Immune complexes from rheumatoid arthritis synovial fluid induce FcγRIIa dependent and rheumatoid factor correlated production of tumour necrosis factor-α by peripheral blood mononuclear cells

Immune complexes (ICs) can induce production of cytokines by peripheral blood mononuclear cells via Fc receptors. Rheumatoid factor (RF) develop in response to ICs in many clinical and experimental settings. We investigated whether and how polyethylene glycol (PEG) precipitated ICs from rheumatoid arthritis (RA) sera and synovial fluid (SF) can influence cytokine production by peripheral blood mononuclear cells. We also examined the relationship between RF and IC induced cytokine production. Parallel sera and SF from 47 RA patients and sera from 15 healthy control individuals were PEG precipitated. The precipitates were added to serum-free peripheral blood mononuclear cell cultures and tumour necrosis factor (TNF)-α levels were measured after 20 hours. In separate cell culture experiments FcγRIIa and FcγRIII were blocked and monocytes were depleted or enriched. RF in serum was determined by nephelometry, and IgG levels in precipitates and anti-cyclic citrullinated peptide antibodies in serum were measured using ELISA. Clinical data were collected from the patients' charts. In two separate investigations, we demonstrated a correlation between RF, PEG-precipitated IgG levels and induction of the proinflammatory cytokine TNF-α by PEG-precipitated SF ICs. No such correlation was found for serum ICs. TNF-α levels induced by SF precipitates, but not serum precipitates, correlated with the number of swollen and tender joints. Monocytes/macrophages were shown to be the main responder cells, and blockade of FcγRIIa, but not blockade of FcγRIII, inhibited TNF-α production in cultures stimulated with precipitated ICs. Anti-cyclic citrullinated peptide correlated with RF but exhibited no association with IgG content in PEG precipitates or with precipitate-induced TNF-α levels. These findings support the hypothesis that SF ICs and correlated RF production are directly linked to cytokine-dependent inflammation in RA. Suppression of monocytes/macrophages in RA joints or blockade of the primate-specific activating FcγRIIa receptor might be ways to reduce IC-induced TNF-α production in the joints of seropositive RA patients

Microarray testing in patients with systemic lupus erythematosus identifies a high prevalence of CpG DNA-binding antibodies

OBJECTIVE: Many autoantibodies are known to be associated with SLE, although their role in clinical practice is limited because of low sensitivity and weak associations with clinical manifestations. There has been great interest in the discovery of new autoantibodies to use in clinical practice. In this study, we investigated 57 new and known antibodies and their potential for diagnostics or risk stratification. METHODS: Between 2014 and 2017, residual sera of all anti-dsDNA tests in the UMC Utrecht were stored in a biobank. This included sera of patients with SLE, patients with a diagnosis of another immune-mediated inflammatory disease (IMID), patients with low (non-IMID) or medium levels of clinical suspicion of SLE but no IMID diagnosis (Rest), and self-reported healthy blood bank donors. Diagnosis and (presence of) symptoms at each blood draw were retrospectively assessed in the patient records with the Utrecht Patient-Oriented Database using a newly developed text mining algorithm. Sera of patients were analysed for the presence of 57 autoantibodies with a custom-made immunofluorescent microarray. Signal intensity cut-offs for all antigens on the microarray were set to the 95th percentile of the non-IMID control group. Differences in prevalence of autoantibodies between patients with SLE and control groups were assessed. RESULTS: Autoantibody profiles of 483 patients with SLE were compared with autoantibody profiles of 1397 patients from 4 different control groups. Anti-dsDNA was the most distinguishing feature between patients with SLE and other patients, followed by antibodies against Cytosine-phosphate-Guanine (anti-CpG) DNA motifs (p<0.0001). Antibodies against CMV (cytomegalovirus) and ASCA (anti-Saccharomyces cerevisiae antibodies) were more prevalent in patients with SLE with (a history of) lupus nephritis than patients with SLE without nephritis. CONCLUSION: Antibodies against CpG DNA motifs are prevalent in patients with SLE. Anti-CMV antibodies are associated with lupus nephritis

Microarray analysis of autoantibodies can identify future Systemic Lupus Erythematosus patients

OBJECTIVE: Reliable early ascertainment in patients with SLE is important to prevent the accumulation of irreversible organ damage. Autoantibodies are often present in the serum of patients before the first symptoms arise, therefore they are of potential use as early diagnostic tools. METHODS: We used a custom-made antibody microarray containing 57 autoantigens to analyze serum samples of 1519 patients previously tested for anti-dsDNA and 361 samples of self-reported healthy blood bank donors (BBD). The 1519 patients included 483 patients with SLE, 346 patients with other immune mediated inflammatory diseases (IMID), 218 patient controls without relevant clinical symptoms (Non-IMID), and 472 patients that did not fit in any of the previous groups (Rest). The Non-IMID and BBD groups were used individually to create multivariable prediction models to distinguish samples of patients with SLE from these control groups. We subsequently used these models to predict the outcome for samples of patients who developed SLE while in follow-up (pre-SLE). RESULTS: Out of 1036 patients with no diagnosis of SLE at the moment of sample collection, 17 patients developed SLE while in follow-up (mean time to diagnosis 7.2 months). The best performing model (AUC 0.83) identified 9 out of 17 (53%) pre-SLE samples as SLE, with a specificity of 94%. CONCLUSION: Serum samples of patients who will develop SLE in the future already show a shift of the autoantibody profile prior to diagnosis. In this study, we show that these autoantibody profiles can be used to identify these future SLE patients

Immune Complex Regulated Cytokine Production in Rheumatic and Lymphoproliferative Diseases

Immune complexes (ICs) are produced during normal immune responses and facilitate clearance of foreign antigens. ICs not efficiently cleared from the circulation can cause tissue damage. This might happen if ICs are formed with autoantibodies and autoantigens. Well described effects of ICs are neutralization of antigen, classical complement activation or FcR-mediated phagocytosis, whereas cytokine inducing effects of ICs in human clinical settings are less well described. I have investigated cytokine-inducing properties in vitro of ICs from patients with rheumatoid arthritis (RA), systemic lupus erythematosus (SLE) and cryoglobulinemia in association with lymphoproliferative diseases. Cryoglobulin (CG)-induced cytokine production varied with changes in temperature and ionic strength in parallel to CG precipitation. IgG CG-induced cytokine production was also mediated via FcγIIa on monocytes. Blockade of the complement system, resembling the in vivo situation of complement consumption in CG-associated diseases, increased IgG CG induced IL-10 and decreased TNF-α production. This represents hitherto not described mechanisms for CG-associated inflammation. ICs from SLE patients induced IL-10 and IL-6 production from PBMC cultures via FcγRIIa. Occurrence of anti-SSA autoantibodies and signs of in vivo complement activation contributed to increased levels of circulating ICs in SLE patients, corresponding to increased amounts of IC-induced IL-10 in vitro. This represents a possible vicious cycle that might perpetuate antibody dependent pathology in SLE, and put anti-SSA in a new pathological context. RF-associated ICs from RA joints and ICs formed with antibodies against collagen type II from RA serum induced pro-inflammatory cytokine production from monocytes via FcγRIIa, showing how specific autoantibodies might induce or perpetuate joint inflammation in RA. I have described how ICs can induce significant amounts of pathophysiologically important monocyte-derived cytokines in three major IC-dependent diseases. Blockade of FcγRIIa and suppression of monocytes/macrophages might be a means of reducing pathogenic IC-induced cytokine production in these diseases