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  • Editorial
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Complement and arthritis: another step in understanding

Abstract

In a recent research article in Arthritis Research and Therapy ('Analysis of C204 and the C4 binding protein in the MRL/lpr mouse'), Wenderfer and colleagues report that deficiency in C4 binding protein, a down-regulator of the classic pathway of complement, does not affect the development of autoimmune disease. These data support the earlier finding that the alternative pathway, and not the classic pathway, drives disease progression. However, in a milder variant of the MRL/lpr model, the lpr/lpr mouse, classic pathway deficiency does contribute toward renal pathology and more severe disease. In this editorial we discuss the factors that may cause such a discrepancy.

In a previous issue of Arthritis Research and Therapy, Wenderfer and colleagues [1] analysed the C4 and the C4 binding protein in the MLR/lpr mouse, a well-studied model of immune complex disease with autoimmune tissue damage [2]. The lpr mutation confers a defect in Fas, with resulting failure of cellular apoptosis, and the MRL defects predispose the mouse to the development of autoimmunity. At an early age these mice develop massive lymphadenopathy, lupus like antibodies, and severe tissue damage.

Organ pathology results, in part, from the formation and organ deposition of immune complexes, the activation of complement, and consequent tissue damage. Previous work has shown that much of this damage is a result of alternative complement pathway (AP) activation [3]. Cross-breeding MRL/lpr mice with complement factor B deficient animals, defective in activation and function of the AP but with the classic complement pathway (CP) intact, leads to amelioration of symptoms, decreased glomerulonephritis, vasculitis, tissue damage and decreased lethality. The CP has not been shown to be a major pathway for complement mediated tissue damage in MRL/lpr mice.

Wenderfer and colleagues [1] have carried this analysis further by examining the effect of C4 binding protein (C4 bp) deficiency in the MRL/lpr model. Their methodology was similar to studies of factor B deficiency. The mutation for C4 bp was bred into MRL/lpr mice and these doubly inbred animals were compared to the parent strain MRL/lpr in terms of organ pathology, complement activation, and lethality.

It is known that C4 bp is a control protein of the CP and plays little or no role in AP activation [4]. C4 bp has a number of actions: it binds primarily to C4b to inhibit the continued activation of the CP; it serves to increase the degradation of the CP C3 convertase, consisting of C4b and C2a, and thereby decrease the activity of the convertase; it acts as a co-factor for the degradation of C4b to C4d with complement factor I; and C4 bp has been shown more recently to interact with CD40 as well as CD154 in human in vitro models, although the details of these interactions are still not clear [5, 6].

In the study by Wenderfer and colleagues [1], the authors report that deficiency in C4 bp made little difference to survival, organ pathology, and the extent of autoimmunity in MRL/lpr animals. This further supports the central role of the AP in contrast to the CP. An interesting question relates the findings in this paper and the findings of Prodeus and colleagues [7]. These authors studied the effect of targeting the genes for complement proteins C4 and C3 and the complement receptors CD35 and CD21 in the closely related lpr/lpr model. In the absence of the MRL abnormalities and on the C57/B6 background, these mice develop mild autoimmune disease. They reported that when the gene for C4 or CD21/CD35 was deleted in the lpr/lpr model, but not the gene for C3, there was a marked increase in disease activity and lethality. They reasoned that in this and other disease models, C4 and CD35/CD21 participate in tolerance induction. Presumably, if the gene for C4 bp was of great importance in down-regulating the CP, this pathway might be up-regulated upon gene deletion and lead to an increase in tolerance induction. However, this was not the case. On the other hand, C4 levels are low in the MRL/lpr model, perhaps preventing C4 bp from regulating C4 and CP activity.

The MRL/lpr model may not be the optimal choice for studying the function of C4 bp in mediating tolerance induction. The abnormality is present in mice on an H-2k background, which is known to be associated with very low serum C4, as recognized by Wenderfer and colleagues [1]. The MRL/lpr mouse has a defect in Fas mediated apoptosis, one of the multiple checkpoints in the immune response that leads to the deletion of strongly self-reactive lymphocytes [8]. On the MRL background this defect predisposes to severe autoimmunity. The animals have massive enlargement of lymphoid organs. Perhaps the modulating effects contributed by the CP are not evident when massive stimulation of self reactive lymphocytes is induced.

The finding that C4 bp deficient MRL/lpr animals have no alteration in autoimmune manifestations of disease confirms the observation that, in this model, the AP plays the dominant role in tissue deposition of immune complexes and organ damage. It is known that in many situations, the AP is activated by the CP, and the AP provides most of the anaphylotoxins, C3a and C5a, as well as most of the C3 deposited in tissue. In the MRL/lpr model, there may be such high levels of circulating immune complexes in these animals that the AP does not require the CP for optimal activation. More studies should define these issues.

The detailed paper by Wenderfer and colleagues clearly shows that C4 bp cannot control the development of autoimmunity in the MRL/lpr model and leads the way to further studies that may help us understand how individual complement pathways contribute to either tolerance or autoimmunity.

Abbreviations

AP:

= alternative complement pathway

C4 bp:

= C4 binding protein

CP:

= classic complement pathway.

References

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Correspondence to Michael M Frank.

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Frank, M.M., Hester, C.G. Complement and arthritis: another step in understanding. Arthritis Res Ther 10, 104 (2008). https://doi.org/10.1186/ar2359

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