C5b-9 terminal complement complex protects oligodendrocytes from death by regulating Bad through phosphatidylinositol 3-kinase/Akt pathway.

Apoptosis of oligodendrocytes is induced by serum growth factor deprivation. We showed that oligodendrocytes and progenitor cells respond to serum withdrawal by a rapid decline of Bcl-2 mRNA expression and caspase-3-dependent apoptotic death. Sublytic assembly of membrane-inserted terminal complement complexes consisting of C5b, C6, C7, C8, and C9 proteins (C5b-9) inhibits caspase-3 activation and apoptotic death of oligodendrocytes. In this study, we examined an involvement of the mitochondria in oligodendrocyte apoptosis and the role of C5b-9 on this process. Decreased phosphatidylinositol 3-kinase and Akt activities occurred in association with cytochrome c release and caspase-9 activation when cells were placed in defined medium. C5b-9 inhibited the mitochondrial pathway of apoptosis in oligodendrocytes, as shown by decreased cytochrome c release and inhibition of caspase-9 activation. Phosphatidylinositol 3-phosphate kinase and Akt activities were also induced by C5b-9, and the phosphatidylinositol 3-phosphate kinase inhibitor LY294002 reversed the protective effect of C5b-9. Phosphatidylinositol 3-phosphate kinase activity was also responsible for the phosphorylation of Bad at Ser112 and Ser136. This phosphorylation resulted in dissociation of Bad from the Bad/Bcl-xL complex in a G(i)alpha-dependent manner. The mitochondrial pathway of oligodendrocyte apoptosis is, therefore, inhibited by C5b-9 through post-translational regulation of Bad. This mechanism may be involved in the promotion of oligodendrocyte survival in inflammatory demyelinating disorders affecting the CNS.

Role of the C5b-9 complement complex in cell cycle and apoptosis.

Assembly of C5b-9 on cell membranes results in transmembrane channels and causes cell death. When the number of C5b-9 molecules is limited, nucleated cells are able to escape cell death by endocytosis and by shedding of membranes bearing C5b-9. Sublytic CSb-9 induces proto-oncogenes, activates the cell cycle, and enhances cell survival. In addition, C5b-9 reverses the differentiated phenotype of postmitotic cells, such as oligodendrocytes and skeletal muscle cells. The signal transduction pathways responsible for cell cycle activation by CSb-9 include Gi-mediated activation of extracellular signal-regulated kinase 1 and phosphatidylinositol 3-kinase (PI3-K). Cell survival enhanced by C5b-9 is mediated by the PI3-K/Akt pathway, which inhibits apoptosis through regulation of BAD. These findings indicate that complement activation and membrane assembly of sublytic C5b-9 play an important role in inflammation by promoting cell proliferation and by rescuing apoptotic cells.

Role of tumor necrosis factor-alpha in neuronal and glial apoptosis after spinal cord injury.

We investigated the role of tumor necrosis factor (TNF)-alpha in the onset of neuronal and glial apoptosis after traumatic spinal cord crush injury in rats. A few TUNEL-positive cells were first observed within and surrounding the lesion area 4 h after injury, with the largest number observed 24-48 h after injury. Double-labeling of cells using cell type-specific markers revealed that TUNEL-positive cells were either neurons or oligodendrocytes. One hour after injury, an intense immunoreactivity to TNF-alpha was observed in neurons and glial cells in the lesion area, but also seen in cells several mm from the lesion site rostrally and caudally. The level of nitric oxide (NO) also significantly increased in the spinal cord 4 h after injury. The injection of a neutralizing antibody against TNF-alpha into the lesion site several min after injury significantly reduced both the level of NO observed 4 h thereafter as well as the number of apoptotic cells observed 24 h after spinal cord trauma. An inhibitor of nitric oxide synthase (NOS), N(G)-monomethyl-l-arginine acetate (l-NMMA), also reduced the number of apoptotic cells. This reduction of apoptotic cells was associated with a decrease in DNA laddering on agarose gel electrophoresis. These results suggest that: (i) TNF-alpha may function as an external signal initiating apoptosis in neurons and oligodendrocytes after spinal cord injury; and (ii) TNF-alpha-initiated apoptosis may be mediated in part by NO as produced by a NOS expressed in response to TNF-alpha.

Inhibition of oligodendrocyte apoptosis by sublytic C5b-9 is associated with enhanced synthesis of bcl-2 and mediated by inhibition of caspase-3 activation.

We have previously shown that generation of sublytic C5b-9, the membrane attack complex of complement, induces oligodendrocytes to enter cell cycle and reduces apoptotic cell death in vitro. In the present study, the cellular factors involved in apoptosis of oligodendrocyte progenitor cells and oligodendrocytes, and the inhibitory effect of C5b-9 on apoptotic process were investigated. Oligodendrocyte progenitor cells identified by mAb A2B5 that were isolated from neonatal rat brains were differentiated into oligodendrocytes in serum-free defined medium. The differentiation, which occurs simultaneously with apoptotic cell death, was associated with a rapid loss of bcl-2 mRNA and increased expression of caspase-3 mRNA. Activation of caspase-3 in differentiating cells was demonstrated by the generation of 17- and 12-kDa fragments of caspase-3 proenzyme and by cleavage of poly(ADP-ribose) polymerase, a specific caspase-3 substrate. Cell death associated with differentiation was inhibited by the caspase-3 inhibitor DEVD-CHO in a dose-dependent manner. Assembly of sublytic C5b-9 resulted in inhibition of caspase-3 activation. In addition, synthesis of BCL-2 protein in oligodendrocytes was significantly increased by C5b-9. The TNF-alpha-induced apoptosis of oligodendrocytes was also inhibited by C5b-9. These results indicate that up-regulation of BCL-2 protein and inhibition of caspase-3 activation are potential mechanisms by which C5b-9 increases survival of oligodendrocyte in vitro and possibly in vivo during inflammation and immune-mediated demyelination affecting the CNS.

Requirements for measles virus induction of RANTES chemokine in human astrocytoma-derived U373 cells.

Interferons and chemokines play a critical role in regulating the host response to viral infection. Measles virus, a member of the Paramyxoviridae family, induces RANTES expression by astrocytes. We have examined the mechanism of this induction in U373 cells derived from a human astrocytoma. RANTES was induced in a dose- and time-dependent manner by measles virus infection. Inhibition of receptor binding by the anti-CD46 antibody TRA-2.10 and of virus-membrane fusion by the tripeptide X-Phe-Phe-Gly reduced RANTES expression. Formalin-inactivated virus, which can bind but not fuse, and extensively UV-irradiated virus, which can bind and fuse, were both ineffective. Therefore, virus binding to the cellular receptor CD46 and subsequent membrane fusion were necessary, but not sufficient, to induce RANTES. UV irradiation of virus for less than 10 min proportionally inhibited viral transcription and RANTES expression. RANTES induction was decreased in infected cells treated with ribavirin, which inhibits measles virus transcription. However, RANTES mRNA was superinduced by measles virus in the presence of cycloheximide. These data suggest that partial transcription of the viral genome is sufficient and necessary for RANTES induction, whereas viral protein synthesis and replication are not required. This hypothesis was supported by the fact that RANTES was induced through transient expression of the measles virus nucleocapsid gene but not by measles genes encoding P or L proteins or by leader RNA in A549 cells. Thus, transcription of specific portions of measles virus RNA, such as the nucleocapsid gene, appears able to generate the specific signaling required to induce RANTES gene expression.

IP-10 gene transcription by virus in astrocytes requires cooperation of ISRE with adjacent kappaB site but not IRF-1 or viral transcription.

Transcription of the IP-10 gene requires interferon (IFN)-stimulated response element (ISRE) and kappaB sites to be induced by lipopolysaccharide (LPS), IFN-gamma, virus, and poly(I:C). A requirement for Stat1 binding to ISRE for IFN-gamma and IFN regulatory factor-1 (IRF-1) binding to ISRE for LPS, poly(I:C), and virus has been reported. We investigated whether viral transcription is required for IP-10 induction and how ISRE interacts with IRF-1 and with two kappaB sites. IP-10 mRNA was induced by Newcastle disease virus and Sendai virus in rat astrocytes and the human astrocytoma U251 cell line. IP-10 was also induced by UV-irradiated virus, which is unable to carry out viral transcription. The minimal IP-10 virus response element (VRE) consists of an ISRE and adjacent kappaB site between -236 and -153, to which p50/p65 NF-kappaB proteins and IRF-like proteins bind. Virus induced NF-kappaB binding to an isolated kappaB sequence adjacent to ISRE. However, no protein binding to isolated ISRE was induced by virus. Virus also induced IP-10 in cells expressing a defective IRF-1 gene. Therefore, effective ISRE activity of IP-10 VRE may require an IRF-like protein binding, which is enhanced by an NF-kappaB heterodimer binding to an adjacent KB site. IRF-1 is not required for virus-induced IP-10 gene expression.

Molecular cloning and characterization of RGC-32, a novel gene induced by complement activation in oligodendrocytes.

Sublytic complement activation on oligodendrocytes (OLG) down-regulates expression of myelin genes and induces cell cycle in culture. Differential display (DD) was used to search for new genes whose expression is altered in response to complement and that may be involved in cell cycle activation. DD bands showing either increased or decreased mRNA expression in response to complement were identified and designated Response Genes to Complement (RGC) 1-32. RGC-1 is identical with heat shock protein 105, RGC-2 with poly(ADP-ribose) polymerase, and RGC-10 with IP-10. A new gene, RGC-32, that encodes a protein of 137 amino acids was cloned. RGC-32 has no homology with other known proteins, and contains no motif that would indicate its function. In OLG, the mRNA expression was increased by complement activation and by terminal complement complex assembly. RGC-32 protein was localized in the cytoplasm and co-immunoprecipitated with cdc2 kinase. Overexpression of RGC-32 increased DNA synthesis in OLGxC6 glioma cell hybrids. These results suggest that RGC-32 may play a role in cell cycle activation.

Induction of IP-10 chemokine promoter by measles virus: comparison with interferon-gamma shows the use of the same response element but with differential DNA-protein binding profiles.

Measles virus (MV) and interferon (IFN)-gamma induced IP-10 chemokine mRNA in U373 glioblastoma cells. The minimal response element for both MV and IFN-gamma was localized between nucleotide -231 and -153 of muIP-10 promoter, which contains an IFN-stimulated response element (ISRE) and the distal NF-kappa Bd site. Mutation of individual elements showed that ISRE and NF-kappa Bd were required to function together. DNA-protein binding profiles with the minimal response element showed that IFN-gamma induced a complex consisting of STAT1 while MV induced a complex consisting of p50 and p65 in the absence of new protein synthesis. IFN-gamma and MV also induced IRF-1 DNA binding activity which persisted for longer time periods with IFN-gamma stimulation. Despite the functional requirement of both ISRE and NF-kappa Bd elements, different combinations of DNA binding factors are used in the induction of IP-10 by MV or IFN-gamma.

Activation of Ras and mitogen-activated protein kinase pathway by terminal complement complexes is G protein dependent.

Assembly of terminal complement complexes (TCC) C5b-7, C5b-8, and C5b-9 on target cells during acute and chronic inflammation induces hydrolysis of plasma membrane phospholipids and heterotrimeric G protein activation. TCC also stimulate a variety of cellular activities, which include cytokine synthesis, proto-oncogene activation, and mitotic signaling. Now we report that sublytic TCC induced Ras, Raf-1, and extracellular signal-regulated kinase (ERK) 1 activation in JY25 B cell line. When cells were exposed to C5b-9, GTP-bound Ras in anti-C5b-9 immunoprecipitates was increased 3.2-fold at 2 min, while GTP-bound Ras in anti-Ras immunoprecipitates was increased 2-fold at 10 min. Both C5b-9 and C5b-7, but not C5b6, increased Raf-1 kinase activity maximum 3.3-fold at 2 min and 2.8-fold at 5 min, respectively. ERK1 activity was 2-fold increased by C5b-9 at 2 min and by C5b-7 at 10 min, over the C5b6 level. The role of mitogen-activated protein kinase (MAPK) pathway on TCC-inducible mitotic signaling was evaluated by assessing DNA synthesis and activator protein 1 (AP-1) DNA-binding activity. The MAPK/ERK-specific inhibitor PD 098,059 abolished the C5b-9-induced DNA synthesis. Involvement of G protein in the activation of MAPK pathway by TCC was indicated by inhibition of Raf-1 and ERK1 kinase activity, as well as the DNA synthesis by pretreatment of cells with pertussis toxin. Overexpression of beta-adrenergic receptor kinase 1 carboxyl-terminal peptide in JY25 cells also inhibited Raf-1 and ERK1 activity, indicating a direct involvement of G betagamma subunits in the signal transduction generated through activation of MAPK pathway by TCC assembly in the plasma membrane.

Sublytic terminal complement attack on myotubes decreases the expression of mRNAs encoding muscle-specific proteins.

Activation of inflammatory and cytotoxic complement effectors that include the C5b-9 complex plays an important pathogenic role in myasthenia gravis, an inflammatory autoimmune disease of the muscle. Altered muscle-specific gene expression has been observed in experimental myasthenic rats. In this study, we have examined the effect of sublytic C5b-9 on myotubes differentiated from C2C12 myoblasts, by generating C5b-9 with C7-deficient serum with or without C7. Within 2 h, C7-deficient serum plus C7, compared with C7-deficient serum alone, induced markedly decreased levels of mRNAs encoding alpha-actin, troponin I slow twitch isoform, acetylcholine receptor alpha, and muscle aldolase A, whereas the heat shock protein 83 mRNA level remained constant, by northern analysis. Because the half-life of the acetylcholine receptor alpha was estimated to be > 8 h, the C5b-9 effect was, in part, due to enhanced mRNA decay. Because C5b-9 also induced c-jun mRNA and reduced the myoD mRNA level, a possible inhibition of muscle gene transcription by C5b-9 was examined in myotubes transfected with troponin promoter-luciferase gene constructs. Luciferase activity was reduced to 50% in response to C5b-9 at 2 h. Thus, C5b-9 appears to inhibit the muscle-specific gene expression by stimulating mRNA decay and by decreasing the transcription process. The data also indicate a possible pathogenic role of C5b-9 in immune-mediated inflammatory muscle disorders in which complement activation has been implicated.

Terminal complement complexes induce cell cycle entry in oligodendrocytes through mitogen activated protein kinase pathway.

Sublytic complement attack through C5b-9 assembly induces oligodendrocytes (OLG) to express proto-oncogenes and to enter the cell cycle from resting G0/G1 phase to S phase. We have investigated whether cell cycle induction by C5b-9 is mediated by mitogen activated protein kinase (MAPK) pathway in OLG. C5b-9 but not C5b6 induced activation of both ERK1 and c-jun NH2 terminal kinases 1 (JNK1) in OLG. The increased ERK1 and JNK1 activities are transient, reaching a maximum around 20 min following exposure to C5b-9. Activation of Raf-1 and MEK1, upstream kinases of ERK1, was shown by increased Raf-1 kinase activity in anti-Raf-1 immunoprecipitates of OLG treated with C5b-9 and ERK1 activity that can be inhibited by PD098,059, a specific MEK1 inhibitor. Requirement for the ERK1 pathway in DNA synthesis was then evaluated using PD098,059. Enhanced DNA synthesis induced by serum complement was completely abolished when OLG were pretreated with PD098,059. On the other hand, c-fos mRNA expression induced by complement was inhibited only 50% by PD098,059, while the c-jun mRNA level was not affected by this MEK1 inhibitor. Interestingly, p70 S6 kinase, an important ribosomal kinase in mitogenesis, was also activated by C5b-9. These findings indicated that the MAPK pathways appears to play a major role in inducing OLG to enter the S phase of the cell cycle from the resting G1/G0 phase.

Sublytic complement attack induces cell cycle in oligodendrocytes.

Sublytic complement attack on oligodendrocytes (OLG) by activation of terminal complement complexes (TCC) selectively enhances the decay of myelin protein mRNAs. We have investigated whether TCC also stimulate differentiated OLG to enter the cell cycle and whether the cell cycle induction is related to the oncogene expression. Complement activation and TCC assembly induced expression of c-jun, JunD, and c-fos mRNAs, increased AP-1 DNA-binding activity within 1 h, and increased [3H]thymidine uptake. The c-jun NH2-terminal kinase activity was increased to the maximum level 20 min after TCC assembly. The increase in thymidine uptake was inhibited by pretreatment of OLG with antisense c-jun oligonucleotides. Studies on cyclin-dependent kinase (cdk) activation revealed that complement increased cyclin-dependent cell cycle associated kinase-2 activity in G1, while cdk2 and cdk4 showed low activity during G1 progression. However, the activity of cdk4 complexed with cyclin D2 showed a marked increase in G1/S transition. Our data provide evidence that sublytic TCC stimulate OLG to enter the cell cycle by induction of c-jun through activation of the c-jun NH2-terminal kinase pathway. In addition, sublytic TCC assembly significantly reduced the number of OLG undergoing apoptotic cell death, which occurs spontaneously in defined medium. These changes together with enhanced degradation of myelin protein mRNA may represent a mechanism for differentiated primary OLG to respond to limited complement activation in inflammation.

Binding of a protein to an AU-rich domain of tumour necrosis factor alpha mRNA as a 35 kDa complex and its regulation in primary rat astrocytes.

Newcastle disease virus (NDV) induces tumour necrosis factor alpha (TNF alpha) gene transcription and increases the mRNA stability. NDV stabilizes TNF alpha mRNA by preventing poly(A) shortening in a protein kinase C-dependent manner. TNF alpha 3'-untranslated region (UTR) contains an AU-rich domain (ARD) with seven AUUUA pentamers, a motif implicated in poly(A) removal and mRNA degradation. In this report, protein binding to TNF alpha ARD and the effects of NDV and kinases on ARD-binding activity were investigated in primary rat astrocytes. Both nuclear and cytoplasmic extracts contained proteins binding to centrally located 27 nt AUUUAUUAUUUAUUUAUUAUUUAUUUA, within TNF alpha ARD. Portions of ARD with a single AUUUA did not show ARD-binding activity. The ARD-protein complexes migrated as two bands on electrophoretic mobility-shift assay. The slower moving complexes appeared either as a broader band or doublets. The UV cross-linked ARD-protein complexes, however, migrated as a single 35 kDa band on SDS/PAGE. In cytoplasmic extracts treated with alkaline phosphatase there was a decrease in the faster moving complex and an increase in the slower moving complex, whereas NDV infection produced the reverse effect. In addition, the faster moving complex was decreased when cytoplasmic extracts from NDV-infected cells were treated with protein phosphatase 1 or 2A. Neither NDV infection nor phosphatase treatment affected the mobility pattern of nuclear extracts. The data indicate that a protein of molecular mass less than 35 kDa binds to a segment of TNF alpha ARD containing primarily UUAUUUAUU motifs, and the ARD-binding activity in cytoplasmic compartment is post-transcriptionally modified.

Regulatory mechanisms of MuRantes and CRG-2 chemokine gene induction in central nervous system glial cells by virus.

In this report we characterize the induction mechanisms of two chemokine genes, MuRantes and crg-2, the murine homologs of human RANTES and IP-10, respectively, in primary rat astrocytes and microglia by the neurotropic paramyxovirus, Newcastle Disease Virus (NDV). The time course for NDV induction of both MuRantes and crg-2 genes in astrocytes and microglia was similar, with peak mRNA expression at 10-12 h. Unlike crg-2, MuRantes mRNA was not induced by IFN-gamma. MuRantes and crg-2 are transcriptionally induced by noninfectious, UV-irradiated NDV in astrocytes and microglia, unlike TNFalpha gene transcription, which is induced only by live NDV. These data indicate that signals generated through virus-receptor interaction on the target cell surface suffice to initiate MuRantes and crg-2 gene transcription in the absence of viral replication. In astrocytes, MuRantes mRNA accumulation in response to NDV was completely blocked by tyrosine kinase inhibitors, and partially by PKC and PKA inhibitors, whereas crg-2 mRNA accumulation was significantly inhibited by PKC inhibitors, but minimally or not affected by inhibitors of tyrosine kinase or PKA activity. These kinase inhibitors also affected MuRantes and crg-2 gene transcription in similar patterns to those observed for mRNA levels, but did not reduce the mRNA stability. Therefore, the signals required for mRNA accumulation appear to operate at the level of transcription. Efficient transcription of MuRantes and crg-2 genes may require different sets of transcriptional proteins and enhancers that are regulated by different signaling pathways activated by NDV.

Tyrosine kinase activation by Newcastle disease virus is required for TNF-alpha gene induction in astrocytes.

Astrocytes, when appropriately stimulated, produce a variety of cytokines including TNF-alpha. Production of TNF-alpha by astrocytes stimulated with Newcastle disease virus (NDV) is achieved by transcriptional activation and mRNA stabilization. A PKC-dependent pathway is responsible for a 10-fold increase in TNF-alpha mRNA stability by reducing poly(A) tail removal. The present study examined signal pathways induced by NDV in primary rat astrocytes that are responsible for TNF-alpha gene transcription as well as the possible source of kinase activity required for mRNA stabilization. Transcription of TNF-alpha gene in astrocytes stimulated by NDV or LPS and IFN-gamma was inhibited completely by the tyrosine kinase inhibitor herbimycin, and partially by a PKC inhibitor H7, as determined by nuclear run-on assay. HA-1004, a cyclic nucleotide-dependent kinase inhibitor, showed no effect. These results indicated that tyrosine kinase signaling pathways seemed to precede the activation of PKC in induction of TNF-alpha gene. Increase in tyrosine kinase activity in NDV-infected astrocytes was demonstrated by a two- to threefold increase in tyrosine phosphorylation of Pl-PLC gamma 1. Because astrocytes contain minimal Pl-PLC beta, and NDV-induced TNF-alpha mRNA was affected by pertussis toxin only modestly, Pl-PLC gamma 1 is likely the enzyme responsible for DAG generation and the PKC-dependent mRNA stabilization in response to NDV.

Definition of a lipopolysaccharide-responsive element in the 5'-flanking regions of MuRantes and crg-2.

Macrophages are stimulated by lipopolysaccharide (LPS) of gram-negative organisms. The changes in LPS-stimulated macrophages include transcriptional activation of multiple immediate-early genes, which may contribute to the natural immunity to microorganisms. We have defined by deletion and mutational analysis LPS-responsive elements (LREs) in two chemokine genes, MuRantes and crg-2, which are activated in an immediate-early manner. LRE consists of two motifs, TCAYR, which is an AP-1 half site with two flanking bases, and (A/T) (G/C)NTTYC(A/T)NTTY, which resembles in part the interferon-stimulated responsive element (ISRE). The orientation of these two motifs relative to each other in MuRantes differed from that in crg-2. These two motifs are separated by 10 and 6 nonconsensus nucleotides in the MuRantes and crg-2 LREs, respectively. Stimulation of macrophage-like RAW 264.7 cells with alpha/beta interferon did not activate MuRantes, indicating that the ISRE-like motif in MuRantes does not have ISRE activity. Upon stimulation of RAW 264.7 cells with LPS, proteins capable of binding to LRE accumulate in the nuclei as measured by electrophoretic mobility shift assay. These LRE-binding proteins include c-Jun and CREB.

Effects of Ca2+ deregulation on mitochondrial membrane potential and cell viability in nucleated cells following lytic complement attack.

We have previously shown [Papadimitriou JC. Ramm LE. Drachenberg CB. Trump BF. Shin ML. (1991) J. Immunol., 147, 212-217] that formation of lytic C5b-9 channels on Ehrlich ascites tumor cells induced rapid depletion of adenine nucleotides associated with prelytic leakage preceding cell death. Extracellular Ca2+ concentration ([Ca2+]e) reduction by chelation markedly delayed the onset of cell death, although the adenine nucleotide leakage was enhanced. In the present study, we examined the temporal relationships between ionized cytosolic Ca2+ ([Ca2+]i), mitochondrial membrane potential (delta psi m) and cell death in individual cells by digital imaging fluorescence microscopy (DIFM), during the earliest phase of C5b-9 attack. The results showed an immediate, > 20-fold rise in [Ca2+]i, rapidly followed by dissipation of delta psi m and subsequent acute cell death. These events were markedly delayed by chelation of Ca2+e, but not by nominally Ca2+ free medium. Differing from previous reports indicating propidium iodide labeling of viable cells bearing C5b-9 channels, with DIFM we observed nuclear fluorescence with that marker only in association with cell death. These findings indicate that Ca2+ influx through lytic C5b-9 channels is responsible for the massive increase in [Ca2+]i, as well as for the rapid loss of delta psi m, followed by acute cell death. When this [Ca2+]i increase is prevented, the cell death is probably related to metabolic depletion.

Ultrastructural studies of complement mediated cell death: a biological reaction model to plasma membrane injury.

Complement-mediated nucleated cell death has been shown to be independent of colloid-osmotic swelling. In contrast, other factors (e.g. Ca2+ influx) are of importance in the induction of cell death. In this communication, the sequential morphological features of complement-mediated cell injury have been studied by electron microscopy and compared with biochemical data (ATP content and LDH release). It was observed that immediately after C5b-8 lesion formation, although the overall cell, morphology is well preserved, the mitochondria display an "ultracondensed" appearance. Upon addition of C9, the mitochondria remain initially condensed, but swell progressively with final formation of flocculent densities. The nuclei become progressively edematous, with concurrent disappearance of heterochromatin. The nucleoli lose their associated chromatin and display segregation of their components with formation of markedly electron-dense filamentous deposits. The nuclear envelope remains initially intact, but subsequently progressive dilatation of the associated perinuclear RER cisterna and distention of the nuclear pores associated with leakage of chromatin into the cytoplasm are seen. The larger cell organelles (including mitochondria, ER, Golgi apparatus, etc.) become clustered around the nucleus, concurrently with marked edema of the outer cytoplasm and bleb formation. The RER cisternae become dilated, whereas the Golgi complex disappears. Relatively early on the plasma membrane shows breaks in continuity. The pattern of these changes--potentially related to Ca2+ influx, ATP efflux and overall metabolic depletion--corresponds to the previously described model of cell reaction to injury, confirming the dynamic nature of the process. The morphology of cell death in this model shares some features, e.g., the nucleolar changes, with "apoptosis" (programmed cell death). However, the overall pattern appears to correspond more to "necrosis," characterized by loss of volume control and mitochondrial abnormalities.

Enhanced degradation of messenger RNA encoding myelin proteins by terminal complement complexes in oligodendrocytes.

Sublytic terminal C complexes (TCC) are capable of stimulating cells and affect the target cell activity. Activation of TCC that generates leukotriene B4 in oligodendrocytes, the myelin-forming cells of the central nervous system, is also a required process in antibody-mediated demyelination of rodent cerebellar explants. In the present study, the effect of TCC on myelin protein gene expression was studied in primary rat oligodendrocytes in culture. Sublytic activation of serum C reduced accumulation of mRNA encoding proteolipid protein (PLP) and myelin basic protein (MBP) within 1 h, but not beta-actin mRNA. C activation, on the other hand, induced sustained expression of c-jun mRNA. Experiments using C7-deficient human serum to determine the role of TCC showed that selective MBP and PLP mRNA down-regulation was achieved only when C7 was reconstituted to form TCC. The C7 requirement was also observed in the presence of alpha-amanitin. Post-transcriptional regulation was explored by determining mRNA decay, which demonstrated that the MBP and PLP mRNA were selectively destabilized when C7 was reconstituted. Limited exploration of the signals responsible for the TCC effect revealed that down-regulation of mRNA by TCC was significantly influenced by Ca2+ on PLP, whereas MBP did not show the same Ca2+ sensitivity as PLP. The TCC-mediated MBP mRNA decay was completely abrogated by HA1004, an inhibitor for the cAMP- and cGMP-dependent protein kinases, but not by H7, a protein kinase C inhibitor.

Glutamate differentially inhibits the expression of class II MHC antigens on astrocytes and microglia.

MHC molecules are required for Ag recognition by T cells. Inasmuch as cells in the central nervous system do not express MHC constitutively, appearance of MHC, in inflammatory and degenerative diseases of the brain, may indicate local Ag presentation and subsequent immune response. Although both astrocytes and microglia are capable of class II MHC expression in vitro, in vivo studies failed to show the presence of significant amounts of class II on astrocytes compared to microglia. Our study is designed to clarify possible regulatory mechanisms that can explain the differences in inducibility of class II MHC between astrocytes and microglia in vivo. Using dissociated rat brain cell cultures, we have found that glutamate, an excitatory neurotransmitter, exerted a profound inhibitory effect on IFN-gamma-induced expression of class II on astrocytes, but not on microglia. Both glutamate and norepinephrine, a neurotransmitter previously reported to down-regulate class II on astrocytes, inhibited the induction of class II on astrocytes by eliminating accumulation of class II MHC mRNA. The kinetics of class II mRNA induction by IFN-gamma in the presence of glutamate suggested that glutamate may act as a transcriptional inhibitor. It is likely that class II induction on astrocytes in vivo may be selectively down-regulated by neurotransmitters such as glutamate and norepinephrine.