Specific suppression of major histocompatibility complex class I and class II genes in astrocytes by brain-enriched gangliosides.

The effect of brain-enriched gangliosides on constitutive and cytokine-inducible expression of major histocompatibility complex (MHC) class I and II genes in cultured astrocytes was studied. Before treatment with gangliosides, astrocytes expressed constitutive MHC class I but not class II molecules, however, the expression of both MHC class I and II cell surface molecules on astrocytes was induced to high levels by interferon gamma (IFN-gamma). Constitutive and IFN-gamma-inducible expression of MHC class I and II molecules was suppressed by treatment of astrocytes with exogenous bovine brain gangliosides in a dose-dependent manner. Constitutive and induced MHC class I and II mRNA levels were also suppressed by gangliosides, indicating control through transcriptional mechanisms. This was consistent with the ability of gangliosides to suppress the binding activity of transcription factors, especially NF-kappa B-like binding activity, important for the expression of both MHC class I and II genes. These studies may be important for understanding mechanisms of central nervous system (CNS)-specific regulation of major histocompatibility molecules in neuroectodermal cells and the role of gangliosides in regulating MHC-restricted antiviral and autoimmune responses within the CNS.

Inducibility of Ia antigen on astrocytes by murine coronavirus JHM is rat strain dependent.

Inducibility of Ia molecules on cultivated astrocytes by JHM virus correlates with demyelinating disease susceptibility of animals from which these astrocytes are derived. On the contrary, class I induction of both astrocytes and oligodendrocytes occurs as a consequence of normal cultivation procedures in both susceptible and resistant strains. Increased expression of class I antigens on rat astrocytes and oligodendrocytes is not related to JHM viral infection as it is in the mouse. These data indicate that strain differences in Ia inducibility, rather than inducibility of class I antigens, by JHM virus may explain higher levels of T cell-mediated damage to myelin during infection in susceptible rat strains compared with resistant strains.

Oligodendrocyte-specific expression and autoantigenicity of transaldolase in multiple sclerosis.

Although the etiology of multiple sclerosis (MS) is unknown, there is compelling evidence that its pathogenesis is mediated through the immune system. Molecular mimicry, i.e., crossreactivity between self-antigens and viral proteins, has been implicated in the initiation of autoimmunity and MS. Based on homology to human T cell lymphotropic virus type I (HTLV-I) a novel human retrotransposon was cloned and found to constitute an integral part of the coding sequence of the human transaldolase gene (TAL-H). TAL-H is a key enzyme of the nonoxidative pentose phosphate pathway (PPP) providing ribose-5-phosphate for nucleic acid synthesis and NADPH for lipid biosynthesis. Another fundamental function of the PPP is to maintain glutathione at a reduced state and, consequently, to protect sulfhydryl groups and cellular integrity from oxygen radicals. Immunohistochemical analyses of human brain sections and primary murine brain cell cultures demonstrated that TAL is expressed selectively in oligodendrocytes at high levels, possibly linked to production of large amounts of lipids as a major component of myelin, and to the protection of the vast network of myelin sheaths from oxygen radicals. High-affinity autoantibodies to recombinant TAL-H were detected in serum (25/87) and cerebrospinal fluid (15/20) of patients with MS. By contrast, TAL-H antibodies were absent in 145 normal individuals and patients with other autoimmune and neurological diseases. In addition, recombinant TAL-H stimulated proliferation and caused aggregate formation of peripheral blood lymphocytes from patients with MS. Remarkable amino acid sequence homologies were noted between TAL-H and core proteins of human retroviruses. Presence of crossreactive antigenic epitopes between recombinant TAL-H and HTLV-I/human immunodeficiency virus type 1 (HIV-1) gas proteins was demonstrated by Western blot analysis. The results suggest that molecular mimicry between viral core proteins and TAL-H may play a role in breaking immunological tolerance and leading to a selective destruction of oligodendrocytes in MS.

Characterization of an Na+/K+/Cl- co-transport in primary cultures of rat astrocytes.

The furosemide- and bumetanide-sensitive component of the 86Rb+ uptake into primary cultures of rat astrocytes was fully dependent on the simultaneous presence of Na+ and Cl- in the incubation mixture and is therefore most likely an Na+/K+/Cl- co-transporter. As expected for such a co-transporter, its activity is insensitive to 0.1 mM amiloride and to 4-acetamido-4'-isothiocyanostilbene-2,2'-disulfonic acid, and of the tested anions, only Br- could partly replace Cl-. The K0.5 values for K+, Na+ and Cl- activation were 2.7, 35 and 40 mM, respectively. The activity of the co-transporter was stimulated 1.5-times in hyperosmolar (500 mosM) medium.

Interferon regulatory factor element and interferon regulatory factor 1 in the induction of major histocompatibility complex class I genes in neural cells.

The role of the MHC-IRF-E and interferon regulatory factor 1 (IRF-1) in the regulation of MHC class I genes in astrocytes was analyzed. Transcriptional activation of MHC class I genes after treatment of astrocytes with various inducers occurred over a period of hours and correlated with cell surface expression. Functional analysis of the MHC class I gene promoter region confirmed that induction was controlled by a restricted region of 88 base pairs containing two well-defined inducible enhancers, the MHC-CRE and the MHC-IRF-E. Further analysis showed that potential MHC-CRE enhancer activity was silent. Therefore, the MHC-IRF-E, rather than the MHC-CRE, appeared responsible for enhancement of the MHC class I gene and was supported by three findings: (1) site-directed mutation of the MHC-IRF-E-abrogated induction, (2) promoter constructs containing IRF-Es as the sole enhancers were highly inducible in astrocytes, and (3) the expression of transcription factor IRF-1, which acts through the MHC-IRF-E to induce MHC class I genes, was induced to high levels in parallel with that of MHC class I induction. The induction of the IRF-1 gene correlated with the prior induction of the gamma-activated factor (GAF) or NF-kappa B, depending on the inducer, indicating that both gamma activation sites (GAS) and kappa B sites in the IRF-1 promoter are important.(ABSTRACT TRUNCATED AT 250 WORDS)

Increased inducible activation of NF-kappaB and responsive genes in astrocytes deficient in the protein tyrosine phosphatase SHP-1.

The protein tyrosine phosphatase SHP-1 is critical for controlling cytokine signaling through the Jak-Stat pathway and, consequently, for controlling inflammatory cellular immune responses dependent on these cytokines. However, the role of SHP-1 in regulating proinflammatory signaling may be incompletely understood, and it may control other distinct inflammatory agents. The present study analyzed the ability of tumor necrosis factor-alpha (TNF-alpha), double-stranded RNA, and interferon-gamma (IFN-gamma) to induce the transcription factor NF-kappaB in astrocytes expressing or lacking SHP-1. On exposure to the inducers, NF-kappaB was markedly increased in astrocytes obtained from motheaten mice lacking SHP-1 compared with normal littermate cells expressing SHP-1, consisted of p50 and p65 subunits, and was induced in a protein synthesis-independent manner. The increased nuclear NF-kappaB expression coincided with elevated loss of the cytoplasmic inhibitor IkappaB alpha in motheaten mouse cells. Enhanced NF-kappaB expression in motheaten mouse cells correlated with increased expression of genes with functional kappaB sites, including IFN regulatory factor-1 (IRF-1) and inducible nitric oxide synthase (iNOS) genes. MHC class I molecules were also increased in motheaten cells, consistent with the increased expression of IRF-1. Together, the data indicate an increased sensitivity of cells lacking SHP-1 to various inducers of NF-kappaB. Therefore, the regulation of not only Stats but also of NF-kappaB by SHP-1 may be important in controlling events promoted by proinflammatory agents in vivo that are especially apparent in multiple tissues of motheaten mice. This study suggests an additional role for SHP-1 in controlling specific and nonspecific immune responses where induction of NF-kappaB is involved.

Neuron-specific regulation of major histocompatibility complex class I, interferon-beta, and anti-viral state genes.

The regulation of major histocompatibility complex (MHC) class I, interferon (IFN)-beta, and anti-viral state expression in neurons was analyzed. Treatment of neurons with either double-stranded RNA (poly I: poly C) or virus, but not IFNs, induced high levels of IFN-beta, but not MHC class I genes. However, neurons treated with IFN-beta established an anti-viral state. Transfection of neurons with IFN-beta constructs showed that a region containing PRDI (IRF-E site) and PRDII (kappa B site) mediated induction, but closely related sites in a MHC class I construct did not. Gel mobility shift assays indicated that transcription factors containing the RelA (p65) component of NF-kappa B, but not p50, bound to PRDII. PRDI, however, bound to transcriptional antagonist IRF-2. Unique selective induction of these transcription factors is likely to mediate non-coordinate expression of IFN-beta, MHC class I, and anti-viral state genes in neurons.

Inducibility of Ia molecules on keratinocytes reflects genetic control on astrocytes in the brain.

We have recently observed strain differences in interferon-gamma (IFN-gamma) induction of Ia on astrocytes in rats and mice that are susceptible or resistant to experimental allergic encephalomyelitis (EAE) (Massa et al., 1987). We now found that keratinocytes cultured from rat skin show the same strain differences as astrocytes. Keratinocytes of EAE-susceptible Lewis rats are induced to higher levels of Ia expression compared to relatively resistant Brown-Norway (BN) rats, independent of the dose of IFN-gamma applied. This difference in regulation is specific for class II histocompatibility molecules because no such differences are seen with class I antigen induction by IFN-gamma. That keratinocytes reflect similar strain differences as astrocytes may be explained by a common ectodermal origin of these epithelial-like cells. This observation allows the determination of the genetic predisposition of an autoimmune response in the central nervous system by skin biopsy. This approach may be of importance in studies of immunopathological phenomena of brain tissue in man such as multiple sclerosis.

Analysis of Ia induction on Lewis rat astrocytes in vitro by virus particles and bacterial adjuvants.

Viral particles of a neurotropic murine hepatitis virus (JHM) and various substances known to have immunoregulatory effects, including bacterial lipopolysaccharide (LPS) and synthetic adjuvant peptide (muramyl dipeptide) (AP), were tested for their ability to induce Ia antigen expression on Lewis rat astrocytes in vitro. JHM virus, LPS and AP are all capable of inducing Ia molecules on astrocytes, however, in a pattern and kinetics distinct from recombinant rat gamma interferon (gamma-IFN). Whereas gamma-IFN induced Ia expression on astrocytes and all macrophages after 48 h treatment, JHM virus, LPS and AP required 4-7 days for maximal induction of Ia on astrocytes, but had little to no effect on the macrophage population. This indicates that astrocytes are uniquely reactive to components derived from infectious agents and that these components are immunoregulatory with respect to Ia expression on astrocytes. We have also attempted to determine possible mechanisms by which these agents induce astrocyte Ia and show that phorbol myristate acetate and Ca2+ ionophore A23187 have similar effects. These findings suggest that infectious agents may directly stimulate antigen presenting functions of astrocytes in the brain through gamma-IFN-independent mechanisms.

Genetic regulation of class I major histocompatibility complex (MHC) antigen induction on astrocytes.

Neural cells, including astrocytes, normally do not express detectable levels of class I major histocompatibility complex (MHC) molecules, unlike cells of most tissues. However, upon cultivation in vitro, astrocytes begin to express class I molecules, increasing with time after plating. This spontaneous expression was examined in the present study to characterize inducible expression on astrocytes among various strains of mice. Inducible expression, either as a consequence of cultivation or standard gamma-interferon treatment, differed markedly among the strains examined. Analysis of congenic strains on a C57BL/10 (B10) background showed that expression was controlled by genes within the MHC locus. Examination of additional congeneic animals with various recombinations within the MHC showed that high or low expression of MHC molecules correlates with the presence of particular MHC class I genes. In general, H-2a and H-2d class I products are expressed much higher on astrocytes than H-2b and H-2s products. This difference in expression is not seen on spleen cells indicating tissue specificity. Moreover, levels of expression at the cell surface are reflected by the steady-state level of RNA message within astrocytes of the different strains.

Expression of major histocompatibility complex (MHC) class I genes in astrocytes correlates with the presence of nuclear factors that bind to constitutive and inducible enhancers.

The molecular basis of constitutive and inducible major histocompatibility complex (MHC) class I gene expression was studied in murine astrocytes in primary culture. Astrocytes constitutively expressed MHC class I molecules and treatment of these cells with interferon-gamma (IFN-gamma) further induced expression. The conserved region containing the upstream MHC class I regulatory element (MHC-CRE) and juxtaposed interferon consensus sequence (ICS) enhanced constitutive MHC class I promoter activity. As seen with cell surface expression of MHC molecules, treatment of astrocytes with IFN-gamma increased MHC class I promoter activity. Inducible expression required the presence of the MHC-CRE/ICS enhancer region. Nuclear factors that bind to the MHC-CRE and ICS were constitutively expressed in cultured astrocytes and IFN-gamma treatment further induced binding activity both to the MHC-CRE and ICS and correlated with induction of MHC class I gene expression. This study identifies the MHC-CRE and ICS as the major cis elements in controlling MHC class I promoter activity and suggests that the expression of nuclear factor binding activities to these enhancer elements is a basic transactivating mechanism for the expression of MHC class I genes in astrocytes.

Cell-cell junctional interactions and characteristic plasma membrane features of cultured rat glial cells.

Mixed cultures of astrocytes and oligodendrocytes derived from cerebral hemispheres of 18-19 day old rat fetuses were studied with the freeze-fracture technique. The plasma membranes of cultured astrocytes and oligodendrocytes differ substantially in their intramembrane particle profiles, and they can be positively identified consistently. Orthogonal small particle assemblies and numerous isolated globular particles characterize astrocytic plasma membranes, whereas the plasma membranes of oligodendrocytes show numerous elongated particles and fewer large and small globular particles similar to those seen in situ. Using these distinct differential features, we can identify partners of glial cell junctions. We can identify numerous interastrocytic gap junctions, as well as heterologous astrocyte-to-oligodendrocyte gap junctions. The plasma membranes of adjacent oligodendrocytes form numerous tight junctions consisting of linear P face strands and/or rows of particles interrupted by short segments of grooves, the complementary features on the E face. "Reflexive" type tight junctions seen in situ are also observed. In addition to intercellular junctions, glial cells develop special plasma membrane structural domains. Astrocytic plasma membranes often contain groups of plasmalemmal vesicles (caveolae), a distinctive feature of astrocytes in situ. Oligodendrocytes form flattened velate processes with cytoplasm restricted to finger-like channels resembling myelin lamellae in situ. Cultured astrocytes and oligodendrocytes develop the entire range of plasma membrane structural specializations seen in situ in the absence of the normal brain tissue framework. Thus, primary glial cell cultures allow experimental study of many glial cell properties, including their plasma membrane specializations.

Cell junctions and intramembrane particles of astrocytes and oligodendrocytes: a freeze-fracture study.

The plasma membranes of astrocytes and oligondendrocytes in the white matter of the cat were studied with the freeze-fracturing technique. The intramembrane particle profiles differ in the two type of cell. Orthogonal, small particle assembles and isolated globular particles 5-18 nm in diameter characterize the astrocytic plasmalemma, whereas the plasma membrane of oligodendrocytes shows large, tall globular particles, small globular particles, small ellipsoidal particles and previously undescribed, thin, short, rectilinear strands composed of fused subunits. Using these distinct differential features we can identify partners of glial cell junctions. We confirm the existence of interastrocytic gap junctions. Moreover, we identify numerous heterologous gap junctions between astrocytes and oligodendrocytic cell bodies, processes and the outer turn of myelin sheaths. Interoligodendrocytic gap junctions are not observed. Adjacent oligodendrocytes, however, form tight junctions consisting of linear P face strands and rows of particles; tight junctions are a reliable marker for oligodendroglial membranes. Connexons of interastrocytic gap junctions are packed in a crystalline array, while astrocyte-oligodendrocyte junctional connexons are closely packed but not crystalline. This study indicates that gap junctions between glial cells are pleomorphic and non-randomly distributed. The junctions between astrocytes and those between astrocytes and oligodendrocytes may had different roles in interglial and neuron-glia cooperation.

Growth pattern of various JHM coronavirus isolates in primary rat glial cell cultures correlates with differing neurotropism in vivo.

The JHM strain of murine hepatitis coronavirus is neurotropic in rats, causing either fatal acute encephalomyelitis or subacute demyelinating encephalomyelitis. We have examined the growth properties of three JHM virus isolates in primary rat glial cultures and found a correlation with their ability to cause disease. Wild type JHM virus has the propensity to cause lytic infections in glial cultures, and a temperature-sensitive mutant designated JHM-ts43 invariably produces persistent infections with reduced cytopathic effects (CPE) as compared to the wild type. Moreover, a non-neurotropic isolate, designated JHM-Pi virus, produces either non-productive persistent infections at low multiplicity of infection (m.o.i.) or productive persistent infections at high m.o.i., with, however, no CPE. The phenotypic expression of persistence is glial cell-dependent, since all three viruses produce similarly lytic infections when grown on various susceptible cell lines. The genetic basis of JHM virus persistence can be explained at the level of direct virus-glial cell interactions.

C2H2-171: a novel human cDNA representing a developmentally regulated POZ domain/zinc finger protein preferentially expressed in brain.

We describe a novel human zinc finger cNDA. C2H2-171. This cDNA represents an mRNA which encodes a protein of 484 amino acids and a calculated molecular weight of 54 kD. Four zinc finger-like domains are found in the C-terminal end of the protein. At the N-terminus, C2H2-171 contains a POZ/tramtrack-like domain similar to that found in the tumor associated zinc finger proteins LAZ-3/BCL-6 and PLZ-F, as well as in non-zinc finger proteins. C2H2-171 RNA is preferentially expressed in the brain, and increases during the course of murine development, with maximal expression in the adult. C2H2-171 RNA is differentially expressed in brain regions, with the highest level of expression in the cerebellum. C2H2-171 RNA was expressed at high levels in primary cerebellar granule cell neurons compared to astrocytes. The gene encoding C2H2-171 is highly conserved in vertebrates, and maps to the terminus of human chromosome 1 (1q44-ter). This chromosomal location is associated with a number of cytogenetic aberrations including those involving brain developmental anomalies and tumorigenesis. These data suggest that C2H2-171 may play an important role in vertebrate brain development and function.

Preliminary characterization of an Na+,K+,Cl- co-transport activity in cultured human astrocytes.

We have studied the potassium uptake using 86Rb+ into monolayers of secondary cultures of human astrocytes prepared from cerebral hemispheres of a 4-month-old fetus. With the use of inhibitors we could attribute 30-40% of the 86Rb+ uptake to an Na+,K+-ATPase, 50-60% to an anion-cation co-transporter and 10% to potassium leak channels. The anion-cation co-transporter was dependent on the simultaneous presence of both sodium and chloride in the incubation medium and is therefore most likely an Na+,K+,Cl- co-transporter. This is the first evidence of such an Na+,K+,Cl- co-transport in human astrocytes.

Plasmalemmal vesicles (caveolae) of fibrous astrocytes of the cat optic nerve.

Plasmalemmal vesicles (caveolae) are described in fibrous astrocytes of the cat optic nerve. In thin sections, astrocytic caveolae appear as flask-shaped invaginations of the plasma membrane with a 60-nm lumen that communicates with the extracellular space through a 35-nm stoma. Occasional bilobed caveolae occur. The caveolae extend approximately 85 nm into the astrocytic cytoplasm and are often embedded within a granular or filamentous ectoplasmic substance connected by 4-8-nm filament bridges to underlying bundles of 10-nm glial filaments. In freeze-fracture replicas, the caveolar stomata appear as dimples on the P face and as craters on the E face, often arranged in hexagonal or linear arrays and spaced at a center-to-center distance of 110-130 nm. The caveolar membrane is apparently particle-free. Fibrous astrocytes related to the connective-tissue septa of the optic nerve show different densities of caveolae on different areas of their plasma membranes. Plasma membranes apposing a basal lamina have few caveolae, whereas membranes not apposed to the basal lamina but to other astrocytic membranes have up to 17 caveolae/micrometers 2. Caveolae also occur on astrocytic plasma membranes apposed to myelin sheaths. Possible functions of the astrocytic caveolae are discussed in the light of plasmalemmal properties of other types of caveolae-bearing cells.

Modulation of major histocompatibility complex class I genes by interferon-gamma and ganglioside GT 1b in astrocytes: involvement of protein tyrosine phosphatases.

We have previously reported that the polysialoganglioside GT1b suppresses the induction of major histocompatibility complex class I molecules by interferon-gamma in astrocytes. Suppression by GT1b depended on the presence of sialic acid moieties because asialo-GM1 was not suppressive. In the present report, GT1b was found to act transcriptionally to suppress class I genes because both the interferon-gamma induction of RNA and the activity of class I promoter constructs were inhibited. Furthermore, GT1b suppressed promoter activity through interferon regulatory factor elements, indicating an effect on the transcription activation factor, interferon regulatory factor 1. Interferon-gamma induced interferon regulatory factor 1 within 8 h, and GT1b suppressed this induction. The suppression of interferon regulatory factor 1 by GT1b correlated with the suppression of gamma-activated factor binding at the promoter of the interferon regulatory factor 1 gene. The suppression of gamma-activated factor by GT1b appeared to involve increased protein tyrosine phosphatase activity because treatment of the cells with pervanadate reversed the effect of GT1b on the gamma-activated factor and, correspondingly, phosphotyrosine content. In sum, GT1b displays specific effects on interferon-gamma signaling and negative feedback regulatory molecules in astrocytes.

The role of protein tyrosine phosphatase SHP-1 in the regulation of IFN-gamma signaling in neural cells.

The role for protein tyrosine phosphatase SHP-1 in controlling signal transduction by IFN-gamma in astrocytes was studied. IFN-gamma induced the gamma-activated factor (GAF) within 30 min and GAF subsequently declined by 8 h after treatment. However, treatment with IFN-gamma in the presence of protein tyrosine phosphatase inhibitor vanadate blocked the decrease in GAF activity. The increased stability of GAF in vanadate-treated cultures was similarly observed in astrocytes of motheaten mice, which specifically lack the protein tyrosine phosphatase SHP-1. Prolongation of GAF activity coincided with increased expression of the IFN-inducible transcription factor, IFN-regulatory factor-1 (IRF-1). Increased IRF-1 was coincident with increased expression of MHC class I molecules in astrocytes in accordance with the activity of IRF-1 in the promoter region. These data implicate an important role for protein tyrosine phosphatases, including SHP-1, in the regulation of IFN-gamma-signaling and IFN-gamma-inducible genes in neural cells.