Activated contact system and abnormal glycosaminoglycans in lupus and other auto- and non-autoimmune diseases.

Systemic lupus erythematosus (SLE), heparin-induced thrombocytopenia (HIT), rheumatoid arthritis (RA) are marked by the presence of autoantibodies against negatively changed DNA, phospholipids, heparin, and chondroitin sulfate, respectively. Heparin/protein complexes induce contact system activation in HIT patient plasmas. The activated contact system generates thrombin. Thrombin is responsible for thrombosis, a common cause of death and disabilities for both HIT and SLE. In this chapter, we analyze plasma contact system proteins, thrombin- and kallikrein-like activities, glucosamine and galactosamine content from SLE-, RA-, osteoarthritis (OA)-, and psoriasis (Ps)-patient plasmas in addition to pooled 30+ healthy patient plasmas. We found that all SLE patient plasmas exhibited abnormal contact systems marked by the absence of high molecular weight kininogen, the presence of processed C1 inhibitor (C1inh), the display of abnormal thrombin- and kallikrein-like activities, and increased levels of plasma glucosamine and galactosamine. Different patterns of contact system activation distinguish SLE, RA, and Ps whereas no contact system activation is observed in normal and OA patient plasmas. The presence of paradoxical "lupus anticoagulants" in certain thrombosis-prone SLE patient plasmas, marked by delayed clotting in clinical plasma test, was explained by the consumption of contact system proteins, especially high molecular weight kininogen. Finally, we discovered that mouse and human SLE autoantibodies bind to cell surface GAGs with structural selectivity. In conclusion, markers of abnormal contact system activation represent potential new targets for autoimmune disease diagnosis, prevention, and treatment. These markers might also be useful in monitoring SLE activity/severity and in pinpointing patients with SLE-associated arthritis and psoriasis.

Heparin and oversulfated heparin byproduct induce thrombin generation through contact system activation in plasma of patients with HIT.

Heparin-induced thrombocytopenia with thrombosis (HITT) is the most severe side effect of heparin administration. Patients with HITT may die or have permanent sequelae such as stroke or limb amputation. Contaminated heparin is associated with anaphylactic reactions and deaths by activating the contact system. It is also associated with high incidence of HIT via a yet unknown mechanism. This study showed that although oversulfated heparin byproduct induced thrombin activities in both normal and HIT patient plasmas through the contact system activation, authentic heparin induced thrombin activities only in HIT patient plasmas containing autoantibodies against protein/ heparin complex. These data suggest that the negatively charged immunoglobulin G (IgG)/platelet factor 4 (PF4)/heparin complex activate the contact system and produce thrombin in human plasma, and thrombin partially activates the platelets allowing subsequent platelet activation through IgG/Fc receptor II signaling. The newly discovered mechanism of heparin-induced thrombin activity could explain the increased incidence of HIT in patients exposed to contaminated heparin. Furthermore, the assays used in these studies would be valuable for HIT diagnosis, prevention, and treatment.

High affinity glycosaminoglycan and autoantigen interaction explains joint specificity in a mouse model of rheumatoid arthritis.

In the K/BxN mouse model of rheumatoid arthritis, autoantibodies specific for glucose-6-phosphate isomerase (GPI) can transfer joint-specific inflammation to most strains of normal mice. Binding of GPI and autoantibody to the joint surface is a prerequisite for joint-specific inflammation. However, how GPI localizes to the joint remains unclear. We show that glycosaminoglycans (GAGs) are the high affinity (83 nm) joint receptors for GPI. The binding affinity and structural differences between mouse paw/ankle GAGs and elbows/knee GAGs correlated with the distal to proximal disease severity in these joints. We found that cartilage surface GPI binding was greatly reduced by either chondroitinase ABC or beta-glucuronidase treatment. We also identified several inhibitors that inhibit both GPI/GAG interaction and GPI enzymatic activities, which suggests that the GPI GAG-binding domain overlaps with the active site of GPI enzyme. Our studies raise the possibility that GAGs are the receptors for other autoantigens involved in joint-specific inflammatory responses.

Increased number and function of FoxP3 regulatory T cells during experimental arthritis.

OBJECTIVE: CD4+CD25+FoxP3+ regulatory T (Treg) cells are critical regulators of autoimmunity. Yet the number of Treg cells is paradoxically increased in rheumatoid arthritis (RA) patients, and Treg cells show variable activity in human studies. The objective of this study was to characterize the expansion and function of Treg cells during the initiation and progression of experimental arthritis. METHODS: To unequivocally identify Treg cells, we crossed FoxP3gfp mice with K/BxN mice to generate arthritic mice in which Treg cells express green fluorescence protein. We examined the expansion and function of Treg cells and effector T (Teff) cells during different stages of arthritis, using flow cytometry and cell proliferation analyses. RESULTS: In K/BxN mice, thymic selection of KRN T cells resulted in an enrichment of forkhead box P3 (FoxP3)-positive Treg cells. Treg cell numbers increased during arthritis, with significant increases in spleens and draining lymph nodes, indicating selective tropism to sites of disease. In contrast to the in vitro unresponsiveness of Treg cells when cultured alone, substantial proportions of Treg cells proliferated in both nonarthritic and arthritic mice. However, they also underwent greater apoptosis, thereby maintaining equilibrium with Teff cells. Similarly, enhanced Treg cell-suppressive activity during arthritis was offset by greater resistance by their Teff cell counterparts and antigen-presenting cells. CONCLUSION: In this well-established model of RA, the interplay of Teff cells and Treg cells in K/BxN mice recapitulated many features of the human disease. We demonstrated an ordered expansion of Treg cells during arthritis and dynamic changes in Treg cell and Teff cell functions. By elucidating factors that govern Treg cell and Teff cell development in K/BxN(gfp) mice, we will gain insight into the pathophysiology of and develop novel therapeutics for human RA.

Rituximab for the treatment of juvenile dermatomyositis: a report of four pediatric patients.

OBJECTIVE: Juvenile dermatomyositis (DM) is a chronic inflammatory myopathy of childhood primarily affecting the muscles and skin. Treatment for juvenile DM is often difficult, and conventional therapies include corticosteroids and other immune suppressants. We reviewed the records of 4 patients with juvenile DM who received the B cell-depleting anti-CD20 monoclonal antibody rituximab to determine whether this therapy resulted in improved control of their juvenile DM. METHODS: This is a retrospective review of 4 pediatric patients ages 10-17 years with juvenile DM who were treated with rituximab. All patients were tested for myositis autoantibodies and received weekly rituximab infusions for a total of 4 doses. Two patients received repeat courses of rituximab 1 year after their first dose. Patients were followed up between 12 and 24 months after their first course of rituximab, and their strength, muscle enzymes, and rash were reviewed. RESULTS: One patient was positive for a myositis-specific antibody, anti-Mi-2, and demonstrated striking reductions in her muscle enzyme levels for 1 year after rituximab therapy. Following a second course of rituximab, this patient remained disease free for 14 months before requiring a third course of rituximab. Two myositis antibody-negative patients showed clinical improvement and tolerated lower doses of corticosteroids following treatment with rituximab. Finally, 1 patient had worsening of her disease following rituximab. CONCLUSION: These cases highlight the potential for anti-B cell therapies in the treatment of juvenile DM in both myositis-specific autoantibody-positive and -negative patients.

Differential MHC class II presentation of a pathogenic autoantigen during health and disease.

Glucose-6-phosphate isomerase (GPI) is the target autoantigen recognized by KRN T cells in the K/BxN model of rheumatoid arthritis. T cell reactivity to this ubiquitous Ag results in the recruitment of anti-GPI B cells and subsequent immune complex-mediated arthritis. Because all APCs have the capacity to process and present this autoantigen, it is unclear why systemic autoimmunity with polyclonal B cell activation does not ensue. To this end, we examined how GPI is presented by B cells relative to other immunologically relevant APCs such as dendritic cells (DCs) and macrophages in the steady state, during different phases of arthritis development, and after TLR stimulation. Although all APCs can process and present the GPI:I-A(g7) complex, they do so with different efficiencies. DCs are the most potent at baseline and become progressively more potent with disease development correlating with immune complex uptake. Interestingly, in vivo and in vitro maturation of DCs did not enhance GPI presentation, suggesting that DCs use mechanisms to regulate the presentation of self-peptides. Non-GPI-specific B cells are the weakest APCs (100-fold less potent than DCs) and fail to productively engage KRN T cells at steady state and during arthritis. However, the ability to stimulate KRN T cells is strongly enhanced in B cells after TLR ligation and provides a mechanism whereby polyclonal B cells may be activated in the wake of an acute infection.

T cells are not as degenerate as you think, once you get to know them.

In this review, we dissect two different antigen systems which represent the apparent extremes of T cell receptor (TCR) recognition. In the hemoglobin (Hb) system, a minor change in a single MHC anchor residue disrupts TCR recognition. In the KRN system, a single TCR shows strong reactivity to two peptides from unrelated proteins, presented by different MHC molecules. Upon closer analysis, both turn out to be specific recognition events, following set rules of engagement. Thus, although a TCR can recognize multiple ligands sharing minimal sequence homology, this recognition is still highly specific and is constrained by the same structural requirements. TCR degeneracy is therefore limited and is unlikely to be a major mechanism for autoimmunity.

Massive thymic deletion results in systemic autoimmunity through elimination of CD4+ CD25+ T regulatory cells.

Incomplete deletion of KRN T cells that recognize the ubiquitously expressed self-antigen glucose-6-phosphate-isomerase (GPI) initiates an anti-GPI autoimmune cascade in K/BxN mice resulting in a humorally mediated arthritis. Transgenic (Tg) expression of a KRN T cell receptor (TCR) agonist under the major histocompatibility complex class II promoter resulted in thymic deletion with loss of anti-GPI T and B cell responses and attenuated arthritis course. However, double Tg mice succumbed to systemic autoimmunity with multiorgan inflammation and autoantibody production. Extensive thymic deletion resulted in lymphopenia and elimination of CD4+ CD25+ regulatory T cells (Tregs), but spared some CD4+ T cells expressing endogenous TCR, which oligoclonally expanded in the periphery. Disease was transferred by these T cells and prevented by cotransfer of CD4+ CD25+ Tregs. Moreover, we extended our findings to another TCR system (anti-hen egg lysozyme [HEL] TCR/HEL mice) where similarly extensive thymic deletion also resulted in disease. Thus, our studies demonstrated that central tolerance can paradoxically result in systemic autoimmunity through differential susceptibility of Tregs and autoreactive T cells to thymic deletion. Therefore, too little or too much negative selection to a self-antigen can result in systemic autoimmunity and disease.

Despite ubiquitous autoantigen expression, arthritogenic autoantibody response initiates in the local lymph node.

K/BxN mice develop an inflammatory joint disease with many features characteristic of rheumatoid arthritis. In this model, the KRN transgenic T cells and nontransgenic B cells both recognize the glycolytic enzyme glucose-6-phosphate-isomerase (GPI) as an autoantigen. Here, we followed the anti-GPI B cell response that naturally arises in K/BxN mice. The anti-GPI B cell response was robust and arose at the same time as the development of serum anti-GPI autoantibody and joint inflammation. Surprisingly, although GPI was expressed systemically, the anti-GPI B cell response was focused to the lymph nodes (LN) draining the distal joints where arthritis was evident. In lymphotoxin-beta receptor-Ig-treated mice, which lack LNs, the development of arthritis was completely inhibited up to 5-6 weeks. At later times, some arthritis did develop, but at a significantly reduced level. Thus, in this spontaneous model of autoimmunity, the LNs draining the distal joints are essential for both the inhibition and amplification of the arthritogenic B cell response. These findings imply that the immune physiology of a joint is unique, resulting in a local immune response to a systemic autoantigen.