Antibody mediated complement dependent lysis of virus infected cells

Novel mechanism of antibody-independent complement neutralization of herpes simplex virus type 1

The envelope surface glycoprotein C (gC) of HSV-1 interferes with the complement cascade by binding C3 and activation products C3b, iC3b, and C3c, and by blocking the interaction of C5 and properdin with C3b. Wild-type HSV-1 is resistant to Ab-independent complement neutralization; however, HSV-1 mutant virus lacking gC is highly susceptible to complement resulting in > or =100-fold reduction in virus titer. We evaluated the mechanisms by which complement inhibits HSV-1 gC null virus to better understand how gC protects against complement-mediated neutralization. C8-depleted serum prepared from an HSV-1 and -2 Ab-negative donor neutralized gC null virus comparable to complement-intact serum, indicating that C8 and terminal lytic activity are not required. In contrast, C5-depleted serum from the same donor failed to neutralize gC null virus, supporting a requirement for C5. EDTA-treated serum did not neutralize gC null virus, indicating that complement activation is required. Factor D-depleted and C6-depleted sera neutralized virus, suggesting that the alternative complement pathway and complement components beyond C5 are not required. Complement did not aggregate virus or block attachment to cells. However, complement inhibited infection before early viral gene expression, indicating that complement affects one or more of the following steps in virus replication: virus entry, uncoating, DNA transport to the nucleus, or immediate early gene expression. Therefore, in the absence of gC, HSV-1 is readily inhibited by complement by a C5-dependent mechanism that does not require viral lysis, aggregation, or blocking virus attachment.

Restriction fragment analysis of duplication of the fourth component of complement (C4A)

The two genes encoding the fourth component of complement (C4A and C4B) reside between HLA-B and HLA-DR on human chromosome 6. Two kilobases downstream from each C4 gene lies a 21-hydroxylase gene (CA21HA and CA21HB, respectively). Utilizing the method of Southern blotting and a 5'-end 2.4-kb BamHI/KpnI fragment of the C4 cDNA, we have analyzed TaqI-digested DNA from four pedigrees with one or more extended haplotypes containing a C4A duplication, as demonstrated by protein electrophoresis and segregation analysis. Two C4A protein duplications (C4A*2,A*3,C4B*QO and C4A*3,A*5,C4B*QO) segregated with two large TaqI DNA restriction fragments (7.0 and 6.0). In pedigree Fi, one individual homozygous for HLA-A3,B35,C4,DR1,DQ1,BFF,C2C,-C4A2,3,C4BQO had TaqI 7.0- and 6.0-kb restriction fragments with equal hybridization intensities as measured by two-dimensional densitometry (7.0/6.0 kb = 0.83, SD = 0.12, N = 7). A hybridization probe for the 21-hydroxylase gene also demonstrated equal gene dosage (CA21HA/CA21HB = 1.01). DNA from another individual (Ma I-2) with a different C4A gene duplication (C4A*3,A*5,C4B*QO) also had equal densitometry measurements (7.0/6.0 kb = 1.07). We conclude that two extended haplotypes from unrelated pedigrees have two C4 genes and both C4 genes encode separate C4A alleles. These findings are compatible with a gene conversion event of C4B to C4A.

Activation of the alternative complement pathway by mumps infected cells: relationship to viral neuraminidase activity

An inverse relationship exists between the sialic acid content of a particle and its ability to activate the alternative complement pathway. The present studies were performed to determine if the neuraminidase (NANase) activities of different mumps virus strains could influence the ability of mumps virus infected cells to activate the alternative pathway. CV-1 cells were infected with three different mumps virus strains (RW, O'Take, and Kilham) and after 24 hours, 10 percent guinea pig serum (GPS) treated with EGTA/MgCl2 or GPS lacking the 4th component of complement (C4DGPS) was added to the cell monolayers. After 30 minutes, the percentage C3 consumed was determined by a functional hemolytic assay. Cells infected with RW (high NANase) consumed significantly more C3 (23.2 per cent) than cells infected with Kilham (5.7 percent, low NANase). Cells infected with O'Take were intermediate in their ability to activate C3. The degree of C3 deposition on the surface of infected cells, detected by fluorescence microscopy, was also greater for cells infected with the RW than the Kilham strain of mumps virus. These studies suggest that the NANase activity of mumps virus can influence the ability of infected cells to activate the alternative pathway and thereby, the ability of complement to participate in host defense against mumps virus infection.

Genetic predisposition to acute lymphocytic leukemia in American blacks. A Pediatric Oncology Group study

Recent reports have shown an association between genes lying within the major histocompatibility complex (MHC), particularly HLA and factor B (Bf), and acute lymphocytic leukemia (ALL) in white children. The frequencies of Bf and complement component C4 phenotypes in 90 black American children with ALL were examined to determine if a genetic association existed. The Bf and C4 results for the black children with ALL were compared with frequencies in healthy black Americans from the same geographic region. The BfF allele was carried by 95.6% of the black ALL patients compared with 86.1% of the controls (P = 0.017; relative risk = 3.5). In contrast, only 2.2% of the patients with ALL were homozygous for BfS compared with 9.8% of the controls (P = 0.043; relative risk = 0.2). These findings are similar to those observed in white American children. The C4A6 phenotype was found in 11.9% of the black children with ALL compared with 0.6% of the controls (P = 0.0026; relative risk = 22.7). These findings represent the first reported association of a particular allele whose gene lies within the MHC with ALL in black American children. The results suggest that the occurrence of ALL in black American children may be partially due to a genetic influence.

The role of antibody and complement in the control of viral infections

Host defense against viral infection is extremely complex and includes both humoral and cellular immune mechanisms. This contribution examines the mechanisms by which antibody (Ab) and the complement (C) system, major constituents of the humoral immune system, inactivate viruses and block viral maturation in virus-infected cells in vitro. Ab and C may neutralize viruses by envelopment in a coating of protein, by aggregation by lysis, or by facilitating interactions with various effector cells. Ab and C molecules deposited on the surfaces of viruses may physically interfere with the ability of the virus to infect a potentially susceptible cell. This appears to be the most common mechanism by which Ab and C neutralize viruses. In rare instances, Ab and/or C may aggregate viruses; aggregation reduces the net number of infectious particles and thus is manifest as neutralization. C may lyse enveloped viruses, resulting in irreversible viral inactivation. However, this does not appear to be a major mechanism of viral neutralization. Finally, the Fc portions of bound Ab molecules as well as bound C molecules may interact with effector cells with specific receptors for these factors and thereby facilitate viral destruction. In regard to virus-infected cells, the deposition of Ab or C on the cell surface may prevent the maturation or release of viral particles and alter normal cellular functions. Ab and C may also lyse virus-infected cells, abruptly stopping further viral maturation. Such lytic events require only the F(ab')2 portion of the Ab molecule and proceed via activation of the alternative C pathway. Effector cells may also interact with Ab and/or C molecules deposited on virus-infected cells, leading to cytotoxic reactions and/or ingestion depending on the type of effector cell involved. The activated C system has the ability to produce an acute inflammatory response leading to alterations in vessel permeability, edema, changes in smooth-muscle contractility, and the influx of leukocytes. Such inflammatory responses occurring in tissues, including the skin, as a result of C activation not only retard the spread of the infection and facilitate the destruction of the infectious agent, but also in all likelihood damage normal tissues in the vicinity. In addition, C activation in tissues also has the ability to stimulate arachidonic acid metabolism and induce the release of histamine and other mediators as well as pyrogens from appropriate cell types. A number of the systemic symptoms characteristic of viral infections, such as headaches, myalgias, and fever, likely result from such processes.

Complement, viruses, and virus-infected cells

The attachment of specific antibody to viral glycoproteins and other structures on the surface of a virus or virus-infected cell has a number of potential consequences to the virus or virus-infected cell. Antibody is multivalent and thus able to redistribute or patch surface viral proteins or virus-encoded structures within the lipid bilayer of the viral envelope or the cell membrane. In certain instances, antibody may agglutinate viruses or virus-infected cells. The physical presence of antibody molecules on the virus surface may interfere with the ability of the virus to infect potentially susceptible cells. Antibody on the surface of virus-infected cells may prevent the maturation and release of virus particles; antibody also can alter certain normal cell functions. The Fc portions of antibody molecules bound to virus-infected cells facilitate interactions with effector cells bearing Fc receptors. In the case of lymphocytes and perhaps phagocytic cells, this interaction may lead to antibody-dependent cellular cytotoxicity (ADCC) [51, 58]. The exposed Fc regions may also facilitate attempts at ingestion by monocytes, macrophages, and polymorphonuclear leukocytes.

Assessment of antibody mediated cytolysis of adult cardiocytes isolated by centrifugation in a continuous gradient of Percoll in patients with acute myocarditis

Principal objections to conventional cytotoxicity assays in cardiac disease with myocytes as target cells are the use of fetal or neonatal myocardium, the cell-membrane of which does not express all antigenic determinants, and the use of trypsin as enzyme for isolation of the cells, since this alters the myolemmal membrane considerably. An improved and rapid procedure for the isolation of intact adult cardiocytes with collaggenase was developed. by means of a performed continuous self-generating silica sol and gradient centrifugation average enrichment of 81% vital myocytes was achieved by a single isopycnic procedure. The yield was improved to 94 +/- 3% vital cells by identical second centrifugation. Cardiocytes isolated by this method were used as target cells in an assay measuring the cytolytic activity of antibodies in the presence of complement: sera of patients suffering from acute viral myocarditis (Coxsackie B- and influenza-virus) with complement fixing antisacrolemmal antibodies (ASA) of the IgG- and IgM-type showed significant cardiocytolysis. ASA are postulated to play a role in the pathogenesis of acute Coxsackie B- and influenza-virus myocarditis.

On the significance of C2, C4, and factor B polymorphisms in disease

In this review article, recent evidence is presented that some diseases like insulin-dependent diabetes mellitus, multiple sclerosis, and idiopathic membranous nephropathy, which are primarily associated with HLA-D,DR, are also related to the rare C2, C4, and Factor B alleles. Circumstantial evidence is available that at least some of these rare variants may be functionally deficient. Based on the concept of functionally interacting gene clusters, mutant complement genes may lead to impaired effector mechanisms in virus neutralization or lysis of virus-infected cells. Other mechanisms such as alteration of vascular permeability may be involved in the development of proliferative retinopathy and familial hypertension. In lepromatous lepra, an impaired cell-mediated lysis of M. leprae may be related to the hemolytically inactive C4F1 allelic product.

In vivo effect of sera from animals with chronic relapsing experimental allergic encephalomyelitis on central and peripheral myelin

Sera from guinea pigs with acute or chronic relapsing experimental allergic encephalomyelitis (EAE) were injected into lumbosacral subarachnoid space of normal recipient rats. Seventeen of 37 sera induced demyelination in the CNS, and 27 of 37 sera caused demyelinated peripheral nerve fibers in the roots. The highest incidence of demyelinating activity of EAE sera was noted in those from donor animals sampled during the early chronic stage of the disease [40--100 days post sensitization (dps)]. Only few sera from animals sampled during the acute and subacute stage (10--40 dps) were able to induce demyelination. Sera from animals sampled between 100 and 200 dps showed a lower incidence of demyelinating activity as compared to those from the early chronic phase of the disease. There was no clear-cut correlation between the serum-demyelinating activity and the severity of the demyelinating disease in the donor animals. The patterns of demyelination in the central as well as peripheral nervous system of recipient animals were characterized by vesicular disruption of myelin or myelin stripping. Myelin degradation was performed mainly be macrophages. In the CNS some astrocytes also contained debris. Astrocytes increased in size, and mitosis of astrocytes was observed. Oligodendrocytes appeared to be unaffected. No demyelination was found when the sera from animals sensitized with CFA alone or with guinea pig liver tissue were injected into the subarachnoid space of normal recipient rats. Two possible mechanisms of demyelination are discussed: Antibody-mediated complement-dependent and antibody-dependent cell-mediated demyelination.