Bishwajit Nag

Induction of tolerance in experimental autoimmune myasthenia gravis with solubilized MHC class II : acetylcholine receptor peptide complexes

Stimulation of T lymphocytes through the T cell receptor in the absence of costimulatory signal(s) induces a state of unresponsiveness to subsequent antigen presentation. We have employed solubilized complexes consisting of rat class II MHC molecules containing an immunodominant peptide of the acetylcholine receptor (AChR alpha 100-116) to induce unresponsiveness in the autoreactive T lymphocytes mediating an animal model of myasthenia gravis. In vitro incubation of rat T cell lines specific for peptide AChR alpha 100-116 with solubilized complexes of MHC II and AChR alpha 100-116 (MHC II:AChR alpha 100-116) rendered the T cells unresponsive to subsequent stimulation by antigen presenting cells and the peptide. T cell lines with a broader specificity to the entire AChR protein pentamer had an 81% reduction in proliferation to AChR following a preincubation with solubilized MHC II:AChR alpha 100-116. Treatment with the solubilized MHC II:AChR alpha 100-116 induced phosphatidylinositol 4,5-bisphosphate hydrolysis, an early signalling event associated with binding to the TCR. Rats primed with AChR and injected intravenously with MHC II:AChR alpha 100-116 had reduced in vitro T cell proliferation to the AChR alpha 100-116 peptide and to whole AChR. Solubilized MHC II:AChR alpha 100-116 injected i.v. into rats exhibiting serological clinical symptoms of experimental autoimmune myasthenia gravis (EAMG) prevented death in 67% of the treated animals, compared to a 0-20% survival rate in all other control groups. These results demonstrate that solubilized MHC II complexed with an immunodominant autoantigenic peptide is tolerogenic and improves the survival rate of rats with EAMG, suggesting the basis for an antigen-specific therapy in autoimmune diseases such as MG.

Synthesis and structure-activity relationship studies of cinnamic acid-based novel thiazolidinedione antihyperglycemic agents.

A number of 2,4-thiazolidinedione derivatives of -phenyl substituted cinnamic acid were synthesized and studied for their PPAR agonist activity. The E-isomer of cinnamic acid, 11, showed moderate PPAR transactivation. The corresponding Z-isomer, 23, and double bond reduced derivative, 15, were found to be much less potent. Although the E-isomer showed a moderate PPAR gamma transactivation, it demonstrated a strong glucose-lowering effect in a genetic rodent model of diabetes. Results of pharmacokinetic, metabolism and permeability studies are consistent with 11 being an active prodrug with an active metabolite, 14, that has similar glucose lowering and PPAR gamma agonist properties.

A novel peroxisome proliferator-activated gamma (PPARγ) agonist, CLX-0921, has potent antihyperglycemic activity with low adipogenic potential

Agonists of the nuclear receptor peroxisome proliferator-activated receptor gamma (PPAR gamma) are pharmacologically active antihyperglycemic agents that act by increasing peripheral tissue sensitivity to insulin. Many of these agonists have antihyperglycemic activity that is directly proportional to their ability to bind and activate PPAR gamma; however, recent data bring this relationship into question. In this report we describe a new PPAR gamma agonist, CLX-0921, that is derived from a natural product. This thiazolidinedione (TZD) has a spectrum of activity that differs from commercially available TZDs. It is a weak activator of PPAR gamma (EC(50) of 0.284 micromol/L) compared to rosiglitazone (EC(50) 0.009 micromol/L). Despite this difference, the drug maintains potent glucose uptake activity in vitro and glucose-lowering activity in vivo that is equipotent to that of rosiglitazone. Moreover, CLX-0921 showed a 10-fold reduction in in vitro adipogenic potential compared to rosiglitazone. CLX-0921 also increases glycogen synthesis, an activity not typically associated with rosiglitazone or pioglitazone. Thus CLX-0921 appears to have a distinct spectrum of activity relative to other TZDs.

ANTIGEN-SPECIFIC APOPTOSIS IN IMMORTALIZED T CELLS BY SOLUBLE MHC CLASS II-PEPTIDE COMPLEXES

The recognition of T cell receptors (TCR) by purified major histocompatibility complex (MHC) class II‐peptide complexes in the absence of costimulatory signals leads to the induction of T cell nonresponsiveness or anergy. In a recent study using human T cell clones, it was observed that prolonged incubation of resting T cells with soluble MHC II‐peptide complexes appears to result in T cell apoptosis. The present study shows that the engagement of TCR by soluble MHC II‐peptide complexes also results in antigen‐specific apoptosis in immortalized T cells. Apoptosis was demonstrated in a herpes saimiri virus (HSV) transformed human T cell clone (SS8T) restricted for HLA‐DR2 in association with an epitope from the myelin basic protein [MBP(84–102)]. A dose‐ and time‐dependent T cell death was observed upon incubation of SS8T cloned T cells with purified complexes of native human HLA‐DR2 and MBP(83–102)Y83 peptide. The specificity of T cell apoptosis was demonstrated by exposing SS8T cells with DR2 alone and DR2 bound to another high affinity epitope [MBP(124–143)] from the same MBP. Recently, we have shown that the complexes of HLA‐DR2 and [MBP(83–102)Y83] can be reconstituted by refolding Escherichia coli expressed individual DR2 a and β (B5*010l) polypeptide chains lacking the transmembrane region. When SS8T cloned T cells were exposed to purified reconstituted rDR2.MBP(83–102)Y83 complexes, similar apoptosis of T cells was observed. Agarose gel analysis of T cells incubated with complexes showed a degradation of celluar deoxyribonucleic acid (DNA) to oligonucleosomal bands, a characteristic of apoptosis. The quantitative detection of DNA strand breaks was performed by pulsing T cells with 5‐bromo‐2′‐deoxyuridine(BrdU) followed by the detection of BrdU‐labelled DNA fragments using an antibody sandwich enzyme‐linked immuno assay (ELISA). The fragmentation of DNA was also measured by double fluorescence flow cytometry by 3′ end labelling of fragmented DNA with biotinylated‐deoxyuridine triphosphate (dUTP) in the presence of terminal deoxynucleotide transferase (TdT) enzyme. The expression of the bel‐2 protein in SS8T cells following TCR engagement by soluble MHC II‐peptide complexes was monitored by chemiluminescence blot analysis using anti‐bel‐2 monoclonal antibody. Finally, the nucleosomal condensation of T cells following complex treatment, characteristics of typical apoptosis, was demonstrated by transmission electron microscopy. These results suggest that the binding of soluble MHC class II‐peptide complexes to TCR induces antigen‐specific apoptosis in transformed CD4 positive T cells in vitro. Such induction of apoptosis by soluble MHC II‐peptide complexes may provide a novel therapeutic strategy to delete autoreactive T cells in various autoimmune diseases.

Antigenic peptide binding to MHC class II molecules at increased peptide concentrations

Affinity-purified major histocompatibility complex (MHC) class II molecules are known to bind antigenic peptides in vitro. The percentage of MHC class II molecules occupied with such peptides is usually very low and varies significantly depending upon the sequence and size of a given antigenic peptide. The present study describes a method by which complete saturation of affinity-purified MHC class II with antigenic peptide can be achieved by simply incubating purified MHC class II molecules at neutral pH in the presence of several 100-fold molar excess of antigenic peptide. Complexes of human HLA-DR2 and a peptide analog from human myelin basic protein MBP (83-102)Y83 were selected for this study. The on-rate kinetic results showed saturation of MHC class II occupancy at 300-500-fold molar excess peptide concentrations. The specificity of the MBP (83-102)Y83 peptide binding to HLA-DR2 at higher peptide concentration was demonstrated by incubating an equivalent amount of another epitope from myelin basic protein [MBP (1-14) peptide] as well as by competitive binding assays. The quantitation of bound peptide was carried out using biotinylated-MBP (83-102)Y83 peptide which showed 100-125% occupancy of HLA-DR2 with a recovery of 100%. The presence of a single peptide entity in purified complexes was confirmed by reverse-phase narrowbore HPLC analysis of the acid extracted supernatant and by mass spectrometry analysis. Two-dimensional gel electrophoresis (IEF/SDS) of purified HLA-DR2 and DR2.MBP (83-102)Y83 complexes showed the absence of various endogenous polypeptides in 100% loaded complexes. These results demonstrate that higher peptide concentrations can be useful in generating MHC class II-peptide complexes of defined composition. Such complexes of MHC class II occupied with a single peptide may have significant clinical relevance for antigen-specific therapy of various autoimmune diseases and may provide better understanding of MHC-peptide-TCR interactions.

Separation of complexes of major histocompatibility class II molecules and known antigenic peptide by metal chelate affinity chromatography

A small fraction of affinity-purified MHC class II molecules are known to bind antigenic peptides in vitro. No simple method with acceptable recovery exists for separation of complexes of a known antigenic epitope and MHC class II from empty MHC class II and complexes of MHC class II and endogenously bound peptide. Here we describe an one step metal chelate affinity chromatography method to purify complexes of MHC class II and antigenic peptide of known composition. Complexes of human HLA-DR2 (DRB1*1501/DRB5*0101) and a peptide analog from human myelin basic protein MBP(84-102) containing a 6 histidine tag (6 x His) and a tyrosine residue at the N-terminus end [6 x His-MBP(83-102)Y83] were prepared and purified. The absence of residual free 6 x His-MBP peptide in the complex preparations were confirmed by gel filtration and TLC analyses. The purified complexes were applied onto Ni2+.nitrilotriacetic acid (Ni2+.NTA)-agarose affinity support and 6 x His-tagged peptide class II complexes were selectively eluted with imidazole-containing buffer. The quantitation of bound peptide in the eluted complexes showed 100% occupancy of HLA-DR2 (DRB1*1501/DRB5*0101) with [6 x His-MBP(83-102)Y83] peptide with a recovery of 50-75%. The presence of a single peptide entity in the eluted complexes was confirmed by reverse-phase narrowbore HPLC analysis of the acid-extracted supernatant and by amino acid sequencing analyses. As expected, no endogenous polypeptide was detected in the Ni2+.NTA eluted complexes when analyzed by two-dimensional IEF gel electrophoresis. Finally, we demonstrate that both MBP(84-102) and [6 x His-MBP(83-102)Y83] peptides were equally capable of stimulating restricted T cell line in the presence of autologous antigen presenting cells (APCs). These results demonstrate that metal chelate affinity chromatography can be used to prepare MHC class II-peptide complexes containing single peptide. Such complexes of class II molecules containing known peptide have significant clinical relevance for antigen-specific therapy of various autoimmune diseases and may provide better understanding of the trimolecular interaction between MHC class II, antigenic peptide and T cell receptor (TCR).

Vaccination with peptides from MHC class II beta chain hypervariable region causes allele-specific suppression of EAE

In our earlier studies we showed that successful immunotherapy of EAE in SJL/J mice can be achieved either by the use of antibodies to MHC class II antigens or by vaccination with synthetic peptide analogs of the beta chain of MHC class II molecules. We proposed that inhibition of EAE following vaccination with synthetic peptides derived from the beta chain of mouse I-A, was in part due to the generation of auto-anti-MHC class II antibodies that interfered with T cell sensitization. In our present study we show that suppression of EAE following vaccination results in poor sensitization of MBP reactive T cells, and that the lack of immune response is allele-specific. In F1(SJL(I-AS) x Balb/cI-Ad) mice, in which susceptibility to EAE is linked closely to the I-AS allele, vaccination with peptides from beta chain of I-AS results in inhibition of proliferative response to MBP and prevents the development of EAE. Vaccination with peptide from the beta chain of I-Ad did not affect either the development of immune response to MBP or the induction of EAE, indicating allele-specific suppression. Since global immunosuppression is not induced by vaccination with I-A peptides, we propose that this strategy can be extended to human autoimmune diseases wherein a clear association between certain MHC class II alleles and autoimmune disease is evident.

The role of N-linked oligosaccharides of MHC class II antigens in T cell stimulation

A specific increase in T cell extracellular acidification rate has been demonstrated recently when complexes of purified MHC class II molecules and antigenic peptides interact with T cell receptors (TCRs) on cloned T cells. The present study shows that such measurements of an increase in extracellular acidification rate can be used to evaluate the functional role of various N-linked oligosaccharides of MHC class II antigens. Affinity-purified murine IAk and IAs were deglycosylated in the presence of aspargine-amidase enzyme and were characterized by SDS-polyacrylamide gel electrophoresis. The complete removal of all three N-linked oligosaccharides from the alpha/beta heterodimer was confirmed by four different lectin-linked Western blot analyses. Similar to the native heterodimer, both deglycosylated IAk and deglycosylated IAs were fully capable of binding synthetic antigenic peptides derived from myelin basic protein (MBP). When equivalent amount of glycosylated and deglycosylated class II-peptide complexes were exposed to restricted cloned T cells, identical increases in T cell extracellular acidification rates were observed. The specificity of such increases in extracellular acidification rate was demonstrated by exposing cloned T cells to irrelevant complexes of glycosylated and deglycosylated class II and antigenic peptides. These results show how measurement of extracellular acidification rate can be used to study structure-function correlations of ligand-receptor interactions, and support an earlier observation that N-linked oligosaccharides of murine MHC class II molecules are not involved in either antigenic peptide binding or T cell recognition.

pH dependent binding of high and low affinity myelin basic protein peptides to purified HLA-DR2.

Major histocompatibility complex (MHC) class II molecules are cell surface glycoproteins and are known to display processed antigens on the surface of antigen presenting cells (APC). Within the APC, the loading of processed antigenic peptides to MHC class II molecules is known to take place in the endosomal compartment at acidic pH environment. The present study describes the in vitro effect of pH on binding of four biotinylated myelin basic protein (MBP) peptides to affinity purified HLA-DR2 containing a mixture of DRB1*1501 and DRB5*0101 beta chain. The binding affinity of the selected peptides are in the order of MBP(83-102)Y83 > MBP(124-143) > MBP(143-168) > MBP(1-14). Most of these peptides in association with HLA-DR2 are considered as immunodominant epitopes for human multiple sclerosis autoimmune disorder. One epitope, MBP(1-14), had almost no affinity to purified HLA-DR2 and was used as a control peptide in all binding assays. The quantitation of the bound peptide at various pH was carried out by antibody capture of complexes followed by avidin-alkaline phosphatase detection system. Among four peptides tested, only the highest affinity MBP(83-102)Y83 peptide showed maximum binding to purified HLA-DR2 at acidic pH. Two other epitopes, MBP(124-143) and MBP(143-168), showed maximum binding at basic and neutral pH values, respectively. The binding of only high affinity peptides, MBP(83-102)Y83 and MBP(124-143), was significantly affected by changing the pH of the binding buffer. Such alteration in pH of the binding buffer resulted in 100% occupancy of DR2 with both high affinity MBP peptides. In contrast, no significant increase in binding of the low affinity MBP(143-168) peptide was observed at altered pH values. The specificity of the increased binding of high affinity peptides to HLA-DR2 at optimum pH was demonstrated by competitive binding assays using non-biotinylated peptides. Finally, the stability of various MBP peptide bound complexes was tested at 4 degrees, 25 degrees and 37 degrees C which correlates well with their affinity to HLA-DR2. These results suggest that pH plays an important role in in vitro binding of antigenic peptides and such manipulation of binding conditions can be utilized in generating 100% loaded MHC class II with high affinity antigenic peptides. Since high affinity peptides are generally considered as major immunodominant epitopes, the in vitro pH dependent binding can be utilized in screening immunodominant epitopes of various autoantigens and generating complexes of defined composition.

Identification of core structure and critical T cell receptor contact residues in an antigenic peptide by measuring acidification rates

A silicon-based biosensor microphysiometer measures real time cell response by monitoring an increase in extracellular acidification rate in response to ligands for specific membrane receptors. We used the microphysiometer to identify the minimal structure and critical residues of an antigenic peptide for its interaction with T cell receptor (TCR) using a synthetic peptide analog of human myelin basic protein (MBP) corresponding to residues 84-102 [MBP(83-102)Y83]. MBP(83-102)Y83 peptide analogs were allowed to interact with TCRs on a DRB5*0101-restricted Herpes virus saimiri (HVS) transformed human T cell clone (SS8T) which also contains major histocompatibility complexes (MHC) class II (DR2) molecules. Cultured SS8T cells were exposed to 11 N-terminus and 11 C-terminus truncated peptides separately in the microphysiometer chambers to determine the minimal amino acid residues required for the T cell response. In parallel, 13 analogs of the MBP(83-102)Y83 peptide with single alanine substitutions were tested in this assay to identify critical amino acid residues involved in TCR interactions. A minimal core length of MBP(91-100) peptide and residues F-91, K-93, N-94, I-95 and V-96 were essential for TCR interaction. Acidification rate measurements correlated well with enhanced levels of gamma-IFN (interferon gamma) and TNF-beta cytokine production and suggested that the increase in the extracellular acidification rate is a direct result of early T cell signaling events.