Viral neuroinvasion and encephalitis induced by lipopolysaccharide and its mediators

Expansion by Self Antigen Is Necessary for the Induction of Experimental Autoimmune Encephalomyelitis by T Cells Primed with a Cross-Reactive Environmental Antigen

Cross-reactivity with environmental antigens has been postulated as a mechanism responsible for the induction of autoimmune disease. Experimental autoimmune encephalomyelitis is a T cell-mediated autoimmune disease model inducible in susceptible strains of laboratory animals by immunization with protein constituents of myelin. We used myelin proteolipid protein (PLP) peptide 139–151 and its analogues to define motifs to search a protein database for structural homologues of PLP139–151 and identified five peptides derived from microbial Ags that elicit immune responses that cross-react with this self peptide. Exposure of naive SJL mice to the cross-reactive environmental peptides alone was insufficient to induce autoimmune disease even when animals were treated with Ag-nonspecific stimuli (superantigen or LPS). However, immunization of SJL mice with suboptimal doses of PLP139–151 after priming with cross-reactive environmental peptides consistently induced experimental autoimmune encephalomyelitis. Furthermore, T cell lines from mice immunized with cross-reactive environmental peptides and restimulated in vitro with PLP139–151 could induce disease upon transfer into naive recipients. These data suggest that expansion by self Ag is required to break the threshold to autoimmune disease in animals primed with cross-reactive peptides.

No increase in blood-brain barrier permeability after intraperitoneal injection of endotoxin in the rat

Reactions mediated by the brain are part of the response to intraperitoneal administration of endotoxin, a model of gram-negative bacterial infection. To test the hypothesis that a compromised blood-brain barrier (BBB) may contribute to these reactions, the integrity of the BBB was measured following lipopolysaccharide administration. Rats received intraperitoneal injections of 50 microg/kg or 2 mg/kg of endotoxin. Brain uptake of a macromolecular vascular marker, 3H-labelled rat serum albumin, and of a poorly permeable low molecular weight substance, [14C]sucrose, was then measured with the intravenous bolus injection method. Compared to controls, neither dose of endotoxin affected the BBB permeability for these tracers. This was true when brain uptake was measured 5 min or 2 h after lipopolysaccharide injection. It is concluded that intraperitoneal endotoxin even at a high dose does not acutely disrupt the BBB.

Induction of cytokine transcripts in the central nervous system and pituitary following peripheral administration of endotoxin to mice

The regional distribution and inducibility of cytokines in the normal brain is still a matter of controversy. As an attempt to clarify this issue, we studied the constitutive and induced expression of interleukin (IL)-1beta, IL-6, tumor necrosis factor (TNF)-alpha, and interferon (IFN)-gamma mRNAs in the brain, pituitary, and spleen of mice using qualitative and semiquantitative reverse-transcription polymerase chain reaction. The contribution of nonbrain cells to the cytokine transcripts detected was considered. With the exception of IFN-gamma mRNA, transcripts for the other cytokines were found to be constitutively present in the brain. Following i.p. injection of lipopolysaccharide (LPS) at a dose below those described to disrupt the blood-brain barrier (BBB), cytokine mRNA expression was increased in the spleen, the pituitary, and the brain. In the brain, the onset of transcription varied from 45 min (IL-1beta, TNF-alpha) to 4 hr (IFN-gamma), and the peak of mRNA accumulation was observed at different times depending on the cytokine and the brain region studied. IL-1 and IL-6 were highly expressed in the hypothalamus and hippocampus, while TNF-alpha expression was more marked in the thalamus-striatum. The cortex was the region in which cytokines were less inducible. The inducible expression of cytokine mRNAs in the brain was paralleled by stimulation of the hypothalamus-pituitary-adrenal axis. These results show the capacity of brain cells to synthesize different cytokine mRNAs in vivo and define the kinetics of their expression in several brain areas and in the periphery in parallel to the activation of a neuroendocrine pathway by endotoxin.

Genetic determinants of Sindbis virus neuroinvasiveness

After peripheral inoculation of mice, Sindbis virus replicates in a variety of tissues, leading to viremia. In some cases, the virus can enter the central nervous system (CNS) and cause lethal encephalitis. The outcome of infection is age and virus strain dependent. Recently, two pairs of Sindbis virus variants differing in neurovirulence and neuroinvasiveness were derived by limited serial passaging in mouse brain. Two early passage isolates (SVA and SVB) were neurotropic but did not cause lethal encephalitis. SVB, but not SVA, was neuroinvasive. A second independent pair of isolates (SVN and SVNI), which had undergone more extensive mouse brain passaging, were highly neurotropic and caused lethal encephalitis. Only SVNI could reach the brain after peripheral inoculation. From these isolates, virion RNAs were obtained and used to construct full-length cDNA clones from which infectious RNA transcripts could be recovered. The strains recovered from these clones were shown to retain the appropriate phenotypes in weanling mice. Construction and analysis of recombinant viruses were used to define the genetic loci determining neuroinvasion. For SVB, neuroinvasiveness was determined by a single residue in the E2 glycoprotein (Gln-55). For SVNI, neuroinvasive loci were identified in both the 5' noncoding region (position 8) and the E2 glycoprotein (Met-190). Either of these changes on the SVN background was sufficient to confer a neuroinvasive phenotype, although these recombinants were less virulent. To completely mimic the SVNI phenotype, three SVNI-specific substitutions on the SVN background were required: G at position 8, E2 Met-190, and Lys-260, which by itself had no effect on neuroinvasion. These genetically defined strains should be useful for dissecting the molecular mechanisms leading to Sindbis virus invasion of the CNS.

Cold stress-induced neuroinvasiveness of attenuated arboviruses is not solely mediated by corticosterone

In previous studies we have shown that various stress paradigms can induce the penetration of noninvasive, attenuated viruses into the central nervous system (CNS). Since glucocorticoids levels are elevated during stress, we compared the effect of cold stress and corticosterone (CS) injection on neuroinvasiveness of a non-invasive encephalitic virus, WN-25 (West Nile). Exposure of inoculated mice to cold stress or CS resulted in high viremia and a marked increase in mortality when compared to control untreated mice. Exposure of WN-25 inoculated mice to cold treatment or CS injection led to high blood virus levels as compared to nontreated mice (3.2 and 3.1 vs > 1 log 10 PFU/ml). Cold stress or CS (5000 ng/mouse) treatment caused a mortality rate of 70% and 50% of the WN-25 inoculated mice respectively. No mortality was recorded in control inoculated groups (p < 0.05). Passive transfer serum from uninfected cold stressed mice to WN-25 inoculated nonstressed mice, resulted in similar mortality. The levels of CS in passive transferred serum from cold stressed animals was 500 ng/ml, only 2% (100 vs. 5000 ng) of the CS dose required to obtain a similar effect on viral penetration and mortality when CS was injected directly. Therefore, we concluded that CS was not the sole factor responsible for the cold stress effect on the viral infection outcome.

Production and role of cytokines in the CNS of mice with acute viral encephalomyelitis

Semliki Forest Virus (SFV) causes a more severe acute encephalomyelitis in B6 than in SJL mice despite similar T cell proliferation and antibody responses in these two strains. To determine the immunological mechanisms that may contribute to this difference, CNS tissues from SFV-infected B6 and SJL mice were analyzed for viral replication, inflammatory responses and cytokine production, by semiquantitative reverse transcriptase-PCR and immunohistochemistry. Although initially similar on day 2 p.i., SFV replicated to higher viral titers in B6 than SJL mice on days 4 and 7 p.i. Infectious virus was cleared from both strains by day 10 p.i. There were no differences in numbers of CD4+, CD8+ or MHC class I and II+ inflammatory cells at any time point. Higher levels of IL-4 mRNA, lower levels of TNF-alpha, IL-6, IL-1 beta and IL-2 mRNAs and lower IL-2+ and IFN-gamma+ cells were found in B6. These findings suggest that despite comparable immune responses, different patterns of cytokine production correlated with higher levels of virus in the brains and more severe clinical disease in B6, and more efficient clearance of virus and less severe disease in SJL mice.

A co-evolutionary theory of sleep

Based on recent experimental evidence, a novel theory of sleep function and regulation is advanced, stating that sleep primarily evolved to protect the brain against a wakefulness-dependent increase in the permeability of the blood-brain barrier. A restitutional mechanism for the blood-brain barrier had to co-evolve against the omnipresent gut-derived bacterial cell wall constituents, because these and their elicited cellular responses increase blood-brain barrier permeability and potentially harm nervous tissue. Thus, in order to develop a highly organized cerebral structure, an immune-like response specific for the brain co-evolved during the phylogeny of the symbiosis between animals and gut bacteria to control the detrimental effects of bacterial cell wall constituents. In the course of further evolution, the sleep-associated 'controlled inflammatory state' of the brain employed the growth-factor activities of locally activated cytokines to enforce cerebral development and the maintenance of cognitive functions.

Apoptosis and HIV neuropathogenesis

A consequence of HIV infection may be neurological dysfunction secondary to the presence of virus in the central nervous system (CNS). The CNS tropism of HIV and the mechanisms that govern its dissemination are not well defined. One view is that HIV enters the brain through the diapedesis of infected monocytes from blood into the perivascular space. HIV may then spread to susceptible cells throughout parenchyma. An alternate hypothesis is presented, which suggests that T lymphocyte apoptosis may also participate in HIV entry and dissemination in the brain. This is based on the following observations: 1) T lymphocyte apoptosis may be a CNS-specific mechanisms to control inflammation, 2) the most common circulating reservoir of HIV is the T lymphocyte, 3) uninfected macrophages recruited to phagocytize HIV infected apoptotic T lymphocytes in vitro can become productively infected, and 4) the predominant form of HIV in the CNS is unintegrated. Aberrantly high levels of apoptosis in HIV infected lymphocytes within the CNS and subsequent recruitment and infection of macrophages and microglia may be a novel component of HIV neuropathogenesis.

Loss of active neuroinvasiveness in attenuated strains of West Nile virus: pathogenicity in immunocompetent and SCID mice

The neuropathogenicity of West Nile virus (WNV) and two derived attenuated strains WN25 and WN25A, was studied in young adult ICR mice and in severe combined immunodeficient (SCID) mice. Similarity in serology and RNA fingerprints were found between WNV and WN25. The viral envelope proteins of the attenuates differed from WNV in their slower mobility in SDS-PAGE due probably to the presence of N-linked glycan. The three strains were lethal to ICR mice by intracerebral (IC) inoculation, but when inoculated intraperitoneally (IP), WNV caused viremia, invaded the CNS and was lethal, whereas the attenuates showed no viremia or invasion of the CNS. The attenuates elicited antibodies to comparable levels as WNV in IP-infected mice, conferring upon them immunity to IC challenge with the wild type. In IP-inoculated SCID mice the three strains exhibited similar high viremiae that lasted until death of the animals. All strains invaded the CNS and proliferated in the mouse brain to similar high titers, but differed largely in the time of invasion: WNV invaded the CNS of SCID mice (and two other mouse strains) much earlier than the attenuates, which showed large intervals in their time of invasion into individual mouse brains within the group. The data presented for SCID mice indicate that WN25 and WN25A have truly lost the neuroinvasive property, and that this property materialized by a prescribed, active process specific for WNV.

T cell immunity to myelin basic protein induces anterior uveitis in Lewis rats

Uveitis of unknown etiology is known to occur in association with various systemic disorders. We now report that anterior uveitis (AU) can be produced by T cell immunity to myelin basic protein (BP) and accompanies experimental autoimmune encephalomyelitis (EAE). EAE with AU was induced in Lewis rats by immunization to BP in CFA or by immunization to various BP peptides including the encephalitogenic 71-90 peptide. Slit-lamp biomicroscopy of BP-immunized Lewis rats revealed AU, characterised by inflammation of the iris, in 73% of the eyes. The onset of AU in actively immunized rats varied between days 12 and 26, often appearing after spontaneous remission of the paralysis, the hallmark of EAE. The course of AU was progressive, affecting more than 50% of the surface of the iris in 16 of 29 diseased eyes. Like the paralysis, the AU was self-limiting: within 2 weeks the disease remitted. In addition, AU could be adoptively transferred to naive and irradiated rats by a T cell clone specific for BP peptide 71-90. The present observations are compatible with the idea that AU may be triggered by BP-reactive T cells. The myelinated nerves present in the iris have been shown to contain BP. However, these peripheral nerves would now appear to be the only peripheral nerves susceptible to acute EAE.

Monoclonal IgM antibodies to GM1 and asialo-GM1 in chronic neuropathies cross-react with Campylobacter jejuni lipopolysaccharides

We tested monoclonal IgM anti-GM1 and asialo-GM1 antibodies from 6 patients with chronic motor neuropathies for binding to lipopolysaccharides (LPS) from three stains of Campylobacter jejuni. Four of the 6 patients showed strong reactivity with LPS from at least one of the three C. jejuni strains tested as shown by enzyme-linked immunosorbent assay or western blot. Preabsorption with GM1 or asialo-GM1, or blocking with cholera toxin, prevented antibody binding to LPS. These studies indicate that human anti-GM1 or anti-asialo-GM1 antibodies cross-react with LPS from certain strains of C. jejuni, and that bacterial LPS might provide antigenic stimuli for the activation of B cells expressing anti-GM1 antibodies.