylglucosamine and not galactose (%GO) has previously been shown to be raised in rheumatoid arthritis (RA), Crohn's disease (CD) and tuberculosis (Tb), but to be normal in sarcoidosis (SA), and in both lepromatous and tuberculoid leprosy. However we have now studied %GO in sequential serum samples collected from lepromatous leprosy patients undergoing episodes of erythema nodosum leprosum (ENL). During ENL %GO is transiently raised, and this rise parallels an increase in circulating interleukin 2 receptors (IL-2R). These findings confirm that changes in T cell function occur during ENL. Moreover it appears that %GO rises when there is, simultaneously, T-cell-mediated tissue damage and an acute phase response (RA, CD, Tb, ENL), but not when there is an acute phase response without major T cell involvement, or chronic T cell activity alone (SA, and tuberculoid leprosy). We suggest therefore that %GO is an indicator of a type of T cell activity with broad immunopathological implications.     

In situ characterization of T lymphocyte subsets in the reactional states of leprosy.

Using monoclonal antibodies and the immunoperoxidase technique, the numbers and distribution of T lymphocyte subsets in the tissues of reactional states of leprosy (six reversal reaction, nine erythema nodosum leprosum (ENL) and two Lucio's reaction) were determined and compared with those found in stable, non-reactional patients (six tuberculoid, two borderline lepromatous and seven lepromatous). The pattern of segregation of the suppressor/cytotoxic phenotype at the periphery of the granuloma was found in both non-reactional tuberculoid lesions and reversal reactions, but was better developed in the former. In ENL and Lucio's reaction, as well as in non-reactional lepromatous tissue, the helper/inducer and suppressor/cytotoxic phenotypes were both admixed with the aggregated histiocytes. However, the helper/suppressor ratio in ENL (2.1 +/- 0.4) was significantly larger than that in non-reactional lepromatous tissue (0.7 +/- 0.4, P less than 0.001). The immature thymocyte antigen OKT6 was found on scattered large non-lymphoid cells, most commonly in tuberculoid and reversal reaction tissues, less commonly in ENL, but only irregularly in non-reactional lepromatous tissue. The peripheral pattern of the suppressor/cytotoxic phenotype may be an immunohistological reflection of a cell-mediated immune response common to both non-reactional tuberculoid and reversal reaction patients. The reversal of the helper/suppressor ratio in ENL as compared to non-reactional lepromatous disease suggests some role for cell-mediated immunity in the pathogenesis of ENL. The OKT6 positive cell is of unknown origin and function.     

Lack of cytotoxic activity against Mycobacterium leprae 65-kD heat shock protein (hsp) in multibacillary leprosy patients.

Cytotoxic T cells play an important role in host defence mechanisms, as well as in the immunopathology of leprosy. In this study, we evaluated whether Mycobacterium leprae hsp18, hsp65 and Myco. tuberculosis hsp71 could induce cytotoxic T cell activity against autologous macrophages pulsed with these hsp. Paucibacillary (PB) patients and normal controls generated more effector cells than multibacillary (MB) patients with all three hsp tested. There was no cross-reactivity between any of the hsp tested. Mycobacterium leprae hsp65 induced cytotoxic responses only in those MB patients undergoing an erythema nodosum leprosum (ENL) episode. Although hsp65 and hsp18 induced similar proliferation in MB patients, a high proportion of these patients did not generate cytotoxic effector cells in response to hsp65. Hence, those T cells reacting to hsp65 may play an important role in the control of Myco. leprae infection.     

Evidence for the presence of M. leprae reactive T lymphocytes in patients with lepromatous leprosy.

Evidence for the presence of Mycobacterium leprae reactive T cells in many lepromatous leprosy (LL) patients was obtained using in vitro antigen-induced lymphoproliferative responses. (1) Co-cultures of T enriched cells from LL patients when combined with 2 h adherent cells (AC) from HLA-D compatible tuberculoid leprosy individuals showed significant levels of 3H-thymidine incorporation in the presence of soluble and integral M. leprae antigens. (2) More interestingly, autologous T cell + AC co-cultures also showed significant improvement in antigen-induced lymphoproliferation in nine of 16 lepromatous patients. Insignificant improvement was observed in similar co-cultures of tuberculoid leprosy patients. (3) Addition of exogenous, purified human interleukin-2 (IL-2) to antigen stimulated PBMC from some lepromatous patients showed the best improvement in terms of overall 3H-thymidine incorporation, indicating that lepromatous patients possess T cells which can differentiate to an IL-2 responsive state. Significantly, the level of proliferation varied within the group. A proportion of clinically similar lepromatous patients failed to show improvement by any of the above methods.     

Expression of major histocompatibility complex class I and class II antigens in human Schwann cell cultures and effects of infection with Mycobacterium leprae

Recent experiments on rats have raised the possibility that Schwann cells can present antigens to T lymphocytes. We have investigated whether this mechanism might be relevant in leprosy by determining under what conditions human Schwann cells express class I and class II antigens, and whether infection with Mycobacterium leprae affects this expression. The distribution of these antigens was examined on human Schwann cells in dissociated cell cultures derived from human fetal peripheral nerves. We find that both Schwann cells and fibroblastic cells in these cultures normally express class I antigens but not class II antigens. When Schwann cells are infected with live Mycobacterium leprae for 48 h, 73% of Schwann cells phagocytose the bacteria. Mycobacterium leprae prevents 3H-thymidine incorporation into cultured human Schwann cells, but does not affect class I expression in these cells. Treatment of normal and Mycobacterium leprae infected cultures with gamma-interferon for 72 h induces class II expression on most Schwann cells but not on the majority of fibroblastic cells. The fact that human Schwann cells infected with Mycobacterium leprae can be induced by gamma-interferon to express class II antigens suggests that they may be able to present Mycobacterium leprae antigens to T lymphocytes and thus initiate immune responses against the bacteria. We suggest that a failure of this response, such as that seen within nerve trunks in lepromatous leprosy, is caused by deficient class II expression on Schwann cells. This deficiency in class II expression, in turn, may be caused by the reduced gamma-interferon production characteristic of lepromatous leprosy.     

The role of macrophages in the lymphoproliferative response to Mycobacterium leprae in vitro.

Peripheral blood lymphocytes from patients suffering from lepromatous leprosy do not normally react in vitro to stimulation by Mycobacterium leprae antigens. In contrast, we found that T cells from non-responding patients in combination with macrophages from responding patients or healthy contacts did respond well to M. leprae. Conversely, T cells from responding patients or healthy contacts in combinations with macrophages from non-responding patients failed to respond. It seems, therefore, that the lack of response normally observed in in vitro tests using cells from lepromatous leprosy patients is due to a failure of their macrophages to present M. leprae antigens in an immunogenic form.     

CD2 expression and function in lepromatous leprosy.

Leprosy is a spectral disease in which clinical presentation is thought to be related to the host immune response. Previous investigations have suggested that selective unresponsiveness to Mycobacterium leprae in patients with lepromatous leprosy is due to the presence of M. leprae-specific T-suppressor cells. However, it has recently been suggested that CD2 modulation was the mechanism for the observed impaired immune response in lepromatous patients. Therefore, we studied the expression of CD2 and CD3 on lymphocytes in lepromatous skin lesions and peripheral blood mononuclear cells (PBMC). Using immunohistochemical techniques, we found that virtually all of the CD3+ cells in leprosy skin lesions expressed CD2. In addition, indirect immunofluorescence flow cytometry demonstrated that most CD3+ cells in the peripheral blood possessed the CD2 marker, suggesting that CD2 expression of T-lymphocytes is normal. T-cell activation using paired anti-T11(2) and anti-T11(3) or anti-CD3 monoclonal antibodies demonstrated similar 3H-thymidine incorporation and gamma interferon production in the PBMC of lepromatous patients in comparison with the PBMC of their contacts and tuberculoid patients. However, lepromatous PBMC did not proliferate or produce gamma interferon in response to M. leprae. Our data suggest not only that CD2 expression is normal on T lymphocytes in lepromatous leprosy skin lesions but also that CD2 expression in peripheral blood lymphocytes is functional in T-cell activation. Defective CD2 modulation does not appear to be the mechanism for specific unresponsiveness in lepromatous leprosy.