Macrophage-bound C3 fragments as adhesion molecules modulate presentation of exogenous antigens

The versatile functions of complement C3-derived ligands

The complement system is a major component of immune defense. Activation of the complement cascade by foreign substances and altered self-structures may lead to the elimination of the activating agent, and during the enzymatic cascade, several biologically active fragments are generated. Most immune regulatory effects of complement are mediated by the activation products of C3, the central component. The indispensable role of C3 in opsonic phagocytosis as well as in the regulation of humoral immune response is known for long, while the involvement of complement in T-cell biology have been revealed in the past few years. In this review, we discuss the immune modulatory functions of C3-derived fragments focusing on their role in processes which have not been summarized so far. The importance of locally synthesized complement will receive special emphasis, as several immunological processes take place in tissues, where hepatocyte-derived complement components might not be available at high concentrations. We also aim to call the attention to important differences between human and mouse systems regarding C3-mediated processes.

Human T cell derived, cell-bound complement iC3b is integrally involved in T cell activation

Although the complement system is thought to be mainly involved in innate immunity and in the humoral arm of adaptive responses, evidence implicating that complement impacts T cell responses are accumulating recently. The role of the various activation products of the major complement component C3 were mainly studied so far in animal systems, and investigations regarding the effect of different C3-fragments on human T cells are sparse. Here we show that anti-CD3 activated human T lymphocytes derived from the blood and tonsil of healthy individuals produce C3, and the major cleavage fragment that appears on the T cell surface is iC3b. Based on studies carried out in allogenic system we demonstrate that the T cell membrane bound iC3b binds to the CR3 and probably to CR4 receptors expressed on monocyte-derived dendritic cells, and this interaction leads to significantly enhanced T-cell proliferation. Since neither C3aR and nor C3a binding could be detected on the membrane of anti-CD3 activated T cells, our findings indicate that in humans – in contrast to mice – the C3a peptide is most probably not involved directly in the T cell activation process.

CR3 is the dominant phagocytotic complement receptor on human dendritic cells

Dendritic cells (DCs) play a decisive role in immunity; they interact with various pathogens via several pattern recognition and different opsonophagocytotic receptors, including Fc- and complement-receptors. β2-integrins, including complement receptors CR3 (CD11b/CD18) and CR4 (CD11c/CD18) participate in many immunological processes, especially those involving cell migration, adherence, and phagocytosis. Human monocyte derived dendritic cells (MDCs) are known to express CR3 as well as CR4, however possible differences regarding the role of these receptors has not been addressed so far. Our aim was to explore whether there is a difference between the binding and uptake of various complement-opsonized microorganisms, mediated by CR3 and CR4. Studying the expression of receptors during differentiation of MDCs we found that the appearance of CD11b decreased, whereas that of CD11c increased. Interestingly, both receptors were present in the cell membrane in an active conformation. Here we demonstrate that ligation of CD11b directs MDCs to enhanced phagocytosis, while the maturation of the cells and their inflammatory cytokine production are not affected. Blocking CD11c alone did not change the uptake of opsonized yeast or bacteria by MDCs. We confirmed these results using siRNA; namely downregulation of CD11b blocked the phagocytosis of microbes while silencing CD11c had no effect on their uptake. Our data clearly demonstrate that complement C3-dependent phagocytosis of MDCs is mediated mainly by CR3.

A novel, complement-mediated way to enhance the interplay between macrophages, dendritic cells and T lymphocytes

Recently it has been reported that human C3-deficiency is associated with impairments in dendritic cell differentiation. Here we investigated how complement C3 influences the phenotype and functional activity of human dendritic cells. We show that human monocyte-derived dendritic cells (MDCs) when incubated with native, hemolytically active C3, bind the activation fragments of C3 covalently. This reaction directs MDCs to increase expression of MHCII, CD83 and CD86, moreover it results in a significantly enhanced secretion of TNF-alpha, IL-6 and IL-8. A further functional consequence of C3b-fixation is the elevated capacity of the dendritic cells to stimulate allogeneic T cells. The distinct role of covalently fixed C3-fragments is strongly supported by our results obtained with MDCs where CD11b expression was downregulated by siRNA. To reveal the possible in vivo significance of the present findings we modelled a phenomenon occurring during inflammation, where C3 is produced locally by activated macrophages. In these cocultures MDCs were found to fix substantial amounts of macrophage derived C3-fragments on their cell membrane. Our data provide compelling evidence that antigen presenting cells arising in complement-sufficient environment mature to competent stimulators of T cells.

Macrophages from C3-deficient mice have impaired potency to stimulate alloreactive T cells

Impaired T-cell reactivity is a feature of C3-deficient mice in several disease models. The mechanism behind the reduced T-cell response is, however, poorly understood. We explored the hypothesis that antigen-presenting cells (APCs) from C3-/- mice have impaired potency to stimulate antigen-specific T cells, in an alloantigen-dependent model. Our results show that C3-/- macrophages have reduced ability to elicit alloreactive T-cell responses in vitro and in vivo, affecting both the primary and secondary responses. The C3 status of donor macrophages had a major impact on the CD4 T-cell response. The impaired CD4 T-cell response was associated with reduced expression of MHC class II on the surface of C3-/- macrophages, without loss of class II gene expression. Furthermore, inhibition of C3 gene expression in C3+/+ macrophages reduced their ability to stimulate alloreactive T cells, suggesting that endogenous production of C3 could in part contribute to the potency of APCs. Our data provide compelling evidence that C3 deficiency modulates the potency of APCs to stimulate the T-cell response, suggesting a critical role for complement in the maintenance of APC function. This could offer a partial explanation as to why the T-cell response is impaired in C3-/- mice. (Blood. 2006;107:2461-2469)

Allograft rejection: effect of local synthesis of complement

The complement system is known for its ability to participate in non-specific inflammation and membrane injury as well as contributing to antigen-specific immune stimulation. In renal transplantation, the complement cascade behaves true to form in that both non-immune- and immune-mediated destruction of the renal tubules are complement dependent. What is remarkable, however, is the extent of involvement of local synthesis of complement in both of these injuries, suggesting that the extravascular tissue compartment is the domain of local synthesis, whereas the effect of circulating complement is much less. This creates a new paradigm for studying the influence of local synthesis of complement in other organ-based diseases and underlines the need for tissue-targeting strategies in successful therapeutic development.

Influence of complement on the allospecific antibody response to a primary vascularized organ graft

The induction of antibody responses against T cell-dependent antigens has been reported to be influenced by complement. We therefore asked if the primary induction of alloantibodies against transplantation antigens, an important determinant of transplant outcome, is complement sensitive and whether this has functional implications. We transplanted rat kidney allografts into fully major histocompatibility complex-mismatched recipients, in which complement activation was inhibited by daily injection of soluble recombinant human complement receptor type 1 (sCR1). Control allograft recipients were injected with saline. Animals in the control group showed a marked antibody response against donor-specific antigens and an increase in the proportion of activated B and T splenocytes by day 5 after transplantation. Complement-inhibited rats showed a reduced level of antibody binding on target cells sharing the same histocompatibility antigens as the donor strain (p < 0.001), and a reduced level of activated splenic B (p < 0.01) and T (p < 0.01) cells. In a functional assay, the plasma of complement-inhibited rats showed reduced cytotoxic activity against donor-specific cells, and their grafts contained less bound antibody than controls. Analysis beyond 6 days was obscured due to the development of antibodies against sCR1. We conclude that complement activation facilitates the induction of the alloantibody response. Sparing of vascular injury and prolongation of graft survival, previously reported in complement-inhibited rats (Pratt J. R. et al., Am. J. Path. 1996, 149: 2055), could therefore be due to down-regulation of the B cell response as well as reduced complement-dependent cytotoxicity. Inhibition of complement may provide an ancillary approach to the prevention of allospecific antibody formation and the prolongation of allograft survival in primary kidney grafting.

Secretion of the C3 component of complement by peritoneal cells cultured with encapsulated Cryptococcus neoformans

Two isolates of Cryptococcus neoformans were identified as being widely divergent in pathogenic potential after intratracheal infection of mice. These isolates differed in their ability to upregulate capsule synthesis when grown under tissue culture conditions, and this property correlated with virulence. We postulated that differential capsule synthesis may cause differential stimulation of macrophages to produce products such as complement components. To test this hypothesis, heat-killed yeast cells were incubated with normal mouse peritoneal cells (PC) before the level of C3 secreted was determined. Cryptococcal stimulants were grown on mycological agar, which does not promote capsule synthesis, or in RPMI 1640 at 37 degrees C in an atmosphere of 5% CO2, which stimulates capsule synthesis, to determine the role that the capsule plays in the induction of C3 secretion. C3 levels were elevated in cultures containing cryptococci grown in RPMI 1640 at 37 degrees C in an atmosphere of 5% CO2, and the level of C3 detected was correlated with the amount of capsule expressed by the yeast cell stimulant. Nonencapsulated mutants of C. neoformans did not stimulate C3 secretion. Purified capsular polysaccharide (glucuronoxylomannan [GXM]) also stimulated the PC to secrete C3. Two signals were required before GXM stimulated C3 secretion. The second signal was identified as endotoxin present in small amounts (0.06 ng per ml) in tissue medium. Endotoxin may provide a priming stimulus for PC to express receptors or other cytokines needed for effective stimulation of C3. These experiments show that enhancement of C3 secretion by C. neoformans is due to GXM and is correlated with the virulence of the cryptococcal isolate.

Vaccine adjuvants based on gamma inulin

Algammulin and gamma-IN comprise a novel class of vaccine adjuvant. Their use in vaccines is to exploit the humoral defense known as the alternative pathway of complement. They use a "natural" mechanism and the biochemical basis of their action is well understood in general terms. They are fully researched up to the stage of specific commercial application. Inulin itself is registered for human use as a solution and is without physiological effect except for ACP activation as gamma-IN particles. The ACP comprises a relatively harmless part of the inflammatory response. Gamma inulin is nontoxic in several species including humans and is nonpyrogenic. The amount of systemic C3a produced from adjuvant-active doses of gamma-IN is expected to be very much less than that routinely tolerated without effect by human renal dialysis patients. Registration of gamma-IN should not be difficult. Gamma inulin in vivo is either dissolved and excreted unchanged or metabolized to simple foodstuffs. Its primary chemical structure is completely known, and it is inexpensive, readily available, and easy to handle and manufacture. It is completely stable under normal conditions of use and storage. Patent cover is either fully granted or accepted for granting in most developed countries. Alum is also registered for human use and its combination with gamma-IN known as Algammulin is equally nontoxic especially in the fine formulation, and is equally stable. The partial coating with inulin in Algammulin greatly reduces the undesirable effects of alum such as granuloma formation and IgE generation. Combinations of gamma-IN with immunogen carriers other than alum are feasible, either as hybrid particles or as simple mixtures of particles of similar size. Gamma inulin, and especially Algammulin, are potent enhancers of the Th1 immune response pathway, boosting seroconversion rates and immunological memory in protective Ab classes and enhancing cell-mediated immunity. The responses can equal those of CFA. They are also Th2 pathway enhancers, especially for IgA, and the emphasis on Th2 might be varied by altering the alum-to-inulin ratio in the final formulation. A dual response (balanced Th1 and Th2) may be desirable for several reasons. Their primary targets in vivo are probably lymphocytes rather than macrophages. Gamma inulin-based adjuvants therefore comprise new, safe, potent, and attractive candidates for enhancing responses to human and veterinary vaccines, especially those requiring cell-mediated defenses.