Autoimmunity to HSP60 during diet induced obesity in mice.

Adaptive immunity has been implicated in adipose tissue inflammation, obesity and its adverse metabolic consequences. No obesity-related autoantigen has yet been identified, although heat shock protein 60 (HSP60) has been implicated in other autoimmune diseases. We investigated whether feeding a high-fat diet to C57BL/6J mice would cause autoimmunity to HSP60 and whether immunomodulation with peptides from HSP60 would reverse the resulting obesity or metabolic dysfunction. Obese mice had higher circulating levels of HSP60 associated with increased T-lymphocyte proliferation responses and the emergence of circulating IgG1 and IgG2c antibody levels against HSP60. Treatment with escalating doses of a mixture of three proven immunomodulatory HSP60 peptides did not reduce weight but completely reversed the increase in VLDL/LDL levels and partially reversed the glucose intolerance in obese mice. Obese mice mount an autoimmune response to HSP60, which partly underlies the resulting metabolic disturbances.

Fusion between human mesenchymal stem cells and rodent cerebellar Purkinje cells.

AIMS: we explored whether cellular fusion and heterokaryon formation between human and rodent cells in the cerebellum of mice occurs after intravenous injection of human bone marrow-derived mesenchymal stem cells (MSCs). The influence of central nervous system inflammation on this process was also assessed. In addition, we examined whether tumour necrosis factor (TNF)-alpha and interferon (IFN)-gamma, factors associated with inflammation, increase cellular fusion between human MSCs and rodent cerebellar neurons in vitro. METHODS AND RESULTS: human MSCs were intravenously injected into mice with experimental autoimmune encephalomyelitis (EAE) and control mice. After 22 days, mouse Purkinje cells expressing human Golgi Zone were found within the Purkinje cell layer of the cerebellum, indicating that fusion and heterokaryon formation had occurred. The numbers of heterokaryons in the cerebellum were markedly increased in mice with EAE compared with control mice. Rodent cerebellar neuronal cells labelled with enhanced green fluorescent proteinin vitro were co-cultured with human bone marrow-derived MSCs in the presence of TNF-alpha and/or IFN-gamma to determine their influence on fusion events. We found that fusion between MSCs and cerebellar neurons did occur in vitro and that the frequency of cellular fusion increased in the presence of TNF-alpha and/or IFN-gamma. CONCLUSIONS: we believe that this is the first paper to define fusion and heterokaryon formation between human MSCs and rodent cerebellar neurons in vivo. We have also demonstrated that fusion between these cell populations occurs in vitro. These findings indicate that MSCs may be potential therapeutic agents for cerebellar diseases, and other neuroinflammatory and neurodegenerative disorders.

Preparing for first-in-man studies: the challenges for translational immunology post-TGN1412.

Current immunology research is generating many new approaches to immunotherapy. However, the recent disaster surrounding the testing of TGN1412, has unsettled regulators and the pharmaceutical industry regarding new immunotherapies and highlighted the complexities of conducting clinical trials with agents that target the immune system. Here we discuss the critical role for immunologists in ensuring that the development of new immunotherapies continues.

Diversity and dynamics of the T-cell response to MBP in DR2+ve individuals.

It is generally accepted that multiple sclerosis (MS) is mediated by autoreactive T cells and that myelin basic protein (MBP) is one of the target autoantigens. The T-cell response to MBP has been analysed extensively, largely through the use of T-cell lines (TCL) and T-cell clones (TCC), and to date, three immunodominant regions (13-32, 84-103 and 144-163) have been described. However, given that TCL may represent a skewed pattern of peptide reactivity, we have developed a kinetic response assay in which the proliferation of peripheral blood mononuclear cells (PBMC) from MS patients and healthy individuals was measured directly against a panel of peptides spanning the full length of human MBP. Furthermore, PBMC from each subject were tested three times over the course of 18 months. A high proportion of MS patients exhibited a significant response to eight MBP regions (1-24, 30-54, 75-99, 90-114, 105-129, 120-144, 135-159 and 150-170). TCC were subsequently generated from MS subjects and were used to further define the epitope recognized in each case. Overall, normal individuals recognized significantly fewer peptides. In addition, we noted that the T-cell recognition of any one peptide can fluctuate, appearing at one time point, regressing, and subsequently reappearing at a later date. This study provides new insight into the recognition profile and dynamics of myelin-antigen-specific T cells in MS.

Differential responses of CD45+ve T-cell subsets to MBP in multiple sclerosis.

The proliferative response of preparations of whole PBMC populations from 20 healthy individuals and 28 multiple sclerosis (MS) patients to purified protein derivative (PPD) and myelin basic protein (MBP) was monitored in a kinetic assay over a period of up to 10 days. PPD produced a classical secondary response in both groups, the magnitude being significantly reduced in the MS cohort. The magnitude and pattern of response to MBP did not differ between the two populations. The kinetic profile characteristic of a primary response was observed in both groups. Enrichment of the CD45RO+ve and CD45RA+ve T-cell subsets in PBMC led to a secondary response to PPD in the RO+ve and primary response in the RA+ve population in both groups. The response to MBP in both RO+ve and RA+ve populations exhibited primary kinetics in both MS patients and healthy individuals. However, the use of T-cell subset enriched populations allowed a finer dissection of the response to MBP which highlighted the more active role of RO-positive cells in MS patients. The most striking difference between patients and healthy individuals occurred on day 4 of culture when a greater response to MBP occurred in the CD45RO enriched population, paralleling the response to PPD, in the majority of patients. Futhermore in 4/8 patients and only 1/8 healthy individuals the response in the RO+ve cultures was maintained at a higher level than that seen in the corresponding RA+ve cultures throughout the culture period. This data indicates that a measurable memory response to MBP exists in MS patients implying prior activation of MBP reactive T lymphocytes during the course of disease.

Antigen-presenting cell activation: a link between infection and autoimmunity?

The onset of autoimmune diseases such as type I diabetes and multiple sclerosis is often thought to be associated with infection. This has led to studies of molecular mimicry between infectious agents and the self-antigens associated with autoimmunity. Despite many claims, however, a single causative infectious agent for autoimmunity has not been found. An alternative possibility is that many infectious agents are capable of non-specifically enhancing the likelihood of an autoimmune attack. Here we show how infectious agents may activate antigen-presenting cells leading to the activation of autoreactive T cells by otherwise innocuous antigens. The mechanism of activation involves upregulation of co-stimulatory molecules on the antigen-presenting cell resulting in a lowering of the threshold required for activation. These results help explain how diverse infectious agents could cause autoimmune disease in susceptible individuals.

Negative selection during the peripheral immune response to antigen.

Thymic selection depends on positive and negative selective mechanisms based on the avidity of T cell interaction with antigen-major histocompatibility complex complexes. However, peripheral mechanisms for the recruitment and clonal expansion of the responding T cell repertoire remain obscure. Here we provide evidence for an avidity-based model of peripheral T cell clonal expansion in response to antigenic challenge. We have used the encephalitogenic, H-2 A(u)-restricted, acetylated NH(2)-terminal nonameric peptide (Ac1-9) epitope from myelin basic protein as our model antigen. Peptide analogues were generated that varied in antigenic strength (as assessed by in vitro assay) based on differences in their binding affinity for A(u). In vivo, these analogues elicited distinct repertoires of T cells that displayed marked differences in antigen sensitivity. Immunization with the weakest (wild-type) antigen expanded the high affinity T cells required to induce encephalomyelitis. In contrast, immunization with strongly antigenic analogues led to the elimination of T cells bearing high affinity T cell receptors by apoptosis, thereby preventing disease development. Moreover, the T cell repertoire was consistently tuned to respond to the immunizing antigen with the same activation threshold. This tuning mechanism provides a peripheral control against the expansion of autoreactive T cells and has implications for immunotherapy and vaccine design.

Detection of autoreactive T cells in H-2u mice using peptide-MHC multimers.

Myelin basic protein (MBP)-specific T cells play a critical role in the pathogenesis of experimental autoimmune encephalomyelitis (EAE), a prototype for T cell-mediated autoimmunity. In PL/J and B10.PL mice (H-2(u) haplotype), the immunodominant epitope of MBP is represented by an N-terminal nonameric peptide, MBP1-9. To date, the MBP1-9-specific T cell repertoire has not been analyzed in quantitative terms. In the present study we demonstrate, using MHC class II tetramers, that 15,000-70,000 self-antigen-specific T(h) cells accumulate in the draining lymph nodes following immunization with spinal cord homogenate or MBP1-9. In contrast, MBP1-9-specific T cells are undetectable in unimmunized H-2(u) mice and represent >60% of the CD4 cells in naive mice transgenic for a TCR specific for this epitope. The results suggest that the extremely low affinity of the N-terminal peptide for I-A(u) does not limit the MBP1-9-specific T cells from expanding into a sizeable pool of autoreactive T cells. Therefore, the primary immune response to MBP1-9 does not differ quantitatively from previously reported CD4(+) T cell responses to foreign antigens.

Kinetics of peptide uptake and tissue distribution following a single intranasal dose of peptide.

We have previously used intranasal (i.n.) peptide application to induce mucosal tolerance in experimental autoimmune encephalomyelitis (EAE). This strategy, however, appeared to give rise to similar phenomena of tolerance observed as a result of systemic administration of soluble antigenic peptide. We were interested, therefore, in the uptake and tissue distribution of peptide following i.n. treatment. In the H-2u mouse model of EAE, the highly tolerogenic peptide analogue Ac1-9[4Y] of myelin basic protein (MBP) displays high affinity binding to Au MHC class II. For the purpose of the present study this peptide was synthesised to contain a tritiated acetyl group and a protocol was developed to recover radioactivity in solubilised tissues taken at various times after [3H]Ac1-9[4Y] i.n.. Radiolabel loads of the lung and gastro-intestinal tract were initially high but declined rapidly. Radiolabel uptake by blood and lymphoid tissues followed similar kinetics with peak levels around 2.5-4 hours after i.n. administration. Concentrations were high in the draining cervical lymph nodes (CLN) but also reached significant levels in the spleen and 'nondraining' inguinal lymph nodes. The presence of intact antigenic peptide was demonstrated in spleens and CLN from Ac1-9[4Y] i.n. treated mice. Cell suspensions prepared from these tissues at selected time points after peptide i.n. were able to stimulate peptide-specific T cell lines up to at least one day after peptide i.n., suggesting long lasting formation of stable Au-Ac1-9[4Y] complexes in vivo.

Peptide-induced T cell regulation of experimental autoimmune encephalomyelitis: a role for IL-10.

Experimental autoimmune encephalomyelitis (EAE) is a CD4(+) T cell-mediated, inflammatory disease with similarities to multiple sclerosis in humans. Intranasal (i.n.) administration of a myelin basic protein (MBP)-derived peptide can protect susceptible mice from EAE. The mechanisms underlying this phenomenon, however, remain unclear. To analyze the phenotypic and functional changes taking place during the induction of tolerance by peptide inhalation, we have studied the fate of CD4(+) T cells after i.n. peptide application using transgenic mice expressing a TCR specific for the N-terminal peptide (Ac1-9) of MBP. Peripheral T cell death was variably observed in TCR transgenic mice after a single i.n. administration of antigenic peptide but was transient and incomplete. Transgenic spleen cells and cervical lymph node cells responded with a cytokine burst to peptide inhalation and hyperproliferation when re-stimulated in vitro. Transfer experiments demonstrated that the duration of peptide administration required to induce tolerance depended on the precursor frequency of T cells in recipient animals. The stringency of i.n. peptide treatment was increased so as to test the efficacy of tolerance induction both in vitro and in vivo in the presence of high precursor frequencies of antigen-specific T cells. Multiple i.n. doses of peptide completely protected TCR transgenic mice from EAE induced with myelin. Such repeated peptide administration resulted in down-regulation of the capacity of antigen-specific CD4(+) T cells to proliferate or to produce IL-2, IFN-gamma and IL-4 but increased the production of IL-10. The role of IL-10 in suppression of EAE in vivo was demonstrated by neutralization of IL-10. This completely restored susceptibility to EAE in mice previously protected by i.n. peptide. Considering the immunosuppressive properties of IL-10, T cells which are resistant to apoptosis might act as regulatory cells and mediate bystander suppression.

Ability of T cells from patients with rheumatoid arthritis to respond to immunoglobulin G.

The ability of T cells from rheumatoid factor (RF)-positive patients with rheumatoid arthritis (RA) to respond to immunoglobulin G (IgG) was assessed. Peripheral blood mononuclear cells (PBMC) from RA patients and normal individuals were cultured with and without human IgG or Mycobacterium tuberculosis-purified protein derivative (PPD) for 7 days and their proliferative response measured at intervals by their ability to take up tritiated thymidine. PBMC from 14/26 RA patients proliferated in response to IgG (taking a stimulation index of 3 or above as positive). The peak response varied between individuals but usually occurred on day 5, the same day, or 1 day later than the peak response to PPD. By contrast, PBMC from a significantly lower proportion (1/9) of normal individuals and patients with other arthritides (0/6) responded to IgG, although all responded to PPD. PBMC from 9/14 RA patients responded to Fab fragments of IgG but only 3/9 to the Fc fragment. Higher proliferative responses from RA PBMC were elicited by IgG aggregates than the original IgG preparation, but PMBC from 5/5 normal individuals and 5/6 patients with other arthritides failed to respond to the aggregates. The response to IgG was human leucocyte antigen (HLA)-DR restricted and mediated by CD4+ T cells. It is considered that these results advance the hypothesis that IgG-reactive T cells contribute to the initiation or perpetuation of RA.

Inhibition of T-cell responsiveness by nasal peptide administration: influence of the thymus and differential recovery of T-cell-dependent functions.

We have previously demonstrated that intranasal (i.n.) administration of the major encephalitogenic peptide, Ac1-9 of myelin basic protein (MBP), inhibited T-cell responsiveness in vitro and induced tolerance in the H-2u mouse model of experimental autoimmune encephalomyelitis (EAE). The peptide analogue Ac1-9[4Y] with high-affinity binding to the I-Au major histocompatibility complex (MHC) class II molecule was the most effective tolerogen. Here, we show that mice pretreated with 4Y i.n. and primed with myelin had strongly reduced levels of anti-MBP immunoglobulin G2a (IgG2a) and IgG1, demonstrating that both T helper 1 (Th1) and Th2 functions were inhibited in vivo. Since peptide administered i.n. was shown to be functionally relevant in the thymus, the time interval between 4Y i.n. and subsequent priming was varied in euthymic and adult thymectomized (ATx) mice, to examine the duration of in vitro cell unresponsiveness in the presence or absence of a thymus. For intervals of 1-6 weeks, inhibition of T-cell proliferation was virtually complete in both euthymic and ATx mice. From 8 weeks onwards, responsiveness slowly recovered in euthymic but not in ATx mice. With an interval of 16 weeks, substantial recovery of T-cell responsiveness in vitro in euthymic mice was reflected by a low degree of protection from EAE in vivo. By contrast, anti-MBP IgG2a and IgG1 antibody responses were still significantly reduced. These findings suggest that T-cell unresponsiveness by peptide i.n. represents a thymus-independent, peripheral phenomenon, the reversal of which is confined to new T cells being exported from the thymus. As observed for EAE and antibody responses, the kinetics of recovery may vary for different effector functions.

Therapeutic potential of TCR antagonists is determined by their ability to modulate a diverse repertoire of autoreactive T cells.

The use of altered peptide ligands (APL) with TCR antagonist properties holds promise as an antigen-specific therapy for autoimmune disorders. We are investigating the therapeutic potential of APL in experimental autoimmune encephalomyelitis (EAE) using the Ac1-9 peptide of myelin basic protein in H-2u mice. Encephalitogenic T cells recognize Ac1-9 using residues 3Gln and 6Pro as the major TCR contact sites. Use of position 6 APL is compromised by the heterogeneous nature of the Ac1-9-specific repertoire. Here we identify two position 3 APL that act as TCR antagonists on transgenic T cells expressing Ac1-9-specific TCR and that inhibit EAE in H-2u mice. However, the therapeutic capacity of these two APL correlated directly with the ability to maximally inhibit activation of a heterogeneous T cell pool. The implications of these findings for the requirements for EAE induction, the relative contribution of a given T cell subpopulation to pathology and the mechanism underlying EAE inhibition in this model are discussed.

Splenic but not thymic autoreactive T cells from New Zealand Black mice respond to a dominant erythrocyte Band 3 peptide.

Previous work from our laboratory suggested that erythrocyte Band 3 peptide 861-874 is the dominant epitope recognized by splenic T cells from adult New Zealand Black (NZB) mice that are developing autoimmune haemolytic anaemia (AIHA). Here, it is shown that splenic T cells from 6-week-old NZB mice mount a vigorous in vitro proliferative response to peptide 861-874 and some other selected Band 3 peptides. As the donors grow older, splenic T cells respond to an increasing number of Band 3 peptides and the magnitude of their response also becomes greater. Splenic T cells from 3-week-old NZB mice still responded vigorously to peptide 861-874 and Band 3. By contrast, neither thymocytes nor single-positive CD4-enriched thymus cells from NZB mice responded to peptide 861-874 or Band 3, although they responded to concanavalin A (Con A). However, thymocytes from mice expressing a transgenic T-cell receptor (TCR)-specific for myelin basic protein (MBP) peptide Ac 1-9 responded vigorously to Ac 1-9. It is considered that the T-cell response of NZB mice to Band 3 is initially focused on peptide 861-874 and later spreads to other Band 3 peptides as the disease progresses and that peptide 861-874-reactive T cells are primed in the periphery rather than the thymus.

Phenotypic analysis of CTLA-4 and CD28 expression during transient peptide-induced T cell activation in vivo.

The T cell co-stimulatory receptors CD28 and CTLA-4 appear to have opposite effects on T cell activation, mediating augmentation and inhibition of T cell responses respectively. Since these two receptors use the same ligands, CD80 (B7-1) and CD86 (B7-2), the co-ordinate timing of CD28 and CTLA-4 expression has a major impact on the regulation of immune responses. While the kinetics of co-stimulatory molecules have been established for T cell stimulation in vitro, little is known about CD28 and CTLA-4 expression in response to T cell activation in vivo. In this study we have investigated the kinetics of CD28 and CTLA-4 expression upon CD4(+) T cell activation in response to soluble peptide in vivo. Using mice transgenic for a T cell receptor specific for the I-Au-restricted N-terminal peptide of myelin basic protein MBP Ac1-9, we show maximal up-regulation of both CD28 and CTLA-4 2 days after peptide administration. CTLA-4 expression correlated positively with early activation markers on the same cells and was high on blast cells. Administration of peptide analogs with higher affinity for I-Au MHC class II revealed a higher increase in CTLA-4 than in CD28 expression in response to improved TCR ligation. Further, a small population of CD4(+) T cells expressing CTLA-4, CD25 and CD45RBlow was identified in mice that had not been treated with specific peptide. The implications of these observations for immune regulation are discussed.

Fine specificity of the myelin-reactive T cell repertoire: implications for TCR antagonism in autoimmunity.

The use of altered peptide ligands (APL) to modulate T cell responses has been suggested as a means of treating T cell-mediated autoimmune disorders. We have assessed the therapeutic potential of TCR antagonist peptides in autoimmunity using murine experimental autoimmune encephalomyelitis (EAE) as a model. The Tg4 transgenic mouse expresses an MHC class II-restricted TCR specific for the immunodominant encephalitogenic epitope of myelin basic protein, Ac1-9 (acetylated N-terminal nonamer). We have used T cell lines derived from Tg4 mice to define the TCR contact residues within Ac1-9. APL with appropriate substitutions at the primary TCR contact residue were effective antagonists of Tg4 T cells. These antagonist APL, however, were found to induce EAE in susceptible, nontransgenic strains of mice. Underlying this, the Ac1-9-specific T cell repertoire of normal mice, rather than reflecting the Tg4 phenotype, showed considerable diversity in fine specificity and was able to respond to the Tg4 antagonist APL. Defining antagonist APL in vitro using T cell clones, therefore, was not a reliable approach for the identification of APL with EAE-suppressing potential in vivo. Our findings highlight the complexities of the autoreactive T cell repertoire and have major implications for the use of APL in autoimmune diseases.

Antigen-specific tolerance induction and the immunotherapy of experimental autoimmune disease.

Antigen-specific tolerance induction is the ultimate goal for specific immunotherapy of autoimmune diseases. Here we will discuss recent experiments designed to induce tolerance following mucosal administration of antigens in a mouse model of experimental autoimmune encephalomyelitis (EAE). We were unable to induce oral tolerance either with whole myelin, myelin basic protein (MBP) or the immunodominant peptide antigen. Oral tolerance was possible, however, with an analogue of the immunodominant peptide modified to increase its affinity for the restricting major histocompatibility complex (MHC) antigen. By contrast, intranasal deposition of peptide antigen proved highly effective for both prevention and treatment of EAE. Prevention of disease was directly related to the antigenic property of the peptide which, in itself, was related to affinity for MHC. Notably, administration of a single peptide was shown to inhibit disease involving multiple epitopes. We investigated the resulting bystander regulation by studying the cellular basis of peripheral tolerance in a transgenic model. These studies indicate that bystander regulation may be the consequence of selective cytokine secretion.

Qualitative and quantitative effects of CD28/B7-mediated costimulation on naive T cells in vitro.

The CD28/B7 system provides costimulatory signals necessary for optimal T cell activation. We have examined the effects of blocking B7.1 and/or B7.2 in an in vitro system using TCR transgenic T cells specific for myelin basic protein. Activation of naive T cells was found to be B7.2 dependent and not dependent on the presence of B7.1 molecules. However, increasing the strength of signal through the TCR using peptide analogues with higher affinity for MHC compensated for blockade of B7.2 molecules, suggesting that signal 1 alone can be sufficient for the activation of naive T cells. The role of B7 molecules in the differentiation of T cells was further investigated by restimulating T cells with fresh APC and peptide in B7-sufficient conditions. A down-regulation of IL-2 and IFN-gamma production by T cells primed in the presence of anti-B7.2 mAb was partially overcome when high affinity peptide analogues were used to restimulate T cells. In contrast, a significant down-regulation of the differentiation of cells producing Th-2 cytokines was observed in the presence of anti-B7 Abs. Differentiation of IL-4-secreting cells was influenced by both B7.1 and B7.2, while IL-5 secretion was totally dependent on B7.2. These results suggest that B7-mediated costimulation is essential for the development of Th-2-associated cytokines, the absence of which cannot be overcome by increasing the strength of the signal through the TCR.

Identification of an indirectly presented epitope in a mouse model of skin allograft rejection.

BACKGROUND: The indirect pathway of allorecognition involves the processing and presentation of donor molecules by recipient antigen-presenting cells to alloreactive CD4+ T cells. Our objective was to assess the occurrence and significance of the indirect presentation of allogeneic major histocompatibility complex molecules in the rejection of major histocompatibility complex class I-disparate skin. METHODS: A mouse model of allograft rejection was developed in which tail skin from C57.BL/10 (H2b) donors was transplanted onto B10.A(5R) recipients resulting in an allogeneic mismatch at the D locus. T-cell depletion studies were used to characterize T-cell subset involvement in rejection. B10.A(5R) mice were immunized with pools of overlapping peptides spanning the polymorphic region of Db in order to identify Db-derived epitopes involved in rejection. The relevance of these epitopes was assessed through immunization of recipient mice with peptides before skin grafting to observe the effect of presensitization on the kinetics of rejection. RESULTS: Rejection of Db-disparate skin by B10.A(5R) was delayed by CD4 and CD8+ T-cell depletion, indicating the significance of both cell types in rejection. At least six immunogenic peptides were identified, all of which contained a cryptic T-cell epitope. One peptide, however, was able to accelerate the rejection of Db-disparate skin. Presensitization of B10.A(5R) mice with this peptide also resulted in an increase in alloantibody, indicating the presence of a physiological as well as a cryptic epitope. Presensitization of mice with a peptide containing a distinct cryptic epitope, however, failed to influence rejection. CONCLUSIONS: These findings demonstrate a significant role for the indirect pathway of antigen presentation in allograft rejection.