Identification of Clinically and Pathophysiologically Relevant Rheumatoid Factor Epitopes by Engineered IgG Targets

Objective: Rheumatoid factors (RFs), which are anti-IgG autoantibodies strongly associated with rheumatoid arthritis (RA), are also found in other diseases and in healthy individuals. RFs bind to various epitopes in the constant (Fc-) domain of IgG. Therefore, disease-specific reactivity patterns may exist. This study was undertaken in order to develop a new approach to dissecting RF epitope binding patterns across different diseases. Methods: We analyzed RF reactivity patterns in serum from patients with seropositive arthralgia, patients with RA, and patients with primary Sjögren’s syndrome (SS) using bioengineered, natively folded IgG-Fc targets that demonstrated selective RF binding toward several distinct regions of the IgG-Fc domain. Results: Rheumatoid factor responses primarily bound the Fc Elbow region, with a smaller number of RFs binding the Fc Tail region, while the Fc receptor binding region was hardly targeted. A restricted reactivity against the IgG-Fc Tail region was associated with less positivity for anti–citrullinated protein antibodies (ACPAs) and less arthritis development in arthralgia, whereas combined reactivity toward IgG-Fc Tail and Elbow regions was associated with more arthritis development. Reactivity toward the IgG-Fc Tail region was observed far more frequently in RA than in primary SS. Conclusion: Bioengineered IgG targets enable serologic characterization of RF reactivity patterns, and use of this approach appears to reveal patterns associated with ACPA detection and arthritis development in patients with arthralgia. These patterns are able to distinguish RA patients from primary SS patients. This new methodology improves the clinical value of RFs and our understanding of their pathophysiologic processes

On the origin of rheumatoid factors: Insights from analyses of variable region sequences

Objectives: Rheumatoid factors (RFs) are thought to play an important role in rheumatoid arthritis (RA), but are also found in healthy donors (HDs). Previous studies examined variable region sequences of these autoantibodies at a time when knowledge of the human germline repertoire was incomplete. Here we collected and analyzed RF sequence data from the literature to elucidate how RFs develop and whether their characteristics differ between RA patients and HDs. Methods: A database was built containing nucleotide sequences of RF heavy and light chain variable domains and characteristics including affinity, isotype and specificity, all collected from published papers. Gene usage and mutation frequencies were analyzed using IMGT/HiV-QUEST. Selection strength was assessed with the BASELINe tool. Results: Sequences were retrieved for 183 RF clones (87 RA; 67 HDs; 29 other). No biased gene usage was observed for RA and HDs. However, there does appear to be skewed gene usage in RFs from patients with mixed cryoglobulinemia. Mutation frequency varies considerably between RFs, and isotype-switched clones have significantly more mutations. Monospecific RFs carry more mutations than polyspecific RFs; no difference was found for RA- versus HD-derived RFs. Overall, reported affinity is low (median 1 µM), with a non-significant trend toward higher affinity of RA-derived RFs. Mutation frequency and affinity did not appear to be correlated. BASELINe analysis suggests an overall lack of positive selection and less negative selection strength in RA-derived RFs. Conclusions: RFs derived from RA patients have similar properties as those derived from HDs. The RF response can be characterized as a moderately matured autoantibody response, with variable levels of somatic hypermutation, but low affinity

Olecranon bursitis caused by Scedosporium apiospermum in a patient treated with CAR-T cells

Chimeric antigen receptor (CAR-) T cell therapy is a relatively new form of immunotherapy for hematological malignancies. Although patients are at increased risk of infection following CAR-T cell therapy, reports of fungal infections are scarce. We report a case of Scedosporium apiospermum infection causing bursitis of the elbow in a lymphoma patient after treatment with CAR-T cells. The fungal bursitis relapsed under posaconazole treatment, but was cured after surgical extirpation of the bursa

IgG Subclass Specificity Discriminates Restricted IgM Rheumatoid Factor Responses From More Mature Anti-Citrullinated Protein Antibody-Associated or Isotype-Switched IgA Responses

To investigate the presence and patterns of specific IgG subclass recognition by IgM rheumatoid factor (IgM-RF) and IgA-RF with a newly developed enzyme-linked immunosorbent assay (ELISA), which can discriminate between polyspecific and restricted RF responses. Polyspecific and restricted RF responses were determined with our ELISA, which uses individually coated recombinant IgG subclasses instead of polyclonal IgG as target antibodies. Fine specificity was determined using target antibodies with single amino acid mutations in the Fc region. In a screening panel of 93 sera that were previously found to be IgM-RF positive in a conventional RF assay, we were able to discriminate between sera with polyspecific IgM-RF responses (i.e., RF responses directed against all 4 IgG subclasses) and those with restricted IgM-RF responses, with low or absent relative reactivity against IgG2, IgG3, or IgG4. We found the largest variation for anti-IgG3 reactivity. Samples without detectable anti-IgG4 reactivity formed an independent group from the other restricted RF responses and the polyspecific RF responses. The specificity of these anti-IgG4-negative sera could be pinpointed to single amino acid differences between IgG1 and IgG4. Polyspecific RF responses more often showed signs of RF response maturation, with more isotype switching to IgA-RF, as compared to restricted RF responses. In a cohort of IgM-RF+ and/or anti-citrullinated protein antibody (ACPA)-positive arthralgia patients, we found restricted RF responses in 35% (49 of 140) of RF+/ACPA- patients, while RF+/ACPA+ patients, who have a much higher risk of developing rheumatoid arthritis, virtually always (123 of 128 [96%]) showed a polyspecific RF response. IgG subclass-specific RF distinguishes between immature restricted RF responses and potentially more pathogenic, ACPA-associated polyspecific response

Clinically relevant discrepancies between different rheumatoid factor assays

Accurate measurements of rheumatoid factors (RFs), autoantibodies binding IgG, are important for diagnosing rheumatoid arthritis (RA) and for predicting disease course. Worldwide, various RF assays are being used that differ in technique and target antigens. We studied whether assay choice leads to clinically important discrepancies in RF status and level. RF measurements using four commercial RF assays were compared in 32 RF+ samples. Using enzyme-linked immunosorbent assays (ELISAs), the influence of the target antigen source - human IgG (hIgG) versus rabbit IgG (rIgG) - on measured RF levels was investigated in arthralgia patients and RA patients. Substantial discrepancies were found between RF levels measured in the four commercial assays. Six samples (19%) with RF levels below or slightly above the cutoff in the rIgG-based Phadia assay were RF+ in three assays using hIgG as the target antigen, some with very high levels. Direct ELISA comparisons of RF reactivity against hIgG and rIgG estimated that among 173 ACPA+ arthralgia patients, originally RF negative in rIgG-based assays, up to 10% were single positive against hIgG. Monoclonal RFs binding to hIgG and rIgG or hIgG only supported these findings. In a cohort of 69 early RA patients, virtually all RF responses reacted with both targets, although levels were still variable. The use of RF assays that differ in technique and target antigen, together with the different specificities of RF responses, leads to discrepancies in RF status and levels. This has important consequences for patient care if RA diagnosis and disease progression assessments are based on RF test result

Allogeneic HLA-A*02-Restricted WT1-Specific T Cells from Mismatched Donors Are Highly Reactive but Show Off-Target Promiscuity

T cells recognizing tumor-associated Ags such as Wilms tumor protein (WT1) are thought to exert potent antitumor reactivity. However, no consistent high-avidity T cell responses have been demonstrated in vaccination studies with WT1 as target in cancer immunotherapy. The aim of this study was to investigate the possible role of negative thymic selection on the avidity and specificity of T cells directed against self-antigens. T cell clones directed against the HLA-A*0201–binding WT1126–134 peptide were generated from both HLA-A*02–positive (self-HLA–restricted) and HLA-A*02–negative [nonself (allogeneic) HLA [allo-HLA]-restricted] individuals by direct ex vivo isolation using tetramers or after in vitro priming and selection. The functional avidity and specificity of these T cell clones was analyzed in-depth. Self-HLA–restricted WT1-specific clones only recognized WT1126–134 with low avidities. In contrast, allo-HLA–restricted WT1 clones exhibited profound functional reactivity against a multitude of HLA-A*02–positive targets, even in the absence of exogenously loaded WT1 peptide, indicative of Ag-binding promiscuity. To characterize this potential promiscuity, reactivity of the T cell clones against 400 randomly selected HLA-A*0201–binding peptides was investigated. The self-HLA–restricted WT1-specific T cell clones only recognized the WT1 peptide. In contrast, the allo-HLA–restricted WT1-reactive clones recognized besides WT1 various other HLA-A*0201–binding peptides. In conclusion, allogeneic HLA-A*02–restricted WT1-specific T cells isolated from mismatched donors may be more tumor-reactive than their autologous counterparts but can show specific off-target promiscuity of potential clinical importance. As a result of this, administration of WT1-specific T cells generated from HLA-mismatched donors should be performed with appropriate precautions against potential off-target effects