Antigen-specific B cells present cartilage proteoglycan (aggrecan) to an autoreactive T cell hybridoma derived from a mouse with proteoglycan-induced arthritis

Biomaterial Integration in the Joint: Pathological Considerations, Immunomodulation, and the Extracellular Matrix

Defects of articular joints are becoming an increasing societal burden due to a persistent increase in obesity and aging. For some patients suffering from cartilage erosion, joint replacement is the final option to regain proper motion and limit pain. Extensive research has been undertaken to identify novel strategies enabling earlier intervention to promote regeneration and cartilage healing. With the introduction of decellularized extracellular matrix (dECM), researchers have tapped into the potential for increased tissue regeneration by designing biomaterials with inherent biochemical and immunomodulatory signals. Compared to conventional and synthetic materials, dECM-based materials invoke a reduced foreign body response. It is therefore highly beneficial to understand the interplay of how these native tissue-based materials initiate a favorable remodeling process by the immune system. Yet, such an understanding also demands increasing considerations of the pathological environment and remodeling processes, especially for materials designed for early disease intervention. This knowledge would avoid rejection and help predict complications in conditions with inflammatory components such as arthritides. This review outlines general issues facing biomaterial integration and emphasizes the importance of tissue-derived macromolecular components in regulating essential homeostatic, immunological, and pathological processes to increase biomaterial integration for patients suffering from joint degenerative diseases. This article is protected by copyright. All rights reserved.

Presentation of the candidate rheumatoid arthritis autoantigen aggrecan by antigen-specific B cells induces enhanced CD4(+) T helper type 1 subset differentiation

Effective immune responses require antigen uptake by antigen-presenting cells (APC), followed by controlled endocytic proteolysis resulting in the generation of antigen-derived peptide fragments that associate with intracellular MHC class II molecules. The resultant peptide-MHC class II complexes then move to the APC surface where they activate CD4(+) T cells. Dendritic cells (DC), macrophages and B cells act as efficient APC. In many settings, including the T helper type 1 (Th1) -dependent, proteoglycan-induced arthritis model of rheumatoid arthritis, accumulating evidence demonstrates that antigen presentation by B cells is required for optimal CD4(+) T cell activation. The reasons behind this however, remain unclear. In this study we have compared the activation of CD4(+) T cells specific for the proteoglycan aggrecan following antigen presentation by DC, macrophages and B cells. We show that aggrecan-specific B cells are equally efficient APC as DC and macrophages and use similar intracellular antigen-processing pathways. Importantly, we also show that antigen presentation by aggrecan-specific B cells to TCR transgenic CD4(+) T cells results in enhanced CD4(+) T cell interferon-γ production and Th1 effector sub-set differentiation compared with that seen with DC. We conclude that preferential CD4(+) Th1 differentiation may define the requirement for B cell APC function in both proteoglycan-induced arthritis and rheumatoid arthritis.

B-cell involvement in the pathogenesis of RA-is there a contribution of the sympathetic nervous system?

The pathogenesis of rheumatoid arthritis (RA), the most common rheumatic disease, is still an unsolved puzzle. For many years, T-cells were the main focus of research, but recently, the B-cell drew more and more attention not least, due to the observation in humans that the anti-CD20 antibody Retuximab, which selectively depletes subsets of B-cells, lessens disease symptoms. A second novel approach to understand pathomechanisms that contribute to the development and progression of arthritis focuses on the sympathetic nervous system, which is known to moderate the function of immune cells, e.g., the B-cell, and therefore, is tied into a complex neuroimmune network that influences the course of the disease. This review first discusses current research that shows the significance of B-cells in the pathogenesis of RA. It then gives a short review of knowledge regarding the role of the sympathetic nervous system (1) in RA pathogenesis and (2) in modulating B-cell responses. Finally, the hypothesis is introduced that the sympathetic nervous system via modulating B-cell function, e.g., antibody production, influences the development and progression of RA.

B cells are important as antigen presenting cells for induction of MHC-restricted arthritis in transgenic mice

Rheumatoid arthritis and its animal model, collagen-induced arthritis, are known as a T and B cell dependent disease. To analyze the role of B cells in arthritis, we generated B cell deficient (microMT) mice carrying HLA-DQ8 as transgene, Abetao.DQ8.micromt mice. HLA-DQ8 transgenic mice (Abetao.DQ8) are susceptible to collagen induced arthritis, an animal model for inflammatory arthritis. Deletion of IgM gene led to the absence of B cells while T cells were comparable to Abetao.DQ8 mice. Arthritis and autoantibodies was completely abrogated in B cell deficient DQ8 mice. T cell response and proinflammatory cytokine production in response to type II collagen and its derived peptides in vitro was significantly decreased despite an increased number of Mac-1 positive cells in DQ8.micromt mice compared to DQ8 mice suggesting B cells could be important for antigen presentation as well. In vitro substitution of B cells from wild type mice restored the response in DQ8.micromt mice. B cells could also present CII-derived peptides to antigen-specific DQ8-restricted hybridomas reinforcing the role of B cells in presentation of antigens to T cells. The data suggest that B cells can be involved in pathogenesis of arthritis by producing autoantibodies and antigen presentation.

Aggrecan: A Target Molecule of Autoimmune Reactions

Aggrecan in cartilage forms aggregates with hyaluronan and link protein, embedded in a collagen network. It accounts for the compressive stiffness and resilience of the hyaline cartilage. Many forms of inflammatory arthritis were shown to be accompanied with aggrecan degradation and loss from the cartilage. The loss of this major component of cartilage renders the tissue more vulnerable when exposed to abrasive forces. Therefore, aggrecan degradation may significantly contribute to cartilage destruction in arthritis. Furthermore, fragments of degraded aggrecan are released during joint inflammation. Thus, molecules of an avascular, immune-privileged tissue (hyaline cartilage) may become accessible to the cells of the immune system. Similarly, there is a "leakage" of aggrecan fragments from cartilage during aging and after joint injury, which may also lead to autosensibilisation. Autoimmune reactivity to aggrecan can be detected in human joint diseases, as well as in animal models of arthritis. The epitopes involved in these processes are currently being identified. Recent data from work with mice suggest a strong immune response focused to the N-terminal G1 domain of aggrecan that leads to arthritis and spondylitis.

Complex pattern of Th1 and Th2 activation with a preferential increase of autoreactive Th1 cells in BALB/c mice with proteoglycan (aggrecan)-induced arthritis

The central role of CD4+ T cells and the balance between T helper (Th) subpopulations in the pathogenesis of autoimmune diseases have been extensively studied. Proteoglycan (aggrecan)-induced arthritis (PGIA) is a murine model for rheumatoid arthritis (RA), which is characterized by a Th1 dominance at the onset of the disease. In addition to CD4+ T cells, antigen-presenting B cells and autoantibodies seem to play an important role in the development and regulation of PGIA. To identify proteoglycan-specific CD4+ T cell subsets and Th1- and Th2-supported antibody isotypes during the progression of PGIA, spleen cells of proteoglycan-immunized BALB/c mice were harvested at different times of immunization, and at different stages of the disease, and their cytokine production and antigen-specific antibody isotype profiles were determined by enzyme-linked immunospot (ELISPOT) assays. Both Th1 and Th2 cytokine-producing cells, with the predominance of IL-4/IL-5-secreting cells, were detected during the prearthritic stage, and a shift toward a Th1 dominance was observed at the time of onset of arthritis. Tissue homogenates of acutely inflamed joints contained significantly higher levels of interferon-gamma than IL-4. The prearthritic period and both the acute and chronic phases of joint inflammation were characterized by IgG1 dominance in the sera and this correlated with the number of IgG1-secreting B cells in the spleen. However, the ratio of autoreactive IgG1/IgG2a-secreting cells decreased in arthritic animals. These results indicate the activation and possible regulatory roles of both Th1 and Th2 subsets in the autoimmune process, with the necessity of a relative increase of autoreactive Th1 cells for the induction of joint inflammation.

A recurrent valpha17/vbeta10 TCR-expressing T cell clone is involved in the pathogenicity of collagen-induced arthritis in DBA/1 mice

Collagen-induced arthritis (CIA) is an experimental model that mimics clinical and histological features of rheumatoid arthritis. In this disease, a crucial role in initiating the pathological changes has been assigned to T lymphocytes expressing the Th1 phenotype. Aiming at identifying type II collagen (CII)-specific T cells involved in CIA, T cell clones were generated in vitro from the lymph nodes (LN) of CII-immunized DBA / 1 mice. In three independent experiments, we repeatedly isolated CD4(+) Th1 clones recognizing the immunodominant epitope in the CB11 fragment of bovine CII and expressing a unique alpha betaTCR produced by the rearrangement of Valpha17/Jalpha20 and Vbeta10/Dbeta1.1/Jbeta2.5 gene segments. By reverse transcriptase-PCR, we demonstrated the presence of mRNA transcripts specific for the beta complementary-determining region 3 of this clonotype in the LN of the majority (73%) of mice with CIA whereas it was never detected in control animals. When transferred to CII-immunized DBA/1 mice, this recurrent Th1 clone augmented the incidence, aggravated significantly the clinical signs of CIA and greatly enhanced the anti-CII antibody response. Altogether, these results provide evidence that a CD4(+) Th1 clone belonging to the public arm of the response toward the immunodominant epitope of CII is involved in the cascade of events leading to CIA.

Modulation of hyaluronan receptor (CD44) function in vivo in a murine model of rheumatoid arthritis

OBJECTIVE

To determine how in vivo modulation of CD44 function by antibodies influences disease severity in a murine model of rheumatoid arthritis.

METHODS

Mice with proteoglycan (PG)-induced arthritis were subjected to systemic treatment with 3 different monoclonal antibodies against CD44. Joint swelling and serum levels of hyaluronan (HA) and soluble CD44 (sCD44) were monitored. Inflammatory leukocyte infiltration in the joints, cell surface CD44 expression, and leukocyte adhesion to HA were compared. The effects of anti-CD44 treatment on the immune status of arthritic animals were also determined.

RESULTS

Antibody IRAWB14, which enhances HA binding, aggravated the inflammatory symptoms, while KM201, which blocks ligand binding, reduced the severity of arthritis. The most effective suppression of inflammation was noted upon treatment with antibody IM7, whose epitope lies outside the HA binding domain of CD44. Serum levels of sCD44 increased, and HA levels decreased, in response to IM7. KM201 and IM7 treatment reduced, but IRAWB14 treatment enhanced, the adhesion of leukocytes to HA. However, these antibodies had little effect on PG-specific immune responses.

CONCLUSION

Each antibody acted in vivo by virtue of its combined effects on CD44-HA binding and CD44 shedding. The dramatic reduction in arthritis severity effected by IM7 treatment was associated with extensive shedding of cell surface CD44 molecules. Loss of CD44 appears to be a major factor in preventing CD44- and HA-dependent cell-matrix interactions at the inflammatory site. Our study indicates a critical role for CD44 in the pathology of joint inflammation and reveals a unique mechanism of receptor down-regulation, which can be used therapeutically.

Progressive polyarthritis induced in BALB/c mice by aggrecan from normal and osteoarthritic human cartilage

OBJECTIVE

To find an "unlimited" source of antigenic material (aggrecan) for arthritis induction in BALB/c mice; to analyze the specificities of immune reactions to aggrecan and type II collagen in 2 arthritis-susceptible murine strains, BALB/c mice for proteoglycan (aggrecan)-induced arthritis and DBA/1j mice for collagen-induced arthritis; to compare the histopathologic features of arthritis induced by purified aggrecans or total extracts of osteoarthritic (OA) cartilage; and to determine arthritis susceptibility in various BALB/c colonies.

METHODS

Aggrecans from total extracts of human fetal, normal adult, OA, and rheumatoid cartilage samples and from osteophytes were isolated, purified by gradient centrifugation, deglycosylated, characterized, and tested for arthritis induction. Purified type II collagen and salt-soluble collagens from OA cartilage were denatured, stromelysin treated, and used for immunization and arthritis induction in arthritis-susceptible (DBA/1j and BALB/c) murine strains.

RESULTS

Chondrocytes from OA cartilage synthesize predominantly fetal-type aggrecan, which is the most efficient antigenic material for arthritis induction in BALB/c mice. The critical autoimmune/arthritogenic T cell epitopes of aggrecan are located in the G1 domain. Although most of the aggrecan molecules are heavily degraded and lost from OA cartilage, the G1 domain-containing fragments accumulate in OA cartilage. The amount of G1-containing fragments is approximately twice as much in OA than in normal adult articular cartilage, and the arthritogenic epitope(s) remains intact in G1-containing fragments retained in cartilage. Thus, total extracts of OA cartilage (without additional purification), if deglycosylated appropriately, can be used as arthritogenic material in BALB/c mice.

CONCLUSION

Predominantly G1 domain-containing fragments of aggrecan accumulate in OA cartilage, and these are the fragments which induce arthritis in BALB/c mice. Arthritis induction is highly specific for aggrecan epitopes and dictated by the genetic background of the BALB/c strain.

Critical Roles of Glycosaminoglycan Side Chains of Cartilage Proteoglycan (Aggrecan) in Antigen Recognition and Presentation

Systemic immunization of BALB/c mice with proteoglycan (aggrecan) from fetal human cartilage induces progressive polyarthritis, an experimental disease similar to human rheumatoid arthritis. The development of the disease in this genetically susceptible murine strain is based on cross-reactive immune responses between the immunizing fetal human and mouse self-proteoglycans. One of the cross-reactive and arthritogenic T cell epitopes (92GR/QVRVNSA/IY) is localized in the G1 domain of human/murine proteoglycan. Susceptible BALB/c mice, however, develop arthritis only if both the chondroitin sulfate (CS) and keratan sulfate (KS) side chains of the arthritogenic human proteoglycans are removed. The function of these two glycosaminoglycan side chains is opposite. The presence of a KS side chain in adult proteoglycan inhibits the recognition of arthritogenic T cell epitopes, prevents the development of T cell response, and protects animals from autoimmune arthritis. In contrast, the depletion of the CS side chain generates clusters of CS stubs and provokes a strong B cell response. These carbohydrate-specific B cells are the most important proteoglycan APC. Taken together, proteoglycan-induced progressive polyarthritis is dictated by three major components: genetic background of the BALB/c strain, highly specific T cell response to epitope(s) masked by a KS chain in aging tissue, and the presence of proteoglycan (CS stub)-specific B cells required for sufficient Ag presentation.

Trypanosoma cruzi-infected macrophages are defective in major histocompatibility complex class II antigen presentation

Trypanosoma cruzi, the intracellular protozoan parasite that causes Chagas' disease, interferes with the host immune response to establish a persistent infection. In this report, we demonstrate that macrophages infected with T. cruzi are unable to effectively present antigens to CD4 T cells. The interference is due to defective antigen-presenting cell (APC) function, as antigen-independent stimulation of the T cell in the presence of infected macrophages is not affected. The defect is distal to antigen processing and is not due to decreased major histocompatibility complex (MHC) class II expression, decreased viability, defective peptide loading in the infected macrophages, nor absence of CD28 co-stimulation. There was a role for gp39: CD40 co-stimulation during antigen presentation to the T cells we studied, but the expression of CD40 on T. cruzi-infected macrophages was not decreased. Antigen-specific adhesion between macrophages and T cells was reduced by infection. Equivalent levels of the adhesion molecules lymphocyte function-associated antigen-1, intercellular adhesion molecule-1, vascular cell adhesion molecule-1 or very late antigen-4 are found on infected and uninfected APC, suggesting that reduced expression of these adhesion molecules was not responsible for the defect in antigen-specific adhesion. The defective T cell:macrophage adhesion may be due to the reduced expression of other adhesion molecules or other changes in the cell induced by infection. Interfering with MHC class II antigen presentation in infected macrophages may help T. cruzi to blunt the immune response by the host.