Peter K.E. Trinder

Interleukin-7 or interleukin-15 enhances survival of Mycobacterium tuberculosis-infected mice.

ABSTRACT Both antigen-presenting cells and immune effector cells are required to effectively eradicate or contain Mycobacterium tuberculosis-infected cells. A variety of cytokines are involved to ensure productive “cross talk” between macrophages and T lymphocytes. For instance, infection of macrophages with mycobacteria leads to effective interleukin-7 (IL-7) and IL-15 secretion, and both cytokines are able to maintain strong cellular immune responses of α/β and γ/δ T cells. Here we show that either cytokine is able to enhance survival of M. tuberculosis-infected BALB/c mice significantly compared to application of IL-2, IL-4, or phosphate-buffered saline (as a control). Enhanced survival could be achieved only when IL-7 or IL-15 was delivered as a treatment (i.e., 3 weeks postinfection), not when it was administered at the time of infection. Increased survival of M. tuberculosis-infected animals was observed following passive transfer of spleen cells harvested from M. tuberculosis-infected, IL-7- or IL-15-treated animals, but not after transfer of spleen cells obtained from mice which received either cytokine alone. Histological examination revealed that IL-7 and IL-15 failed to significantly impact on the number and composition of granulomas formed or the bacterial load. Our data indicated that administration of IL-7 or IL-15 toM. tuberculosis-treated animals resulted in a qualitatively different cellular immune response in spleen cells as reflected by increased tumor necrosis factor alpha and decreased gamma interferon secretion in response to M. tuberculosis-infected antigen-presenting cells.

Autoreactivity to mouse C1q in a murine model of SLE

A large proportion of systemic lupus erythematosus (SLE) patients develop glomerulonephritis, coincident with the appearance of autoantibodies to C1q, the Fcrecognizing collagen-like subcomponent of the first component of complement, C1. The MRL/lpr/lpr mouse is an established model for SLE, developing both antinuclear and anti-type II collagen autoantibodies, and rheumatoid factors(s), exhibiting reduced complement levels and later on developing glomerulonephritis and often arthritis. We report here an age-dependent decrease in serum C1q levels coincident with the development of IgG2b autoantibodies reactive with mouse C1q in MRL/lpr/lpr mice. Unlike IgG2b, although high levels of IgM, IgG1 and IgG2a are present in these mice, few, if any, antibodies of these sub-classes reactive with mouse C1q were observed in this study. This is the first report of autoantibodies against autologous C1q in an animal model, and the results should facilitate in clarification of the roles of C1q and autoantibodies reactive with C1q in SLE, as well as their potential connection with glomerulonephritis.

Humoral autoreactivity directed against surfactant protein-A (SP-A) in rheumatoid arthritis synovial fluids

SP‐A is found principally in the lung, and has been associated with lamellar bodies also found in the synovial joint. Both SP‐A and C1q contain collagen‐like regions, and SP‐A and C1q have some structural similarities, both having a globular head region and a collagen‐like tail. Here we are able to show that (i) autoreactivity to SP‐A, as expressed by IgG and IgM autoantibodies, is present in synovial fluid (SF) isolated from patients with rheumatoid arthritis (RA); (ii) in absorption experiments only a limited degree of cross‐reactivity between autoantibodies reactive with C1q and SP‐A is observed; (iii) there is no cross‐reactivity between autoantibodies reactive with type II collagen (CII) and those reactive with SP‐A or C1q; (iv) autoantibodies react with polymeric (dimers and larger) SP‐A, but not with monomeric SP‐A subunits, indicating that a degree of quaternary structure is required for antibody binding. Unlike CII, which not accessible in the normal joint, both SP‐A and C1q are available within the SF in patients with RA and may therefore provide antigens driving an autoimmune response directed against collagen‐like structures.

The collagen‐like component of the complement system, C1q, is recognized by 7 S autoantibodies and is functionally impaired in synovial fluids of patients with rheumatoid arthritis

Cross‐reactivity between type II collagen (CII) and C1q, the collagen‐like subunit of the first component of complement, has been demonstrated in synovial fluid (SF) from rheumatoid arthritis (RA) patients. Many authors have studied autoimmunity to CII in RA, but little work has been done on autoimmunity to C1q in RA. In the data presented here, we have been able to show that in addition to native C1q, an altered form of C1q is present in SF from RA patients. Furthermore, a low molecular weight form of C1q is present in RA SF, although its role, if any, in the pathogenesis of RA is unclear. The presence in these RA SF of C1q‐specific antibodies (IgG and IgM) has been studied and we have partially characterized the antibody moieties involved. As well as binding to C1q and fragments representing the collagen‐tails from C1q, 7 S IgG autoantibodies against C1q also bind to a C1q molecule altered in vitro by incubation with reactive oxygen species and to the non‐apeptide KGEQGEPGA (representing residues 26–34 from the C1q A‐chain), which has previously been shown to suppress the onset of CII‐induced arthritis in an animal model.

Modulation of type II collagen-induced arthritis in DBA/1 mice by intravenous application of a peptide from the C1q-A chain.

In this report we are able to show that intravenous (i.v.) application (day 0) of a nonapeptide (residues 26-34) from the human C1q A-chain (designated peptide A-C1q) prior to intradermal (i.d.) administration of chicken type II collagen (CII) in arthritis-susceptible DBA/1 mice (H2q), leads to abrogation of polymorphonuclear neutrophil (PMN) invasion into the joints. This nonapeptide exhibits epitope characteristics and high homology to residues 137-147 of CB11 (a cyanogen bromide fragment of chicken CII, known to contain both arthritis inducing and suppressing determinants). Arthritis index was lowest in animals pretreated i.v. with CII (as internal control), though animals pretreated i.v. with peptide K (residues 137-147 with an additional glycine residue from CB11) or peptide A-C1q exhibited comparative arthritic indices. Only in the arthritis-positive control group (day 0: PBS i.v.) did i.d. application of CII lead to invasion of PMN into the synovial layer and the joint space. Analysis of antibody (Ab) responses at day 48 after i.v. immunization (day 0) and CII challenge (day 7) revealed IgE-Abs to native CII and also to native C1q. IgG titers to CII were highest in animals pretreated with peptide A-C1q. Abs from this group, exhibiting activity to peptide A-C1q (immunizing antigen), were of mainly IgG1 and IgG3 isotypes. Evaluation of the immune response following i.v. application of peptide A-C1q or CII, prior to i.d. CII administration, in DBA/1 mice, revealed IgM responses to peptide A-C1q and peptide K, but not to CII. Intravenous application of peptide A-C1q led to generation of IgG3-Abs reacting only with peptide A-C1q and peptide K, but not with native CII. Additionally, i.v. application of peptide A-C1q elicited IgG responses to a pentapeptide, resembling amino acid residues 26-30 (K-G-E-Q-G) of the C1q A-chain. This five residue antigenic determinant is present in peptide K, in chicken and human CII as well as in human C1q. No specific IgE response to any of the antigens tested could be detected. Since a peptide from the C1q A-chain is both capable of eliciting immune responses and modulating CII-induced arthritis in mice, we postulate that the collagen-like complement component C1q is involved in the development of CII-induced inflammatory arthritic lesions, and may represent, in vivo, the early antigen responsible for inducing anticollagen antibodies prior to CII in hyaline cartilage becoming available as antigen.

CHAPTER 13 – INTERLEUKIN-7

This chapter discusses interleukin (IL)-7, which is an important lymphopoietin that plays a critical role in both B- and T-cell development. IL-7 promotes expansion of T lymphocytes exhibiting antigen-specific reactivity. IL-7 may be implemented to promote strong and effective immune responses against tumor cells, or directed against microbial or viral infections. It may also be useful in reconstituting an effective, and functional immune system after bone marrow transplantation, or helping to design novel strategies for immune reconstitution in patients with cancer or with HIV infection. IL-7 serves as the major growth and differentiation factor for both thymic and extrathymic development of γ∂ + T lymphocytes. IL-7 promotes immune effector functions in T lymphocytes, natural killer (NK) cells and mono-cytesmacrophages, and modulates the quantity and quality of immune responses in vitro and in vivo .

C1-inhibitor-C1S complexes are internalized and degraded by the low density lipoprotein receptor-related protein☆

Like other serpin-enzyme complexes (SECs), proteinase-complexed C1 inhibitor (C1-INH) is rapidly cleared from the circulation and thought to be a neutrophil chemoattractant, suggesting that complex formation causes structural rearrangements exposing a domain which is recognized by specific cell surface receptors. However, the cellular receptor(s) responsible for the catabolism and potential mediation of chemotaxis by C1-INH-protease complexes remained obscure. To determine whether the SEC receptor mediates the binding and potential chemotaxis of C1-INH.Cs, we performed binding assays with HepG2 cells, neutrophils, and monocytes, and the results show that C1-INH.Cs neither bind to these cells nor cause a chemotactic response of neutrophils and monocytes. Furthermore, C1-INH.Cs, the COOH-terminal C1 inhibitor peptide, or the tetrameric C1-INH.Cs.Cr. C1-INH complex were found to be significantly less effective in competing with the SEC receptor ligand 125I-peptide 105Y for the binding to HepG2 cells than unlabeled 105Y, indicating that the SEC receptor does not sufficiently recognize C1-INH-protease complexes. The asialoglycoprotein receptor was also ruled out to be responsible for the removal of the heavily glycosylated C1-INH.Cs complex, since asialoorosomucoid did not compete for the clearance of C1-INH. 125I-Cs and asialoglycoprotein receptor knockout mice showed no alterations in the C1-INH.125I-Cs clearance rate. We found that C1-INH.125I-Cs complexes were efficiently degraded by normal murine fibroblasts expressing the low density lipoprotein receptor-related protein (LRP) and cellular degradation was significantly reduced by chloroquine and the receptor-associated protein, which is a potent inhibitor of the binding of all known ligands to LRP. Moreover, receptor-associated protein inhibited the in vivo clearance of C1-INH.125I-Cs and murine fibroblasts genetically deficient for LRP did not degrade C1-INH.125I-Cs. Our results demonstrate that C1-INH. Cs complexes do not stimulate neutrophil or monocytic chemotaxis but are removed by LRP, further underscoring its role as a serpin-enzyme complex clearance receptor.