Allergic encephalomyelitis: effect of complement depletion with cobra venom

Targeted inhibition of complement using complement receptor 2-conjugated inhibitors attenuates EAE

Multiple sclerosis (MS) is the most common autoimmune demyelinating disease, affecting millions of individuals worldwide. In the last two decades, many therapeutic options for the treatment of MS have become available, however they are limited in terms of effectiveness and some remain plagued by safety issues. The currently available treatment options target relapsing remitting forms of MS and are not effective against the more progressive forms of the disease. These limitations highlight a significant unmet treatment need for MS. In experimental autoimmune encephalomyelitis (EAE) studies from our laboratory, we have previously shown, using a number of complement mutant and transgenic mice, that inhibition of the alternative complement pathway and the C3 convertase confers significant protection from disease. We report here that targeted inhibition of complement activation using complement receptor 2 (CR2)-conjugated inhibitors significantly attenuates EAE. Administration of CR2-Crry (blocks all complement pathways at C3 activation) and CR2-fH (specifically blocks the alternative pathway) just prior to and during the onset of EAE blocks progression of both acute and chronic disease. These data indicate that inhibition of complement may offer an effective therapeutic approach to treating both acute and chronic forms of demyelinating disease through blocking the alternative pathway or complement convertases.

Venom therapy in multiple sclerosis

To date many people with multiple sclerosis (MS) seek complementary and alternative medicines (CAM) to treat their symptoms as an adjunct to conventionally used therapies. Among the common CAM therapies, there is a renewed interest in the therapeutic potential of venoms in MS. The efficacy of this therapeutic method remains unclear. However, venom-based therapy using bee, snakes and scorpions venom and/or sea anemones toxin has been recently developed because current investigations have identified the various components and molecular mechanism of the effects of venoms under in vitro and in vivo conditions. The aim of this review is to describe the recent findings regarding the role of venoms and their components in treatment of MS disease and that whether venom therapy could be recommended as a complementary treatment or not.

Complement and demyelinating disease: no MAC needed?

It has long been accepted that the complement system participates in the onset, evolution, and exacerbation of demyelinating disease, and it is widely suspected that this is accomplished mainly via destruction of nervous tissue by membrane attack complex (MAC)-mediated lysis of oligodendrocytes and neurons. However, recent studies using mutant mice indicate the MAC may not be so important. For example, mice lacking C5 and mice lacking the C5a receptor both develop experimental autoimmune encephalomyelitis (EAE) with the same frequency and intensity as their wild type counterparts. Also, transgenic mice that express C5a exclusively in the central nervous system (CNS) develop EAE that is not remarkably different from that in non-transgenic littermates. Since C5 is required for formation of the MAC, development of fulminant EAE in the absence of this complement protein demonstrates that non-complement-mediated mechanisms of CNS damage are operating. Paradoxically, mice lacking C3, mice lacking the C3a receptor, and mice lacking the complement receptor type 3 develop attenuated EAE, while mice that express C3a exclusively in the CNS develop severe and often fulminant EAE. Based on these newer data, we posit that C3-derived biologically active fragments, rather than C5 and the MAC, are central players in the pathophysiology of complement in EAE.

Attenuation of experimental allergic encephalomyelitis in complement component 6-deficient rats is associated with reduced complement C9 deposition, P-selectin expression, and cellular infiltrate in spinal cords

The role of Ab deposition and complement activation, especially the membrane attack complex (MAC), in the mediation of injury in experimental allergic encephalomyelitis (EAE) is not resolved. The course of active EAE in normal PVG rats was compared with that in PVG rats deficient in the C6 component of complement (PVG/C6(-)) that are unable to form MAC. Following immunization with myelin basic protein, PVG/C6(-) rats developed significantly milder EAE than PVG/C rats. The anti-myelin basic protein response was similar in both strains, as was deposition of C3 in spinal cord. C9 was detected in PVG/C rats but not in PVG/C6(-), consistent with their lack of C6 and inability to form MAC. In PVG/C6(-) rats, the T cell and macrophage infiltrate in the spinal cord was also significantly less than in normal PVG/C rats. There was also reduced expression of P-selectin on endothelial cells, which may have contributed to the reduced cellular infiltrate by limiting migration from the circulation. Assay of cytokine mRNA by RT-PCR in the spinal cords showed no differences in the profile of Th1 or Th2 cytokines between PVG/C and PVG/C6(-) rats. PVG/C rats also had a greater increase in peripheral blood white blood cell, neutrophil, and basophil counts than was observed in the PVG/C6(-). These findings suggest that the MAC may have a role in the pathogenesis of EAE, not only by Ig-activated MAC injury but also via induction of P-selectin on vascular endothelium to promote infiltration of T cells and macrophages into the spinal cord.

Attenuation of experimental autoimmune demyelination in complement-deficient mice

The exact mechanisms leading to CNS inflammation and myelin destruction in multiple sclerosis and in its animal model, experimental allergic encephalomyelitis (EAE) remain equivocal. In both multiple sclerosis and EAE, complement activation is thought to play a pivotal role by recruiting inflammatory cells, increasing myelin phagocytosis by macrophages, and exerting direct cytotoxic effects through the deposition of the membrane attack complex on oligodendrocytes. Despite this assumption, attempts to evaluate complement's contribution to autoimmune demyelination in vivo have been limited by the lack of nontoxic and/or nonimmunogenic complement inhibitors. In this report, we used mice deficient in either C3 or factor B to clarify the role of the complement system in an Ab-independent model of EAE. Both types of complement-deficient mice presented with a markedly reduced disease severity. Although induction of EAE led to inflammatory changes in the meninges and perivascular spaces of both wild-type and complement-deficient animals, in both C3(-/-) and factor B(-/-) mice there was little infiltration of the parenchyma by macrophages and T cells. In addition, compared with their wild-type littermates, the CNS of both C3(-/-) and factor B(-/-) mice induced for EAE are protected from demyelination. These results suggest that complement might be a target for the therapeutic treatment of inflammatory demyelinating diseases of the CNS.

Antibody-mediated demyelination in experimental allergic encephalomyelitis is independent of complement membrane attack complex formation

The effects of decomplementation by cobra venom factor (CVF) on the pathogenesis of inflammation and demyelination in experimental allergic encephalomyelitis (EAE) and acute antibody-mediated demyelinating EAE (ADEAE) have been quantified histologically and immunocytochemically. In rats immunized with 50 micrograms of myelin basic protein in Freund's complete adjuvant containing 100 micrograms heat-killed Mycobacterium tuberculosis H37Ra, clinical signs of EAE were completely suppressed by two injections of CVF given 9 and 12 days post-immunization. Suppression of clinical disease was associated with a dramatic reduction in peri-vascular inflammation in the CNS, although immunohistochemical staining identified small numbers of infiltrating T cells and macrophages. In contrast, CVF treatment had no significant effect on the clinical severity of ADEAE and although C9 deposition within the CNS was virtually abolished, there was no statistically significant decrease in the extent of demyelination or inflammation. These observations indicate that in the absence of complement components C3 and C5 an antibody-dependent cell-mediated cytotoxic response plays an important role in the pathogenesis of antibody-mediated demyelination. The major role of the complement cascade in EAE appears to be the generation of pro-inflammatory factors that enhance the inflammatory response within the CNS in animals facing a mild encephalitogenic challenge.

Immunohistochemical localisation of terminal complement component C9 in experimental allergic encephalomyelitis

The deposition of terminal complement component C9 within the central nervous system (CNS) has been studied immunohistochemically in three models of experimental allergic encephalomyelitis (EAE) in the rat; inflammatory EAE induced by the passive transfer of myelin basic protein-specific T cells (tEAE), antibody-mediated, demyelinating tEAE and a subacute/chronic model induced by active immunisation with guinea pig spinal cord tissue in adjuvant. Two distinct patterns of C9 reactivity were observed, a diffuse staining of the tissue adjacent to inflammatory lesions, similar to that seen for other extra-vasculated serum proteins, and also granular, sometimes fibrillar C9 deposits around some inflammed vessels and in areas of active demyelination. The latter staining pattern was most pronounced in animals with acute antibody-mediated demyelinating tEAE, in which extensive, but transient, subpial and perivascular granular deposits of C9 were associated with regions of acute demyelination. A similar pattern of granular C9 reactivity was also associated with demyelinating lesions in animals with actively induced chronic progressive EAE. However, these C9 deposits were not observed in rats with purely inflammatory, clinically mild tEAE, although C9 deposition was occasionally observed around a small number of inflammed vessels in animals with hyperacute, lethal tEAE. These observations demonstrate that deposition of C9, the major component of the cytolytic membrane attack complex, in EAE is related to myelin injury rather than CNS inflammation.

Brain damage complicating septic shock: acute haemorrhagic leucoencephalitis as a complication of the generalised Shwartzman reaction

The neuropathological findings in six patients who developed neurological signs after the onset of "septic shock" caused by Gram-negative septicaemia are described. The changes in the brains were characteristic of acute haemorrhagic leucoencephalitis, and there was evidence, particularly in the kidneys, of disseminated intravascular coagulation with tubular necrosis and, in some, appearances indistinguishable from membrano-proliferative glomerulonephritis. It is agreed that acute haemorrhagic leucoencephalitis is another manifestation of a generalised Shwartzman reaction, and it is suggested that activation of complement is the final common pathway that produces tissue damage in the brain and kidney.

Experimental allergic encephalomyelitis in cobra venom factor-treated and C4-deficient guinea pigs

Experimental allergic encephalomyelitis (EAE) was studied in guinea pigs with an inherited deficiency of the fourth component of complement (C4) and in guinea pigs injected with cobra venom factor to deplete the third component and late-acting components of complement. EAE was elicited by immunization with homologous spinal cord or purified basic protein. Administration of cobra factor after the injection of encephalitogenic emulsion delayed the onset and reduced the intensity of the clinical manifestations of EAE. In addition, cobra factor markedly reduced mortality during the sixty days of observation. However, pathological changes of perivascular infiltration and demyelination were similar in cobra factor-treated and untreated animals. Clinical signs of EAE an mortality in C4-deficient guinea pigs were no different from those in normocomplementemic controls. Thus, although activation of the classic complement pathway does not appear to be involved in the production of EAE in guinea pigs, our results suggest a possible role of the alternative complement pathway in the pathogenesis of EAE.

Interstitial immune complex thyroiditis in mice: the role of autoantibody to thyroglobulin

Mice immunized with soluble heterologous thyroglobulins developed autoantibody that cross-reacted with autologous thyroglobulin. There was a direct correlation between the temporal appearance and quantity of serum autoantibody and the presumed in situ formation of immune complexes in the interstitium of the thyroid glands. Immediately after the formation of interstitial immune complexes containing antibody of the IgG complement-fixing type, the thyroids were invaded by a transient but intense neutrophil infiltrate which within 1 wk was replaced by chronic mononuclear elements. By the combination of fluorescence microscopy and autoradiography, thyroglobulin was demonstrated to be one, if not the sole, antigen in the interstitial immune complexes. The interstitial immune complexes were granular to lumpy in appearance and formed at the basal area of the follicular cells in intimate association with the follicular basement membrane. Electron microscopy revealed electron dense deposits, presumably immune complexes, between the follicular basement membrane and the plasma membrane. The presumed in situ formation of immune complexes in this model is similar to that which occurs in the Arthus reaction and is a different mechanism of immune complex injury than that caused by tissue deposition of circulating immune complexes as occurs in serum sickness.