Searching for the Cartilage-associated Mimicry Epitope in Adjuvant Arthritis

Adjuvant arthritis (AA) is a T cell mediated disease which can be induced in genetically susceptible rats by immunization with heat-killed Mycobacterium tuberculosis ( Mt ) suspended in incomplete Freund's adjuvant. The critical mycobacterial T cell epitope for the induction of AA was previously identified as residues 178-186 of the mycobacterial 65 kDa heat shock protein ( Mt. hsp65 178-186 ). It was suggested that the development of AA was due to molecular mimicry between a mycobacterial epitope and a cartilage-associated self-antigen. However, until now such cartilage-associated mimicry epitope has not been identified. In this study we designed a computer search profile to predict mimicry self-epitopes, and investigated whether one or more of these self-epitopes could serve as mimicry epitopes in AA. Although several of these self-epitopes were recognized by arthritogenic T cells, no cross-reactivity was found between T cells specific for these self-epitopes and Mt. hsp65 178-186 specific T cells.     

T cell reactivity to an epitope of the mycobacterial 65-kDa heat-shock protein (hsp 65) corresponds with arthritis susceptibility in rats and is regulated by hsp 65-specific cellular responses.

Adjuvant arthritis (AA) can be induced in genetically susceptible rats by immunization with heat-killed mycobacteria suspended in mineral oil. From our analysis of arthritogenic T cell clone A2b, obtained from an arthritic Lewis rat and specific for the 180-188 epitope of mycobacterial 65-kDa heat-shock protein (hsp 65), the possible origin of AA was explained by the existence of a molecular mimicry of the 180-188 epitope with a cartilage-associated self antigen. We now have shown that Lewis rats respond to the 180-188 epitope after Mycobacterium tuberculosis immunization and that arthritis-resistant Fisher and (Lewis x Fisher)F1 rats, although major histocompatibility complex class II identical with Lewis, do not respond to this epitope. However, in rare cases of arthritis in Fisher rats, responses to the epitope were seen. We obtained no evidence for a defect at the level of antigen processing and presentation or for suppression in Fisher rats. Thus, non-responsiveness in Fisher rats was likely due to a difference at the level of the T cell repertoire. Previously, we have reported that pretreatment with hsp 65 in experimental arthritis, and not only in AA, caused resistance to arthritis induction. We now present evidence that immunization with hsp 65 or in vitro stimulation with hsp 65 may lead to inhibition of responses specific for epitope 180-188. Thus the hsp 65-induced resistance to arthritis is probably caused by the induction of regulatory control specifically targeted at the 180-188 epitope. Especially in rats that tend to focus their responses on the critical 180-188 sequence, such as Lewis, regulation seems to develop following immunization with hsp 65. Since recent evidence suggests that hsp 65 and also the 180-188 epitope have a role in human arthritic conditions, the present findings are expected to contribute to further experimentation directed at exploiting hsp 65 or its epitopes for the development of new therapeutical approaches in humans.     

Modulation of adjuvant arthritis in Lewis rats by recombinant vaccinia virus expressing the human 60-kilodalton heat shock protein.

The immune response to the mycobacterial 65-kDa heat shock protein (hsp65) is considered an important event in the induction of adjuvant arthritis (AA) in rats; this induction probably occurs through a molecular mimicry mechanism involving cross-reactivity against the rat homolog hsp60. To analyze the role of mammalian molecule hsp60 in arthritis, we generated a recombinant vaccinia virus (hsp60-VV) carrying the human hsp60 gene inserted into the thymidine kinase locus under the control of the 7.5k vaccinia virus promoter. Human hsp60 is almost identical to its rat homolog (97.4% linear amino acid homology) and shares about 50% of amino acid positions with Mycobacterium tuberculosis hsp65. The latter supposedly carries a critical epitope for AA induction that is not present in human hsp60. Infections with hsp60-VV of monkey cell cultures led to the expression of the human hsp60 molecule, as evidenced by immunoblotting analysis with specific monoclonal antibodies. Also, Lewis rats infected with hsp60-VV produced specific antibodies, demonstrating the in vivo expression of human hsp60 in the infected animals. Therefore, we used hsp60-VV to analyze whether the delivery of hsp60 could affect the induction of AA in Lewis rats. hsp60-VV clearly reduced and retarded arthritic symptoms when administered to rats at day 7 after AA induction. In contrast, inoculation of rats with a control recombinant vaccinia virus did not affect the course of the disease. The improvement in AA with hsp60-VV administration was associated with a specific immune response, as determined by the presence of antibodies to hsp60 in the sera and the proliferation induced by hsp60 of T cells from popliteal lymph nodes. These results support a critical role for immunity to heat shock proteins in AA. Since the protective construct is virtually identical to rat homolog hsp60, we conclude that immunity directed to conserved areas of this family of proteins is directly involved in the pathogenesis of AA.     

Differential rat T cell recognition of cathepsin D-released fragments of mycobacterial 65 kDa heat-shock protein after immunization with either the recombinant protein or whole mycobacteria

T cells specific for the mycobacterial 65 kDa heat-shock protein(hsp65) play a pivotal role in the development of adjuvant arthritis(AA) in Lewis rats. Upon adoptive transfer, CD4⁺ T cells recognizinga particular hsp65 epitope trigger the onset of disease. Activationof hsp65-reactlve T cells can be achieved by immunization withheat-killed mycobacteria in mineral oil—complete Freund'sadjuvant (CFA)—or with purified recombinant hsp65. Arthritis,however, will only develop after immunization with CFA. In fact,prelmmunlzatlon with hsp65 protects against any subsequent attemptto induce AA. In this study, we examined polyclonal lymph nodecell responses in Lewis rats, Immunized with either CFA or purifiedrecombinant hsp65 in incomplete Freund's adjuvant, to a setof hsp65 fragments generated by a mild digestion with cathepsinD. Prollferatlve responses to several hsp65 fragments variedwith the type of antigen used for immunization. A cathepsinD-released fragment, Identified as residues 376–408, preferentiallytriggered proliferation of rat T cells after hsp65 Immunization.Prelmmunlzatlon of Lewis rats with this peptlde delayed theonset and reduced the severity of AA. Prelmmunlzatlon with anotherfragment which was preferentially recognized after CFA immunization,representing residues 40–60, did not have such a protectiveeffect. Our findings suggest the presence of mycobacterial hsp65determinants that selectively trigger AA-regulatlng T cellsand illustrate that cathepsin D may be used as an experimentaltool to generate such determinants.     

Peptide recognition, T cell receptor usage and HLA restriction elements of human heat-shock protein (hsp) 60 and mycobacterial 65-kDa hsp-reactive T cell clones from rheumatoid synovial fluid.

A commonly held postulate regarding the etiology of rheumatoid arthritis (RA) is that of antigenic mimicry. Recent interest has focused on the mycobacterial 65-kDa heat-shock protein (hsp) as a putative causal agent. The 65-kDa hsp has over 40% sequence homology with the human hsp 60, and elevated synovial T cell responses to both antigens have been demonstrated in RA and juvenile rheumatoid arthritis patients. Such T cells should, therefore, be specific for shared epitopes on the two antigens. To investigate this, we screened synovial fluid mononuclear cells from two early RA patients with peptides of the 65-kDa hsp which have the greatest homology with the human hsp 60. We also raised a panel of T cell clones from one of the patients with the 65-kDa hsp. The synovial T cell population from both patients and one of the T cell clones recognized a peptide representing the amino-acid sequence 241-255. This clone also responded to the peptide of the equivalent human sequence, and was restricted by HLA-DQ. A second T cell clone recognized an adjacent epitope (amino acid sequence 251-265) which is also highly homologous with the human sequence, but this clone was restricted by HLA-DR. The clones utilized different V beta gene segments but the same D beta and J beta gene elements, and both exhibited specific cytotoxicity against autologous antigen-pulsed macrophages. Our findings, therefore, do not disagree with the postulate that autoimmune disease could possibly be triggered by bacterial epitopes with homology to self protein. However, it is also noted that there are alternative interpretations of this data.     

Epitope specificity and MHC restriction of rheumatoid arthritis synovial T cell clones which recognize a mycobacterial 65 kDa heat shock protein.

CD4+ T cell clones specific for the mycobacterial hsp 65 were obtained from synovial fluid of a DR4 homozygous rheumatoid arthritis (RA) patient. A stimulatory epitope was defined using both deletion mutants of the mycobacterial hsp 65 and synthetic peptides and proved to be in a highly conserved region of the molecule. Despite this, however, there was no recognition by these clones of either the recombinant human homologue of mycobacterial hsp 65, P60, nor of a synthetic peptide containing an amino acid sequence from P60 corresponding to the epitope defined in the mycobacterial hsp 65. When the pattern of HLA restriction shown by the hsp-65-specific T cell clones was investigated, all clones tested proved to be restricted by HLA-DP rather than the more usual HLA-DR. Inhibition experiments suggested that this restriction also applied to the polyclonal synovial T cell response to hsp 65, but not to other antigens. Exclusive restriction of T cell recognition of an antigen by HLA-DP has not been reported previously, and strongly suggests that in this case the T cell repertoire for recognizing hsp 65 in the context of DR4 is deficient. Such an association between DR4 and the inability to respond to an immunodominant bacterial antigen may have implications for the pathogenesis of RA.     

Heat-shock protein T-cell epitopes trigger a spreading regulatory control in a diversified arthritogenic T-cell response

Summary: Adjuvant arthritis (AA) in Lewis rats is T-cell mediated and seems to depend on T cells recognising the 180–188 epitope of mycobacterial heat-shock protein (hsp) 60. Analysis of arthritogenic T-cell clone A2b has revealed a mimicry of this particular epitope with an articular cartilage-associated target T-cell epitope. Nasal administration of synthetic peptides covering this 180–188 sequence led to epitope-.specific tolerance and resistance to AA. Since this tolerisation protocol also inhibited avridine arthritis, one may conclude that this form of epitope-specific tolerance had effectuated a spreading tolerisation at the level of target antigens that included a diverse set of possible arthritis -associated antigens. In vitro anergised T cells exhibited suppressive activity in a co-culture system. As in this case - depending on the presence of the antigen of the anergic T cell – such T cells suppressed responder T cells of a different antigenic specificity, we postulated that anergic T cells may be responsible for a spreading of tolerance. It seemed that such spreading of tolerance was channelled through the antigen-presenting cells (APC) and was dependent on direct cell-cell contact. This and additional forms of spreading of tolerance could be responsible for specific nasal tolerance, causing inhibition of the development of an arthritogenic inflammatory response. This can be similarly che case for the arthritis protection that resulted from immunisation with hsps. Analysis of T-cell responses following hsp immunisations revealed that the arthritis inhibitory activity resided in T cells with specificity for a conserved part of microbial hsp60. The same T cells cross-responded to rat self-hsp60. Low level expression of the latter molecule on non-professional APC could possibly have induced a suppressive anergic state in these autoreactive cells. Thus, immunisation with microbial hsp would have led to an expansion of such T cells, leading to raised disease-suppressive potential when selectively trapped and activated in the inflamed self-hsp-overexpressing joint. Alternatively the cross-recognised self-hsp epitope could have the regulatory qualities of an altered peptide ligand or a partial agonist for T cells that see the microbial homologue as the full agonist.     

Cross-reactive mycobacterial and self hsp60 epitope recognition in I-A(g7) expressing NOD, NOD-asp and Biozzi AB/H mice

The highly conserved 60 kD endogenous heat shock protein (hsp60) has been suggested to be a target for T cell recognition in autoimmune diseases such as type I diabetes. We previously reported cross-recognition of both mycobacterial hsp60 (Mt60) and self hsp60 (m60) by Mt60 immunized NOD mice. To identify the epitopes involved, we generated T cell lines against m60 or its mycobacterial counterpart and tested these lines for recognition of complete sets of overlapping peptides spanning either hsp60 sequence. T cell lines responded to identical regions in the hsp60 proteins, regardless of their degree of conservation or I-A(g7) binding-affinity. Additionally, we determined whether a protective genetic background would affect the presence of hsp60 cross-reactive T cells in the peripheral repertoire by comparing epitope recognition in I-A(g7) expressing NOD, NOD-asp and Biozzi AB/H mice. Two out of five immunodominant murine peptides were able to induce proliferation in NOD and NOD-asp Mt60 T cell lines, but not in Biozzi AB/H T cell lines. Our results point out that Mt60 immunization not necessarily leads to proliferative T cells responding to endogenous hsp60 peptides in the context of diabetes-predisposing I-A(g7). Moreover, the capacity of T cells to respond to self hsp60 is not influenced by the presence of protective I-A(g7asp). Yet, proliferation of hsp60 autoreactive T cells is solely measured in combination with insulitis and as such serves as a surrogate marker for islet inflammation.     

The 65-kDa heat-shock protein in the pathogenesis, prevention and therapy of autoimmune arthritis and diabetes mellitus in rats and mice

Conclusions hsp are molecules which are highly conserved from procaryotes to eukaryotes. At a first glance the immune system should treat these molecules as self. However, strong immune reactions to bacterial hsp are observed during infection in mammals.hsp65 plays a role in several autoimmune diseases in animal models. In AA in Lewis rats the involvement of hsp65 has been revealed by T cell clones which induce disease in naive recipients, or by T cell vaccination experiments. T cell clones which show in vivo activity have been used as tools in vitro to define epitopes involved in the disease process. In this manner mycobacterial hsp65 and its epitope peptide 180–188 were deduced for AA in Lewis rats. Similarily the epitope p277 was defined for diabetes in NOD mice.The role of hsp65 in several other autoimmune diseases was seen when animals were pretreated with hsp65 and found to be protected from subsequent induction of autoimmune disease. From the involvement of hsp65 in several different autoimmune diseases, it would appear that hsp65 is somehow a key factor in natural autoimmunity. At a fist glance this is surprising since mycobacterial hsp65 shows 50% amino acid homology with human hsp65, in other words it is half-self.Peptide epitopes, peptide 180–188 in AA in Lewis rats and p277 in IDDM in NOD mice, have been used for peptide vaccination, which represents another possibility for prevention of autoimmune disease. The immunological mechanism which leads to resistance from autoimmune disease involves hsp65 immunity and appears not to be associated with tolerance or non-responsiveness to hsp65, but seems to be due rather to modulation of naturally existing networks of idiotype-anti-idiotype T cells organized around hsp65 as the target antigen.     

Adjuvant arthritis and immunity to the mycobacterial 65 kDa heat shock protein.

The mycobacterial 65 kDa heat shock protein (HSP65) is of critical significance in the model of adjuvant arthritis (AA). Arthritogenic and protective T cell clones obtained from arthritic rats recognized the 180-188 sequence of HSP65. Previous reports have shown that administration of HSP65 prior to disease induction led to resistance to arthritis in the AA model and in several other models of experimental arthritis. Here, we report the development of immunity to HSP65 and the critical 180-188 epitope during the course of AA. Following Mycobacterium tuberculosis (MT) immunization both antibodies and T cell responses to HSP65 were detected. Proliferative responses to the 180-188 epitope were seen exclusively in the local draining lymph node cells at day 14 after immunization. The anatomical distribution and course of T cell responses to HSP65 and its 180-188 epitope are compatible with T cell regulated control of the disease. Although lower HSP65 antibody levels were observed in the animals with severe arthritis, in individual animals no evidence was obtained for a relationship between development of HSP65 humoral immunity and arthritis severity. Nevertheless, during disease exacerbation, elicited by HSP65 immunization during disease development, elevated T cell responses against HSP65 and its 180-188 epitope were found. In contrast, we obtained evidence that successful transfer of arthritis resistance to naive recipients depends on the transfer of HSP65 specific T cells. On the basis of these results, it seems that HSP65 plays a crucial role in the T cell regulatory events involved in both the induction of, and protection against, AA.(ABSTRACT TRUNCATED AT 250 WORDS)     

Mycobacterial 65,000 MW heat-shock protein shares a carboxy-terminal epitope with human epidermal cytokeratin 1/2.

Molecular mimicry between mycobacterial heat-shock protein (hsp) 65 and host tissue antigens have been implicated in the autoimmune pathogenesis of certain idiopathic diseases. Here, we demonstrated that two of our previously characterized monoclonal antibodies (mAb), Ne5 and Nd4 that were directed to a carboxy-terminal epitope on the mycobacterial hsp 65, specifically cross-reacted with suprabasal cytokeratin of the normal human skin. These mAb also showed similar keratin staining of hair follicle epithelia and produced no reaction with other dermal components. Both mAb strongly stained the cytoplasm of the majority of freshly isolated epidermal keratinocytes from the normal human skin. None of these mAb showed staining with human HeLa cells and with human skin fibroblasts. Immunoblotting using total keratin extract prepared from isolated epidermal keratinocytes revealed that mAb Ne5 and Nd4 specifically reacted with a molecular size of 65,000-67,000 MW keratin protein(s) and such reactivity was not observed from cytoskeletal proteins extracted from HeLa cells and skin fibroblasts. Comparison of immunoblotting reactivity with conventional anti-cytokeratin mAb further revealed that mAb Ne5/Nd4 recognized a 65,000-67,000 MW molecular-sized protein corresponding to cytokeratin 1/2 from the same keratinocyte extract as anti-cytokeratin mAb. Preincubation of mAb Ne5/Nd4 with the purified mycobacterial hsp 65 abolished this keratin cross-reactivity in both immunohistochemistry and immunoblotting. Moreover, these mAb showed no keratin staining in lesional psoriatic skin and also reacted weakly with cultured epidermal keratinocytes. Since mAb Ne5/Nd4 specifically recognized a 67,000-65,000 MW molecular-sized protein(s) derived from epidermal keratinocytes and the known characteristics of epidermal cytokeratin 1/2 appeared to be consistent with present results, we concluded that Ne5/Nd4 cross-reactive protein(s) in the human epidermis is suprabasal cytokeratin 1/2. Comparison of the previously mapped Ne5/Nd4 epitope region of amino acid residues 525-540 of the mycobacterial hsp 65 with the entire sequence of human 65,000 MW keratin revealed that a stretch of nine amino acids of the Ne5/Nd4 epitope sequence resembled certain regions of the carboxy-terminus of the human 65,000 MW keratin. This similarity of the mycobacterial hsp 65 probably contributes to the cytokeratin cross-reactive epitope. Our results presented here demonstrate direct evidence of immunological cross-reactivity between mycobacterial hsp 65 and human epidermal cytokeratin 1/2. We speculate that Ne5/Nd4 cross-reactive epitope of epidermal cytokeratins might be an important target for skin diseases.     

The identification of a common pathogen-specific HLA class I A*0201-restricted cytotoxic T cell epitope encoded within the heat shock protein 65.

Bacterial antigens recognized by CD8(+) T cells in the context of MHC class I are thought to play a crucial role in protection against pathogenic intracellular bacteria. Here, we demonstrate the induction of HLA-A*0201-restricted CD8(+) T cell responses against six new high-affinity HLA-A*0201-binding CTL epitopes, encoded within an immunodominant and highly conserved antigen of Mycobacteria, the heat shock protein 65 (hsp65). One of these epitopes, Mhsp65(9(369)), is identical in a large number of pathogenic bacteria, and is recognized in a CD8-independent fashion. Mhsp65(9(369)) could be presented by either mycobacterial hsp65-pulsed target cells or BCG-infected macrophages. Interestingly, T cells specific for this epitope did not recognize the corresponding human hsp65 homologue, probably due to structural differences as revealed by modeling studies. Furthermore, in vitro proteasome digestion analyses show that, whereas the mycobacterial hsp65 epitope is efficiently generated, the human hsp65 homologue is not, thus avoiding the induction of autoreactivity. Collectively, these findings describe high-affinity HLA class I-binding epitopes that are naturally processed and are recognized efficiently by MHC class I-restricted CD8(+) T cells, providing a rational basis for the development of subunit vaccine strategies against tuberculosis and other intracellular infectious diseases.     

Heat shock protein 60 and adjuvant arthritis: a model for T cell regulation in human arthritis

Heat shock proteins (hsp) are highly conserved, immune-dominant microbial proteins, whose expression is increased at sites of inflammation. In the experimental model of adjuvant arthritis (AA) immune responses to hsp determine the outcome of disease. AA can be transferred with a single T cell clone specific for a sequence of mycobacterial hsp65 (Mhsp65). Immunization with whole Mhsp65 on the other hand, protects in virtually all forms of experimental arthritis, including AA. This protective effect seems the consequence of the induction of a T cell response directed against self-hsp60. A similar protective effect of self-hsp60-specific T cells seems present in patients with a spontaneous remitting form of juvenile idiopathic arthritis. Next to hsp60, other hsp have similar protective effects in arthritis, while other conserved microbial proteins lack such capacity. Nasal administration of hsp60 peptides induces IL-10-driven regulatory T cells that are highly effective in suppressing arthritis. Thus hsp60, or peptides derived from hsp60, are suitable candidates for immune therapy in chronic arthritis.     

Lysis of interferon-gamma activated Schwann cell by cross-reactive CD8+ alpha/beta T cells with specificity for the mycobacterial 65 kd heat shock protein.

Heat shock protein (hsp) 65 is a major T cell antigen of Mycobacterium leprae. The hsp 65 of M. leprae is nearly identical in M. bovis/M. tuberculosis (greater than 95% protein sequence homology) and surprisingly similar in man (65% protein sequence homology). Recently, we had provided evidence in a murine model that CD8+ T cells recognize and lyse Schwann cells presenting M. leprae antigen in the context of major histocompatibility (MHC) class I gene products. Because murine Schwann cells are class I negative, antigen presentation requires prior stimulation with interferon-gamma (IFN-gamma). CD8+ T cells were activated against tryptic fragments of mycobacterial hsp 65. These T cells recognized epitopes of hsp 65 which had been generated through the cytoplasmic class I processing pathway. They were also capable of lysing Schwann cells which had been activated by IFN-gamma and not primed with nominal hsp 65 peptides. In contrast, T cells activated against tryptic ova peptides only lysed Schwann cells which had been both stimulated with IFN-gamma and primed with ova peptides. Evidence is presented that class I (H-2D) restricted, CD8+ alpha/beta T lymphocytes with specificity for the mycobacterial hsp 65 recognize IFN-gamma-stimulated Schwann cells probably because they are specific for a(n) epitope(s) shared by the bacterial hsp and a host cognate. Activation of autoreactive T cells with specificity to shared epitopes could contribute to nerve damage in tuberculoid leprosy which is characterized by low to absent M. leprae in Schwann cells.     

Identification of mimicry peptides based on sequential motifs of epitopes derived from 65-kDa glutamic acid decarboxylase

Insulin-dependent diabetes mellitus (IDDM) is an autoimmune disease with a predominantly non-hereditary etiology that results in a destruction of pancreatic beta cells by autoaggressive T lymphocytes. Neither the mechanism of initial stimulation of these T cells nor the nature of the environmental factors implicated in the disease have so far been identified. However, both issues are taken into account by the hypothesis of initial T cell activation by viral or bacterial mimicry peptides with sequence similarities to pancreatic self antigens. We determined sequential epitope motifs to search for mimicry peptides stimulating T cell lines specific for two epitopes derived from the IDDM autoantigen 65-kDa glutamic acid decarboxylase (GAD65). These were GAD65 (88 – 99), presented by HLA-DRB1*0101, and GAD65 (248 – 257), presented by HLA-DRB5*0101. T cell stimulation by peptides with substitutions in HLA anchor or T cell contact positions was analyzed to establish degenerate epitope motifs for database searching. Out of 28 tested candidate mimicry peptides derived from bacterial, viral and human proteins, 3 stimulated T cell lines and a T cell clone specific for epitope GAD65 (248 – 257). Our results demonstrate that mono- and polyclonal GAD65-specific T cells from IDDM patients can be stimulated by viral and bacterial peptides with little apparent sequence homology with autoantigenic epitopes. Moreover, in a synopsis with related published studies, our findings suggest that simple degenerate search motifs comprising principal T cell contacts plus HLA class II binding motifs may suffice to identify most mimicry peptides.     

Heat shock proteins and autoimmunity in humans

Summary T cells and antibodies against self and non-self hsp are present in both patients and healthy controls. T cells responding to hsp65 can be involved in autoimmune diseases, this was demonstrated for two site-specific animal autoimmune diseases: AA in Lewis rats and diabetes (IDDM) in NOD mice. In human ReA there is evidence for a direct stimulation of joint T cells by antigens of the organisms causing the infection which precedes the joint inflammation. The individual antigens of the triggering bacteria still have to be defined, but hsp65 may be of importance since this is one of the molecules recognized by synovial T cells in ReA patients.In RA there are no clear data implicating an infection in the initiation of joint inflammation, but mycobacteria have been suggested to be involved. We have discussed experimental findings which are in favor of, or in contradiction with, a role of mycobacterial antigens — particularly hsp65 — in the etiology of RA. T cells recognizing hsp65 and other mycobacterial antigens are present in the joint, but there is no indication for a specific involvement of one or a limited set of (myco)bacterial antigens in the pathogenesis of RA.     

Suppression of adjuvant arthritis in rats by induction of oral tolerance to mycobacterial 65-kDa heat shock protein

Oral administration of mycobacterial 65-kDa heat shock protein (HSP) given daily for 5 days prior to immunization with Mycobacterium tuberculosis (Mt) suppressed the development of adjuvant arthritis (AA) in rats. AA was significantly suppressed by 30 and 300 μg HSP, and variably by 0.3, 3 μg or 1 mg. Histological analysis of joint samples obtained from control and test rats confirmed the suppression of AA in the fed group. Feeding Mt or hen egg lysozyme (HEL) failed to affect AA, indicating that the suppression was HSP specific. The oral administration of 30 μg HSP decreased both delayed-type hypersensitivity (DTH) reactions and proliferative responses to HSP and Mt. In addition, the proliferation of lymph node cells (LNC) from Mt-sensitized rats was inhibited by the addition of spleen cells (SPC) from HSP-fed animals, possibly by the secretion of transforming growth factor (TGF)-β. Spleen cells obtained from tolerized donors were capable of transferring the tolerance to naive recipients. These results demonstrate that feeding HSP is an effective way to suppress AA and that the suppression of AA may be mediated by regulatory T cells generated following oral administration of mycobacterial 65-kDa HSP.     

Mycobacterial 65-kD heat shock protein induces release of proinflammatory cytokines from human monocytic cells.

Monocytes having phagocytosed mycobacteria are known to present the bacterial 65-kD heat shock protein (hsp) on their cell surface to alpha beta and gamma delta T lymphocytes. Cytotoxic CD4+ cells may then lyse monocytes expressing mycobacterial 65-kD hsp. However, it is not known whether 65-kD hsp directly stimulates monocyte functions other than antigen presentation. This study has demonstrated that following extraction of bacterial lipopolysaccharide, purified recombinant mycobacterial 65-kD hsp may directly activate THP-1 cells, a human monocytic line, to accumulate mRNA for and secrete tumour necrosis factor (TNF), a cytokine important in granuloma formation, the characteristic host immune response to mycobacterial infection. TNF gene expression and secretion following stimulation by hsp was dose-dependent and abolished by heat-induced proteolysis. Subsequently, THP-1 cells secreted IL-6 and IL-8, cytokines involved in recruitment and differentiation of T lymphocytes. The data indicate that secretion of proinflammatory cytokines from monocytes activated by mycobacterial 65-kD hsp may be important in the host immune response and in the development of antigen-specific T cell-mediated immunity.     

Efficient recognition by rat T cell clones of an epitope of mycobacterial hsp 65 inserted in Escherichia coli outer membrane protein PhoE.

PhoE is a pore-forming protein, abundantly expressed in the Escherichia coli outer membrane. Previous investigations have shown the possibility of inserting antigenic determinants in cell surface-exposed regions of PhoE by recombinant DNA techniques without disturbing the biogenesis and the functioning of the protein. This method proved to be successful for foot-and-mouth disease virus B cell determinants. We have now shown for the first time that PhoE can also be used as a carrier molecule for T cell epitopes. A well-characterized T cell epitope (180-188) of the 65-kDa heat-shock protein (hsp 65) of Mycobacterium tuberculosis was expressed in PhoE and tested for recognition by specific T cell clones. Specific and efficient T cell proliferation was found after stimulation with this protein construct in vitro. Interestingly, paraformaldehyde fixation of antigen-presenting cells did not abrogate T cell recognition. Thus, in contrast to hsp 65 itself, recognition of epitope 180-188 in the context of PhoE appeared to be independent of antigen-processing events. At the level of polyclonal T cell responses the epitope in the context of PhoE is recognized more efficiently than 180-188 as synthetic peptide or in the context of the hsp 65 molecule itself. These findings indicate that PhoE may serve as attractive vaccine carrier not only for B, but also for T cell epitopes. Furthermore, the possibility for expression of PhoE constructs in attenuated Salmonella typhimurium strains offers the exciting prospect of new types of live oral vaccines expressing selected combinations of B and T cell epitopes.     

Experimental immunization with anti-rheumatic bacterial extract OM-89 induces T cell responses to heat shock protein (hsp)60 and hsp70; modulation of peripheral immunological tolerance as its possible mode of action in the treatment of rheumatoid arthritis (RA)

OM-89 is a bacterial (Escherichia coli) extract used for oral administration in the treatment of RA. Given the evidence that immunity to bacterial heat shock antigens plays a critical role in the immunomodulation of arthritis and possibly inflammation in general, the purpose of the present studies was to evaluate the presence and immunogenicity of hsp in OM-89. Furthermore, we studied the effects of OM-89 in an experimental arthritis, where hsp are known to have a critical significance in disease development. In rats immunization with OM-89 was found to lead to proliferative T cell responses to hsp60 and hsp70 of both E. coli and mycobacterial origin. Conversely, immunization with hsp antigens was also found to induce T cell reactivity specific for OM-89. Based on this and the antigen specificity analysis of specific T cell lines, hsp70 (DnaK) turned out to be one of the major immunogenic constituents of OM-89. Parenteral immunization with OM-89 was found to reduce resistance to adjuvant arthritis (AA), whereas oral administration was found to protect against AA. Given the arthritis-inhibitory effect of oral OM-89 in AA, it is possible that peripheral tolerance is induced at the level of regulatory T cells with specificity for hsp. This may also constitute a mode of action for OM-89 as an arthritis-suppressive oral drug.