Prevention of adjuvant arthritis in rats by a nonapeptide from the 65-kD mycobacterial heat-shock protein

Intraperitoneal Administration of Adjuvant Inhibits the Development of Adjuvant Arthritis in Rats

In recent years, considerable efforts have been made to develop effective therapy for autoimmune diseases by specific suppression of the autoreactive immune process without affecting the remainder of the immune system. In our study we evaluated the protective effects and therapeutic potential of Mycobacterium butyricum (Mb), the causative antigen inducing adjuvant arthritis (AA), an experimental model of autoimmune disease in the rat. The antigen was administered to rats by a different route and at concentrations 10 and 100 times lower than the inducing one. Arthritis was induced by injection of 0.6 mg of Mb in paraffin oil into the hindpaw, and the severity of disease was assessed by measurement of contralateral paw swelling every three days and primary and secondary lesions were scored on an arbitrary scale after 14, 21, and 28 days. Animals were assigned to different groups and treated intraperitoneally with different doses and schedules of Mb. The administration of 60 μg of Mb every two days, starting 6 days before arthritogenic injection until the second day after, led to a significant inhibition of the arthritic process (p< 0.001 of the arthritic index). Treatment of animals with 60 μg of Mb every two days, from day 2 to day 21 after arthritis induction caused almost total suppression of lesions. However, in both treatment schedules, animals showed important signs of peritoneal inflammation. The administration of single injection of 60 or 6 μg of Mb 10 days after arthritis induction led to an inhibition of arthritic index reaching the maximum percentage on day 14 (26% and 24% with 60 and 6 μg respectively) and was able to delay the development of oedema foot volume, without signs of local inflammation. These results confirm the ability to modulate the autoimmune process even when the immunological response is far advanced, suggesting new strategies in the therapy of human autoimmune diseases.

A measles-derived peptide treats and vaccinates against adjuvant arthritis

Measles vaccine and porcine myelin basic protein were both found to ameliorate or abolish the symptoms of adjuvant arthritis (AA) in Lewis rats whether inoculated at the time of adjuvant administration or after the onset of arthritis. These results are consistent with clinical observations that measles infection can sometimes cause remission of juvenile rheumatoid arthritis. The fact that measles virus proteins and myelin basic protein have significant regions of homology allowed peptides based on these regions to be synthesized. A twenty-amino acid sequence exhibits significant anti-arthritic activity when inoculated into rats with pre-existing AA and it also prevented onset of AA when a single dose was preinoculated three weeks prior to AA induction. These data suggest the possibility of developing novel therapeutic vaccines against some forms of arthritis.

Treatment of adjuvant arthritis with granulocyte-colony stimulating factor and peptide derived from heat shock protein 65

Adjuvant arthritis in Lewis rats is induced by the subcutaneous injection of Mycobacterium tuberculosis in mineral oil, and the predominant T cell immune reactivity is against the heat shock protein 65 derived peptide 176-190. We treated Lewis rats with human recombinant G-CSF followed by (i.v) administration of peptide 176-190 after induction of adjuvant arthritis (AA), and observed decreased disease severity, joint destruction, new bone formation and joint ankylosis. Treatment with G-CSF alone was also effective, but to a lesser extent. In addition, we found that splenocytes from rats treated with G-CSF had reduced antigen presenting capacity compared with splenocytes from vehicle treated rats. Primed lymph node cells from G-CSF plus peptide treated rats showed a marked reduction in proliferation and secretion of IFN-gamma after stimulation with the heat shock protein peptide in vitro as compared to controls.

Activation of T Cells Recognizing an Epitope of Heat-Shock Protein 70 Can Protect Against Rat Adjuvant Arthritis

We have previously reported that CD4+ T cells recognizing a peptide comprising residues 234–252 of the heat shock protein (HSP)70 of Mycobacterium tuberculosis (M.tb) in the context of RT1.B MHC class II molecule emerged in the peritoneal cavity during the course of Listeria monocytogenes infection in rats and suppressed the inflammatory responses against listerial infection via IL-10 production. We report in this work that pretreatment with peptide 234–252 of HSP70 derived from M.tb suppressed the development of adjuvant arthritis (AA) in Lewis rats induced using heat-killed M.tb. T cells from rats pretreated with peptide 234–252 produced a significant amount of IL-10 in response to the epitope. T cells from rats pretreated with the peptide and immunized with M.tb produced the larger amount of IL-10 in response to the peptide, but only a marginal level of IFN-γ in response to purified protein derivative of M.tb. Administration of anti-IL-10 Ab partly inhibited the suppressive effect of pretreatment with peptide 234–252 on the development of AA. Furthermore, transfer of a T cell line specific for the epitope at the time of AA induction markedly suppressed AA. These findings suggested that T cells recognizing peptide 234–252 may play a regulatory role in inflammation during AA via the production of suppressive cytokines including IL-10.

Diversification of response to hsp65 during the course of autoimmune arthritis is regulatory rather than pathogenic

Determinant spreading has been implicated in the pathogenesis of certain autoimmune diseases in animal models. We have observed that during the course of adjuvant arthritis (AA) in the Lewis rat, there is 'diversification' of response to the bacterial 65-kDa heat shock protein (Bhsp65) towards its carboxy-terminal determinants (BCTD). Strikingly, pretreatment of naive Lewis rats with BCTD affords significant protection from AA. Our preliminary studies indicate that the diversification of response to BCTD in the Lewis rat is probably triggered in vivo by the induction and enhanced processing of self(rat) hsp65. Thus, the self hsp65-directed T-cell responses appear to be involved in mediating natural remission from acute inflammatory arthritis induced by a foreign antigen, Mycobacterium tuberculosis. This the first report describing that the new T-cell specificities arising during the course of an autoimmune disease are regulatory/protective rather than pathogenic. Moreover, our results suggest that a final common mechanism involving BCTD might be recruited by other rat strains which either are resistant to AA (WKY rats) or whose susceptibility to AA is modulated significantly by microbial flora (Fisher rats). The results of this study would contribute significantly to understanding of the pathogenesis of human rheumatoid arthritis, and in devising new therapeutic strategies for this disease.

Immune responses to stress proteins: applications to infectious disease and cancer

Heat shock proteins, or stress proteins have been identified as part of a highly conserved cellular defence mechanism mediated by multiple, distinct gene families and corresponding gene products. As intracellular chaperones, stress proteins participate in many essential biochemical pathways of protein maturation and function active during times of stress and during normal cellular homeostasis. In addition to their well-characterized role as protein chaperones, stress proteins are now realized to possess another important biological property: immunogenicity. Stress proteins are now understood to play a fundamental role in immune surveillance of infection and malignancy and this body of basic research has provided a framework for their clinical application. As key targets of both humoral and cellular immunity during infection, stress proteins have accordingly received considerable research interest as prophylactic vaccines for infectious disease applications. The unique and potent immunostimulatory properties of stress proteins have similarly been applied to the development of new approaches to cancer therapy, including both protein and gene-based modalities.

Heat shock proteins and arthritis--new readers start here

The possible roles of heat shock proteins in the pathogenesis of inflammatory arthritis have been discussed for a number of years, and investigated intensively in both animal models and human disease. This review surveys evidence which has pointed, on the one hand, to hsp as targets of a pathogenic immune response, and on the other, to an immunoregulatory role for T cell recognition of self hsp. The extent to which findings in experimental animals have led to further insights applicable to human disease is also emphasised.

Reduction of disease causative T-cells in experimental autoimmune disease models by a new antirheumatic drug, TAK-603

We investigated the mode of action of a new quinoline derivative, TAK-603 (ethyl 4-(3,4-dimethoxyphenyl)-6,7-dimethoxy-2-(1,2,4-triazol-1-ylmeth yl) quinoline-3-carboxylate), in adjuvant arthritis (AA), a model of rheumatoid arthritis. AA rat splenocytes transferred the arthritis to normal syngeneic rats upon inoculation, but the cells from AA rats treated with TAK-603 (6.25 mg/kg/day) caused only mild arthritis with significantly less foot pad swelling and a lower arthritis score. An effect of TAK-603 in the induction phase of AA was suggested. TAK-603 had little effect on CD4+ and CD8+ T-cell populations in the AA rat splenocytes. We therefore estimated the frequency of T-cells which are reactive to the so-called disease causative antigen using a limiting dilution assay (LDA). The ratio of T-cells responsive to PPD, which increased in AA rat splenocytes with the severity of the arthritis, was reduced in AA rats treated with TAK-603. Furthermore, the ratio of MBP (myelin basic protein)-reactive T-cells, which were generated in experimental allergic encephalomyelitis (EAE) rats, were also reduced by TAK-603 administration. These data suggest that TAK-603 acts on the immune system and reduces the number of cells reactive to the relevant antigen.

Diversification of T cell responses to carboxy-terminal determinants within the 65-kD heat-shock protein is involved in regulation of autoimmune arthritis

The T cell response to the 65-kD mycobacterial heat-shock protein (Bhsp65) has been implicated in the pathogenesis of autoimmune arthritis. Adjuvant arthritis (AA) induced in the Lewis rat (RT-1(l)) by injection of Mycobacterium tuberculosis serves as an experimental model for human rheumatoid arthritis (RA). However, the immunological basis of regulation of acute AA, or of susceptibility/resistance to AA is not known. We have defined the specificity of the proliferative T cell responses to Bhsp65 during the course of AA in the Lewis rat. During the early phase of the disease (6-9 d after onset of AA), Lewis rats raised T cell responses to many determinants within Bhsp65, spread throughout the molecule. Importantly, in the late phase of the disease (8-10 wk after onset of AA), there was evidence for diversification of the T cell responses toward Bhsp65 carboxy-terminal determinants (BCTD) (namely, 417-431, 441-455, 465-479, 513-527, and 521-535). Moreover, arthritic rats in the late phase of AA also raised vigorous T cell responses to those carboxy-terminal determinants within self(rat) hsp65 (Rhsp65) that correspond in position to the above BCTD. These results suggest that the observed diversification is possibly triggered in vivo by induction of self(Rhsp65)-reactive T cells. Interestingly, another strain of rat, the Wistar Kyoto (WKY/NHsd) rat (RT-1(l)), with the same major histocompatibility complex class II molecules as the Lewis rat, was found to be resistant to AA. In WKY rats, vigorous responses to the BCTD, to which the Lewis rat responded only in the late phase of AA, were observed very early, 10 d after injection of M. tuberculosis, Strikingly, pretreatment with the peptides comprising the set of BCTD, but not its amino-terminal determinants, provided significant protection to naive Lewis rats from subsequent induction of AA. Thus, T cell responses to the BCTD are involved in regulating inflammatory arthritis in the Lewis rat and in conferring resistance to AA in the WKY rat. These results have important implications in understanding the pathogenesis of RA and in devising new immunotherapeutic strategies for this disease.

Infection, autoimmunity and autoimmune disease

Studies of the immune response of mammals to infectious agents have revealed that members of the hsp60 and hsp 70 family are highly immunodominant. Given their high conservation during evolution this was surprising, because of the apparent risk of triggering of autoimmunity and autoimmune disease during the defense of a mammal against infection. However, detailed studies of the immune responses to HSP in models of autoimmune diseases in animals resulted in a change of the view that autoimmunity necessarily leads to autoimmune disease. It has been found that modulation of autoimmunity to HSP is one way to prevent autoimmune disease. At least in some cases even treatment of autoimmune diseases by immunization with heat shock protein appears feasible. This was shown in adjuvant arthritis in Lewis rats and insulin dependent diabetes in NOD mice. Hsp60 and hsp70 are ubiquitous proteins. Their involvement in regulatory loops of autoimmunity may serve as basis for the development of strategies, to prevent and/or treat autoimmune diseases even without knowledge of the causative (auto-)antigen.

Vaccination with recombinant heat shock protein 60 from Histoplasma capsulatum protects mice against pulmonary histoplasmosis

HIS-62 is a glycoprotein that has been isolated from the cell wall and cell membrane fraction of the pathogenic fungus Histoplasma capsulatum. It is a target of the cellular immune response to this fungus, and it protects mice against a lethal intravenous inoculum of H. capsulatum yeast cells. In this study, we cloned the gene encoding this antigen to reveal its biological nature and studied the immunological activity of recombinant antigen. The amino acid sequences of the NH2 terminus and internal peptides were obtained by Edman degradation. Degenerate oligonucleotides were used to isolate a gene fragment of HIS-62 by PCR. One 680-bp segment that corresponded to the known peptide sequence was amplified from H. capsulatum DNA. This DNA was used to screen a genomic library, and the full-length gene was isolated and sequenced. The deduced amino acid sequence of the gene demonstrated approximately 70 and approximately 50% identity to heat shock protein 60 (hsp 60) from Saccharomyces cerevisiae and hsp 60 from Escherichia coli, respectively. A cDNA was synthesized by reverse transcription PCR and was expressed in E. coli. Recombinant protein reacted with a monospecific polyclonal rabbit antiserum raised against native HIS-62, with monoclonal HIS-62-reactive T cells, and with splenocytes from mice immunized with viable yeast cells. Moreover, vaccination with the recombinant protein conferred protection in mice against a lethal intranasal inoculation with yeast cells. Thus, HIS-62 is a member of the hsp 60 family, and the recombinant hsp 60 is protective against pulmonary histoplasmosis in mice.

Activation of T cells recognizing self 60-kD heat shock protein can protect against experimental arthritis

Lewis rats are susceptible to several forms of experimental arthritis-induced using heat-killed Mycobacterium tuberculosis (adjuvant arthritis, or AA), streptococcal cell walls, collagen type II, and the lipoidal amine CP20961. Prior immunization with the mycobacterial 65-kD heat shock protein (hsp65) was reported to protect against AA, and other athritis models not using M. tuberculosis, via a T cell-mediated mechanism. Hsp65 shares 48% amino acid identity with mammalian hsp60, which is expressed at elevated levels in inflamed synovia. Several studies have reported cross-reactive T cell recognition of mycobacterial hsp65 and self hsp60 in arthritic and normal individuals. We previously described nine major histocompatibility complex class II-restricted epitopes in mycobacterial hsp65 recognized by Lewis rat T cells. Of these only one, covering the 256-270 sequence, primed for cross-reactive T cell responses to the corresponding region of rat hsp60. Here we have tested each hsp65 epitope for protective activity by immunizing rats with synthetic peptides. A peptide containing the 256-270 epitope, which induced cross-reactive T cells, was the only one able to confer protection against AA. Similarly, administration of a T cell line specific for this epitope protected against AA. Preimmunization with the 256-270 epitope induced T cells that responded to heat-shocked syngeneic antigen-presenting cells, and also protected against CP20961-induced arthritis, indicating that activation of T cells, recognizing an epitope in self hsp60 can protect against arthritis induced without mycobacteria. Therefore, in contrast to the accepted concept that cross-reactive T cell recognition of foreign and self antigens might induce aggressive autoimmune disease, we propose that cross-reactivity between bacterial and self hsp60 might also be used to maintain a protective self-reactive T cell population. This discovery might have important implications for understanding T cell-mediated regulation of inflammation.

Specificity of antibodies induced after immunization of mice with the mycobacterial heat shock protein of 65 kD

We have previously shown in mice and monkeys that mycobacterial heat shock proteins (hsp) of 65 and 70 kD exert a strong in vivo helper effect when conjugated to synthetic peptides or bacterial oligosaccharides and given in the absence of any adjuvants. Considering the degree of homology existing in the phylogeny among hsp belonging to the same family, we studied whether antibodies induced in mice with this protocol of immunization with the mycobacterial 65-kD hsp (hsp65) would cross-react, and to what extent, with hsp homologues from other origins, notably with the Escherichia coli GroEL protein and with the human homologue (hsp60). The results obtained show that antibodies to the mycobacterial hsp65 cross-reacted with the E. coli GroEL protein, both in ELISA and Western blot experiments, but not with the human hsp60. In competitive ELISA experiments, the binding of these antibodies to solid-phase hsp65 was very effectively inhibited by low concentrations of the mycobacterial hsp65; however, for human hsp60, 100 times higher concentrations were required in order to obtain similar patterns of inhibition. Finally, murine antibodies to the mycobacterial hsp65 always failed to give positive results in Western blot experiments using extracts of murine cells. Taken together, these data suggest that, after immunization of mice with the mycobacterial hsp65 conjugated to peptides or oligosaccharides in the absence of adjuvants, anti-hsp65 antibodies are induced which cross-react well with hsp homologues from other prokaryotes (e.g. E. coli GroEL), but which weakly bind the human hsp homologue. These results may have implications for the potential use of microbial hsp molecules in the design of conjugated vaccine constructs.

Variability in the induction of experimental arthritis: Yersinia associated arthritis in Lewis rats

Lewis rats of different microbiological status were studied for susceptibility to experimentally-induced Yersinia associated arthritis. Status A rats were serologically positive for Bacillus piliformis, Kilham rat virus and Toolan H-1 virus, whereas status B rats were serologically negative for these same microorganisms. When status A and status B rats were kept in the same room, incidence of arthritis was low (0-13% for status A rats and 27-33% for status B rats). When status B rats only were kept in different environments, increased incidence (up to 89%) of arthritis was observed. These findings suggest that the microbiological status of the host has an effect on the susceptibility to experimentally-induced arthritis. They call attention to the need for strictly defined conditions, including those of the host and the environment, in studies on experimental arthritides.

A constitutive 65 kDa chondrocyte protein as a target antigen in adjuvant arthritis in Lewis rats

The autoantigen in adjuvant arthritis in Lewis rats is still unknown despite the knowledge that the 65 kDa mycobacterial heat-shock protein (hsp) is involved in the disease process. T cells and antibodies obtained from rats with adjuvant arthritis respond to chondrocyte membrane antigen(s). In Western blots a 65 kDa chondrocyte membrane protein (CH65) is stained by sera from arthritic rats. In addition, spleen cells from rats with adjuvant arthritis proliferate in vitro to chondrocyte membranes and CH65 as antigens. Furthermore, pretreatment of rats with CH65 or mycobacterial hsp65 but not human hsp60, induces a significant retardation of the onset of adjuvant arthritis in Lewis rats. The data suggest that CH65 is a potential autoantigen involved in the pathogenesis of adjuvant arthritis in Lewis rats.

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.

Yersinia associated arthritis in SHR rats: effect of the microbial status of the host

Following the intravenous injection of live Yersinia enterocolitica O:8, 50-69% of SHR rats developed arthritis; these rats were antibody free against all rat pathogens tested. In contrast, only 20-25% of SHR rats which had serum antibodies against Bacillus piliformis, Kilham rat virus, and Toolan H-1 virus developed arthritis. The results indicate that the microbial load of the host has a profound effect on the susceptibility to experimental arthritis.

Suppression of adjuvant-induced arthritis in DA rats by incomplete Freund's adjuvant

OBJECTIVE

To define the effects of incomplete Freund's adjuvant (ICFA) on subsequent arthritis induced by complete Freund's adjuvant (CFA) and type II collagen (CII) in DA and Lewis rats.

METHODS

ICFA was injected into DA and Lewis rats before CFA or CII injection.

RESULTS

DA rats previously injected with ICFA had significantly less severe arthritis induced by CFA compared with those not receiving ICFA pretreatment (P < 0.01). ICFA had no significant impact on CFA-induced arthritis in Lewis rats or on CII-induced arthritis in DA rats.

CONCLUSION

The injection of ICFA alone specifically suppresses subsequent CFA-induced arthritis in DA rats, but not in Lewis rats.

Heat shock proteins in autoimmune disease. From causative antigen to specific therapy?

Heat shock proteins (hsp) are highly conserved from bacteria to man. Bacterial hsp, with approximate molecular weights of 60 kDa (hsp60), are immunodominant antigens that are immunologically cross-reactive with their mammalian counterparts. Hsp molecules are therefore useful in studies of fundamental questions concerning immune responses to foreign as opposed to self antigens. The finding that immune responses to hsp are associated with both experimentally-induced and spontaneous autoimmune diseases in animals has prompted intensive research to assess the role of bacterial hsp as the etiological agents involved in the development of autoimmune diseases. Recent evidence from animal models of autoimmune disease has clearly demonstrated the involvement of hsp in both the pathogenesis and the immunoregulation of autoimmune diseases. Studies with arthritogenic and diabetogenic T cell clones have identified immunogenic epitopes of hsp. These have been shown to ameliorate adjuvant arthritis in Lewis rats, and insulin-dependent diabetes mellitus (IDDM) in non-obese diabetic (NOD) mice. Such studies may have important therapeutic implications for the future treatment of human autoimmune disease.

The humoral immune response to heat shock proteins

Humoral immune reactions to heat shock proteins (hsp) from microorganisms are one aspect of microbial infections in humans. The production of antibodies which are specific to epitopes present on procaryotic hsp leads also to the appearance of cross-reactive serum antibodies in the host organism that react with human hsp. This article discusses the consequences of such autoreactive antibodies for the host in context with the development of immune tolerance and autoimmune diseases, especially rheumatoid arthritis (RA), and in experimental animal models for arthritis such as adjuvant arthritis in rats. On the basis of epitope cross-reactivity between hsp and other host proteins, a hypothesis is presented for the development of autoimmune disease following the production of hsp-specific antibodies.

Are heat shock proteins involved in autoimmunity?

Heat shock proteins (HSPs) have been postulated to be critical antigens in both autoimmune disease and experimental models of autoimmunity. This postulate has been largely based on the remarkable conservation of aminoacid sequence between human and bacterial HSPs, so that it has been argued that immune responses initially directed against the HSP of an infectious agent, would have the potential to initiate or maintain autoimmune disease. This would apply especially to T cell recognition of HSPs, since the T cell focuses on short peptide epitopes within a protein antigen rather than on the antigen's secondary structure. This article critically evaluates the available experimental evidence relating to this hypothesis: although research has clearly highlighted the central role of HSPs in the cellular immune response to pathogenic organisms and has shown the potential for T cell responses directed against self HSPs, a role for self HSPs as major target antigens in autoimmune disease has yet to be firmly established.

Prevention of adjuvant arthritis in rats by a nonapeptide from the 65-kD mycobacterial heat shock protein: specificity and mechanism

In a previous study we have shown that Lewis rats were completely protected from adjuvant arthritis by pretreatment with a nonapeptide (residues 180-188) of the 65-kD mycobacterial heat shock protein. Here we address questions of specificity and mechanism(s) of protection. We demonstrate that complete protection against adjuvant arthritis can only be achieved by pre-immunization with the nonapeptide, while pretreatment with either the octapeptide (residues 181-188) of the 65-kD heat shock protein or unrelated immunogenic peptides failed to affect adjuvant arthritis. Interestingly, pretreatment with the nonapeptide of the 65-kD heat shock protein did not protect Lewis rats from type II collagen-induced arthritis. These results demonstrate that protection is both epitope and disease specific. Co-injection of the nonapeptide with mycobacterial antigen even at a weight ratio of 5:1 (nonapeptide:mycobacteria) failed to influence the disease, suggesting that the role of the nonapeptide is not as a 'blocking peptide'. T cells from rats immunized with nonapeptide respond to the nonapeptide as well as to mycobacteria in vitro, and adoptively transfer protection to naive recipients. The data indicate that the nonapeptide-induced protection may result from a T cell-mediated specific suppression.

Heat-shock proteins as immunogenic bacterial antigens with the potential to induce and regulate autoimmune arthritis

Heat-shock proteins are ubiquitous and surprisingly immunogenic bacterial proteins. Due to their extensive evolutionary conservation, development of immune reactivity directed at hsp is expected to jeopardize the maintenance of tolerance for "self". The experimental model of adjuvant arthritis in rats has been illustrative in this respect. In this model disease is induced by immunization to mycobacteria, and by T-cell cloning it appeared that T cells with specificity for the 180-188 sequence of the mycobacterial hsp65 were capable of both inducing the disease or inducing resistance to the disease. Although the exact molecular mimicry relationship of this 180-186 epitope with the proteoglycan moiety of cartilage remains to be elucidated, the crucial significance of hsp65 immunity has been substantiated further, not only in adjuvant arthritis, but also in other models of experimentally induced arthritis. Development of disease is seen to coincide with development of hsp65 reactivity, and in AA to the 180-186 epitope in particular. There is now experimental evidence that responses to hsp65 are subject to regulatory T-cell control, and that such regulatory control may explain the observations that preimmunization with hsp65 induces protection against subsequent development of arthritis. In human arthritis, responses to hsp65 have been seen to occur at the level of synovial fluid-derived T lymphocytes. Especially, in children with juvenile chronic arthritis such responsiveness was seen to be directed at the endogenous "self" hsp60, as it was also found to be expressed at a raised level in the synovial lining cells. Altogether, both from the experimental models and from the human disease, evidence is being collected for hsp65 as a critical antigen which has, in the experimental models, the potential of inducing protective regulatory T-cell control. AA has now offered us some initial possibilities for exploiting this feature of hsp65 in inducing remission of disease. We may hope that, ultimately, such specific immunological intervention in disease will also become a reality in the management of human autoimmune arthritis. The exploitation of the regulatory control mechanisms that normally contain the dangerously autoimmune reactive elements in the system seems to be most attractive for such a purpose. We should not try to modify the outside non-self; however, we should use our understanding of the mechanisms involved in order to stimulate the immune system of the unfortunate to resume control over the management of responses directed at the endogenous "self". It is possible that further analysis of the role of hsp65 in arthritis will lead to such necessary understanding.

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.