Steven H. Sacks

Local synthesis of complement component C3 regulates acute renal transplant rejection.

Accumulating evidence suggests that innate immunity interacts with the adaptive immune system to identify potentially harmful antigens and eliminate them from the host. A central facet of innate immunity is complement, which for some time has been recognized as a contributor to inflammation in transplant rejection but without detailed analysis of its role in what is principally a T cell–mediated process. Moreover, epithelial and vascular tissues at local sites of inflammation secrete complement components; however, the role of such local synthesis remains unclear. Here we show that the absence of locally synthesized complement component C3 is capable of modulating the rejection of renal allografts in vivo and regulating T-cell responses in vivo and in vitro. The results indicate that improved success in kidney transplantation could come from therapeutic manipulation of innate immunity in concert with T cell–directed immunosuppression.

Predominant role for C5b-9 in renal ischemia/reperfusion injury

Previous work has indicated that complement is a mediator of ischemia/reperfusion (I/R) injury. To investigate the components of complement responsible for this effect, we examined a model of renal I/R injury in C3-, C4-, C5-, and C6-deficient mice. We occluded the renal arteries and veins (40-58 minutes) and, after reperfusion (0-72 hours), assessed renal structural and functional injury. C3-, C5-, and C6-deficient mice were protected from renal I/R injury, whereas C4-deficient mice were not protected. C6-deficient mice treated with antibody to block C5a generation showed no additional protection from I/R injury. Reconstitution with C6 alone restored the I/R injury in C6-deficient mice. Tubular epithelial cells were the main structures damaged by complement-mediated attack, and, in contrast, the renal vessels were spared. Neutrophil infiltration and myeloperoxidase activity were reduced in C-deficient mouse kidney, but by a similar extent in C3-deficient and C6-deficient mice. We conclude that the membrane attack complex of complement (in which C5 and C6 participate) may account for the effect of complement on mouse renal I/R injury. Neither C5a-mediated neutrophil infiltration nor the classic pathway, in which C4 participates, appears to contribute to I/R injury in this model. By contrast with other organs, such as the heart, the primary effect of complement in the ischemic area is on the parenchymal cell rather than the vascular endothelial cell. The membrane attack complex of complement is a potential target for prevention of I/R injury in this model.

Fc-dependent depletion of activated T cells occurs through CD40L-specific antibody rather than costimulation blockade

Although the underlying mechanisms are not well understood, it is generally believed that antigen recognition by T cells in the absence of costimulation may alter the immune response, leading to anergy or tolerance. Further support for this concept comes from animal models of autoimmunity and transplantation, where treatments based on costimulation blockade, in particular CD40 ligand (CD40L)-specific antibodies, have been highly effective. We investigated the mechanisms of action of an antibody to CD40L and provide evidence that its effects are dependent on the constant (Fc) region. Prolongation of graft survival is dependent on both complement- and Fc receptor–mediated mechanisms in a major histocompatibility complex (MHC)-mismatched skin transplant model. These data suggest that antibodies to CD40L act through selective depletion of activated T cells, rather than exerting immune modulation by costimulation blockade as currently postulated. This finding opens new avenues for treatment of immune disorders based on selective targeting of activated T cells.

Dendritic cell synthesis of C3 is required for full T cell activation and development of a Th1 phenotype

Previous studies have found that deficiency of complement component C3 is associated with reduced T cell responses in several disease models including viral infection, autoimmune disease, and transplantation. However, the underlying mechanism is unclear. In this study, we demonstrate that dendritic cells (DCs) are able to synthesize C3 and this synthesis is required for the capacity of DCs to stimulate alloreactive T cell responses in vitro and in vivo. Compared with C3-producing DCs, C3-nonproducing DCs exhibit reduced potency to stimulate an alloreactive T cell response, favor the polarization of CD4+ T cells toward Th2 phenotype, and have regulatory T cell-driving capacity. In addition, priming mice with C3-deficient DCs compared with wild-type DCs led to delayed skin allograft rejection. Our findings that nonproduction of C3 by DCs significantly reduced T cell stimulation and impaired allograft rejection provide a potentially important explanation of how C3-deficient mice develop reduced T cell responses and of how C3-deficient donor kidney is protected from T cell-mediated graft rejection.

Local extravascular pool of C3 is a determinant of postischemic acute renal failure

The third complement component (C3) is an acute phase protein that plays a central role in reperfusion injury in several organ models. To investigate the contribution of local synthesis of C3 and distinguish it from that of circulating complement mainly produced by hepatic synthesis, we employed a mouse renal isograft model. Our model demonstrated a close relationship between the extent of intrarenal expression of C3 and cold‐ischemia induced injury. Ischemic C3‐positive donor kidneys transplanted into C3‐positive or C3‐negative recipients developed widespread tissue damage and severe acute renal failure. In contrast, ischemic C3‐negative isografts exhibited only mild degrees of functional and structural disturbance, even when transplanted into normal C3‐positive recipients. Thus local synthesis of C3, mostly identified in the tubular epithelium, was essential for complement‐mediated reperfusion damage, whereas circulating C3 had a negligible effect. Our results suggest a two‐compartment model for the pathogenic function of C3, in which the extravascular compartment is the domain of local synthesis of C3, and where the role of circulating C3 is redundant. Our data cast new light on the mechanism of complement‐mediated tissue injury in nonimmunological disorders, and challenges the long‐standing dogma that circulating components are the main complement effectors of extravascular tissue damage.—Farrar, C. A., Zhou, W., Lin, T., Sacks, S. H. Local extravascular pool of C3 is a determinant of postischemic acute renal failure. FASEB J. 20, 217–226 (2006)

Targeting of mannan-binding lectin-associated serine protease-2 confers protection from myocardial and gastrointestinal ischemia/reperfusion injury

Complement research experienced a renaissance with the discovery of a third activation route, the lectin pathway. We developed a unique model of total lectin pathway deficiency, a mouse strain lacking mannan-binding lectin-associated serine protease-2 (MASP-2), and analyzed the role of MASP-2 in two models of postischemic reperfusion injury (IRI). In a model of transient myocardial IRI, MASP-2–deficient mice had significantly smaller infarct volumes than their wild-type littermates. Mice deficient in the downstream complement component C4 were not protected, suggesting the existence of a previously undescribed lectin pathway-dependent C4-bypass. Lectin pathway-mediated activation of C3 in the absence of C4 was demonstrated in vitro and shown to require MASP-2, C2, and MASP-1/3. MASP-2 deficiency also protects mice from gastrointestinal IRI, as do mAb-based inhibitors of MASP-2. The therapeutic effects of MASP-2 inhibition in this experimental model suggest the utility of anti–MASP-2 antibody therapy in reperfusion injury and other lectin pathway-mediated disorders.

The role of complement in the early immune response to transplantation

The complement system is a key element of the innate immune system, and the production of complement components can be divided into central (hepatic) and peripheral compartments. Essential complement components such as C3 are produced in both of these compartments, but until recently the functional relevance of the peripheral synthesis of complement was unclear. Here, we review recent findings showing that local peripheral synthesis of complement in a transplanted organ is required for the immediate response of the donor organ to tissue stress and for priming alloreactive T cells that can mediate transplant rejection. We also discuss recent insights into the role of complement in antibody-mediated rejection, and we examine how new treatment strategies that take into account the separation of central and peripheral production of complement are expected to make a difference to transplant outcome.

Cyclic AMP plays a critical role in C3a-receptor mediated regulation of dendritic cells in antigen uptake and T cell stimulation

The biochemical basis for complement acting directly on antigen-presenting cells to enhance their function in T-cell stimulation has been unclear. Here we present evidence that engagement of C3a receptor (C3aR) on the surface of dendritic cells (DCs) leads to alterations in the level of intracellular cyclic adenosine monophosphate (cAMP), a potent negative regulator of inflammatory cytokines. C3aR activation-induced depression of cAMP was associated with enhanced capacity of DCs for antigen uptake and T-cell stimulation. Conversely, C3aR-deficient DCs showed elevation of cAMP and impaired properties for antigen uptake and immune stimulation. Similarities in the phenotype of C3-deficient and C3aR-deficient DCs suggest that local production of C3 with extracellular metabolism to C3a is an important driver of DC alterations in cAMP. The finding of a link between complement and adaptive immune stimulation through cAMP offers new insight into how innate and adaptive immunity combine to generate efficient effector and memory responses.

Factor I is required for the development of membranoproliferative glomerulonephritis in factor H–deficient mice

The inflammatory kidney disease membranoproliferative glomerulonephritis type II (MPGN2) is associated with dysregulation of the alternative pathway of complement activation. MPGN2 is characterized by the presence of complement C3 along the glomerular basement membrane (GBM). Spontaneous activation of C3 through the alternative pathway is regulated by 2 plasma proteins, factor H and factor I. Deficiency of either of these regulators results in uncontrolled C3 activation, although the breakdown of activated C3 is dependent on factor I. Deficiency of factor H, but not factor I, is associated with MPGN2 in humans, pigs, and mice. To explain this discordance, mice with single or combined deficiencies of these factors were studied. MPGN2 did not develop in mice with combined factor H and I deficiency or in mice deficient in factor I alone. However, administration of a source of factor I to mice with combined factor H and factor I deficiency triggered both activated C3 fragments in plasma and GBM C3 deposition. Mouse renal transplant studies demonstrated that C3 deposited along the GBM was derived from plasma. Together, these findings provide what we believe to be the first evidence that factor I-mediated generation of activated C3 fragments in the circulation is a critical determinant for the development of MPGN2 associated with factor H deficiency.

Protection against anti-glomerular basement membrane (GBM)-mediated nephritis in C3- and C4-deficient mice

Mice rendered completely deficient of the complement components C3 or C4 were used to determine the influence of complement activation in the heterologous phase of the anti‐GBM disease model. In wild‐type animals the disease is characterized by a neutrophil infiltrate, capillary thrombosis, proteinuria and C3 and C4 deposited within the glomerulus. The early infiltration of neutrophils into the glomeruli is greater in wild‐type mice (2.8 ± 0.3) compared with C3‐deficient (1.4 ± 0.2) and C4‐deficient (1.2 ± 0.003) mice. Deficiency also protects against the subsequent development of proteinuria (2.99 ± 1.11 mg/24 h, 0.059 mg/24 h and 0.327 ± 0.14 mg/24 h in wild‐type, C3‐deficient and C4‐deficient mice, respectively) and decreases glomerular capillary thrombosis in both C3‐ and C4‐deficient mice. The degree of protection is greater in the C3‐deficient than the C4‐deficient animals, suggesting both classical and alternative pathway involvement. These studies support a critical role for complement in the development of anti‐GBM disease. However, the protective effect of complement deficiency can be broken if the dose of nephritogenic antibody is increased.