Functional characterization of soluble and membrane-bound forms of vaccinia virus complement control protein (VCP).

Vaccinia virus secretes a 35 kD protein, vaccinia virus complement control protein (VCP), that inhibits the classical and alternative pathways of complement at several points, indicating that it may be a viral analogue of human complement receptor type 1 (CR1; CD35). Structurally, however, CR1 is composed of 30 short consensus repeats (SCRs), whereas VCP consists entirely of four SCRs. We have begun a structure-function analysis of VCP to define the minimum number of SCRs necessary for function, the functional differences between VCP and CR1, and the potential therapeutic roles for VCP. We addressed these questions by creating and characterizing recombinant soluble and membrane-bound forms of VCP. We have determined that (1) VCP requires all four SCRs to bind C3b, (2) whereas CR1 binds C3b and iC3b, VCP binds C3b but not iC3b, and (3) although normally secreted, if expressed on the membrane of mammalian cells, VCP effectively protects the cells from complement-mediated lysis. Thus, VCP appears to be a compact and unique complement regulatory protein with the ability to inhibit both arms of the complement cascade, but lacking affinity for iC3b. By releasing rather than capturing iC3b-bearing complexes following inactivation of C3b, VCP may 'recycle' its active site locally among infected cells, and thereby enable the virus to evade more efficiently host immune and inflammatory responses. The unique function, compact structure, and capacity of VCP to protect mammalian cells from complement-mediated attack, suggests that it could be used both to better understand the structure-function relationship of complement regulatory proteins, in general, and also to rationally design and develop novel therapeutic agents.

Systemic lupus erythematosus and complement deficiency: clues to a novel role for the classical complement pathway in the maintenance of immune tolerance.

Complete deficiency of C1q, the first component of the classical pathway of complement activation, is almost invariably associated with the development of systemic lupus erythematosus. Understanding why complement deficiency results in the specific autoimmune phenotype of SLE may provide valuable clues to the role of complement in the maintenance of immune tolerance. The following review will focus on the characteristics of complement-deficient SLE and the experimental evidence in support of our hypothesis that C1q may critically influence the immune response to self-antigen contained within surface blebs generated by apoptotic cells.

Induction of T cell anergy by low numbers of agonist ligands.

Engagement of TCR by its ligand, the MHC/peptide complex, causes T cell activation. T cells respond positively to stimulation with agonists, and are inhibited by antagonist MHC/peptide ligands. Failure to induce proper conformational changes in the TCR or fast TCR/MHC dissociation are the leading models proposed to explain anergy induction by antagonist ligands. In this study, we demonstrate that presentation of between 1 and 10 complexes of agonist/MHC II by unfixed APC induces T cell anergy that persists up to 7 days and has characteristics similar to anergy induced by antagonist ligand or TCR occupancy without costimulation. Furthermore, anergy-inducing doses of hemagglutinin 306-318 peptide led to the engagement of less than 1000 TCR/CD3 complexes. Thus, engagement of a subthreshold number of TCR by either a low density of agonist/MHC or a 2-3 orders of magnitude higher density of antagonist/MHC causes anergy. Moreover, we show that anergy induced by low agonist concentrations is inhibited in the presence of IL-2 or cyclosporin A, suggesting involvement of the calcineurin signaling pathway.

C1q binds directly and specifically to surface blebs of apoptotic human keratinocytes: complement deficiency and systemic lupus erythematosus revisited.

Complete deficiency of C1q is almost invariably associated with the development of systemic lupus erythematosus. It has been suggested that this association may result from a generalized failure to clear Ag-Ab complexes. However, it has not been demonstrated how such a broad impairment results in this specific and consistent autoimmune phenotype, in which photosensitive skin disease is the most prominent manifestation. We believe there is another role for the classical pathway in maintaining immune tolerance. Surface blebs of apoptotic keratinocytes are concentrated sources of autoantigens, and these packages may define a novel immune context and challenge self-tolerance if not properly cleared and processed. We demonstrate here that when human keratinocytes are rendered apoptotic, they also develop the capacity to specifically and directly bind to C1q in the absence of Ab. C1q may mediate Ab-independent clearance of apoptotic keratinocytes, and prevent immunization with autoantigens of cutaneous origin.