Pathogenesis of viral infections. Basic concepts derived from the reovirus model

The μ2 and λ1 Proteins of Mammalian Reovirus Modulate Early Events Leading to Induction of the Interferon Signaling Network

It has been previously shown that amino acid polymorphisms in reovirus proteins μ2 and λ1 are associated with differing levels of interferon induction. In the present study, viruses carrying these polymorphisms in either or both proteins, were further studied. The two viral determinants exert a synergistic effect on the control of β-interferon induction at the protein and mRNA level, with a concomitant increase in RIG-I. In contrast, levels of phospho-Stat1 and interferon-stimulated genes are increased in singly substituted viruses but with no further increase when both substitutions were present. This suggests that the viral determinants are acting during initial events of viral recognition. Accordingly, difference between viruses was reduced when infection was performed with partially uncoated virions (ISVPs) and transfection of RNA recovered from early-infected cells recapitulates the differences between viruses harboring the different polymorphisms. Altogether, the data are consistent with a redundant or complementary role of μ2 and λ1, affecting either early disassembly or the nature of the viral RNA in the incoming viral particle. Proteins involved in viral RNA synthesis are thus involved in this likely critical aspect of the ability of different reovirus variants to infect various cell types, and to discriminate between parental and transformed/cancer cells.

Central Nervous System Infections

Central nervous system (CNS) infections—i.e., infections involving the brain (cerebrum and cerebellum), spinal cord, optic nerves, and their covering membranes—are medical emergencies that are associated with substantial morbidity, mortality, or long-term sequelae that may have catastrophic implications for the quality of life of affected individuals. Acute CNS infections that warrant neurointensive care (ICU) admission fall broadly into three categories—meningitis, encephalitis, and abscesses—and generally result from blood-borne spread of the respective microorganisms. Other causes of CNS infections include head trauma resulting in fractures at the base of the skull or the cribriform plate that can lead to an opening between the CNS and the sinuses, mastoid, the middle ear, or the nasopharynx. Extrinsic contamination of the CNS can occur intraoperatively during neurosurgical procedures. Also, implanted medical devices or adjunct hardware (e.g., shunts, ventriculostomies, or external drainage tubes) and congenital malformations (e.g., spina bifida or sinus tracts) can become colonized and serve as sources or foci of infection. Viruses, such as rabies, herpes simplex virus, or polioviruses, can spread to the CNS via intraneural pathways resulting in encephalitis. If infection occurs at sites (e.g., middle ear or mastoid) contiguous with the CNS, infection may spread directly into the CNS causing brain abscesses; alternatively, the organism may reach the CNS indirectly via venous drainage or the sheaths of cranial and spinal nerves. Abscesses also may become localized in the subdural or epidural spaces. Meningitis results if bacteria spread directly from an abscess to the subarachnoid space. CNS abscesses may be a result of pyogenic meningitis or from septic emboli associated with endocarditis, lung abscess, or other serious purulent infections. Breaches of the blood–brain barrier (BBB) can result in CNS infections. Causes of such breaches include damage (e.g., microhemorrhage or necrosis of surrounding tissue) to the BBB; mechanical obstruction of microvessels by parasitized red blood cells, leukocytes, or platelets; overproduction of cytokines that degrade tight junction proteins; or microbe-specific interactions with the BBB that facilitate transcellular passage of the microorganism. The microorganisms that cause CNS infections include a wide range of bacteria, mycobacteria, yeasts, fungi, viruses, spirochaetes (e.g., neurosyphilis), and parasites (e.g., cerebral malaria and strongyloidiasis). The clinical picture of the various infections can be nonspecific or characterized by distinct, recognizable clinical syndromes. At some juncture, individuals with severe acute CNS infections require critical care management that warrants neuro-ICU admission. The implications for CNS infections are serious and complex and include the increased human and material resources necessary to manage very sick patients, the difficulties in triaging patients with vague or mild symptoms, and ascertaining the precise cause and degree of CNS involvement at the time of admission to the neuro-ICU. This chapter addresses a wide range of severe CNS infections that are better managed in the neuro-ICU. Topics covered include the medical epidemiology of the respective CNS infection; discussions of the relevant neuroanatomy and blood supply (essential for understanding the pathogenesis of CNS infections) and pathophysiology; symptoms and signs; diagnostic procedures, including essential neuroimaging studies; therapeutic options, including empirical therapy where indicated; and the perennial issue of the utility and effectiveness of steroid therapy for certain CNS infections. Finally, therapeutic options and alternatives are discussed, including the choices of antimicrobial agents best able to cross the BBB, supportive therapy, and prognosis.

Differential expression of the immediate-early 2 and 3 proteins in developing mouse brains infected with murine cytomegalovirus

Murine cytomegalovirus (MCMV) immediate-early (IE) 2 protein has been reported to be dispensable for growth and latency in mice. Therefore, its role in viral pathogenesis and tissue tropism is not known. Here we prepared specific antibodies to the IE2 and IE3 proteins by using fusion proteins expressed in Escherichia coli as antigens. Immunostaining of MCMV-infected cultured fibroblasts revealed IE2 protein to be expressed diffusely in the nucleoplasm similar to the IE1 protein. In contrast, expression of the IE3 protein, 88 kDa, exhibited a punctate pattern in the nucleus in the early phase of infection then diminished. In the brain of neonatal mice infected with MCMV, both IE2 and IE3 proteins were detected immunohistochemically in the cells of the ventricular walls early in infection. When the infection was prolonged, the IE2 protein was expressed in neurons of the cortex and hippocampus, while the IE3 protein was preferentially expressed in glial cells in the early phase of infection, and its levels declined during the infection. These results suggest that the IE2 protein may play a role in persistent infection in neurons, whereas the IE3 protein, expressed preferentially in glial cells, may play the main role in acute infection.

Features of reovirus outer capsid protein mu1 revealed by electron cryomicroscopy and image reconstruction of the virion at 7.0 Angstrom resolution

Reovirus is a useful model for addressing the molecular basis of membrane penetration by one of the larger nonenveloped animal viruses. We now report the structure of the reovirus virion at approximately 7.0 A resolution as obtained by electron cryomicroscopy and three-dimensional image reconstruction. Several features of the myristoylated outer capsid protein mu1, not seen in a previous X-ray crystal structure of the mu1-sigma3 heterohexamer, are evident in the virion. These features appear to be important for stabilizing the outer capsid, regulating the conformational changes in mu1 that accompany perforation of target membranes, and contributing directly to membrane penetration during cell entry.

Experimental intestinal reovirus infection of mice: what we know, what we need to know

Reovirus, a member of the Reoviridae family, is a ubiquitous virus in vertebrate hosts. Although disease caused by reovirus infection is for the most part mild, studies of reovirus have particularly been valuable as a model for understanding the local host response to replicating foreign antigen in intestinal and respiratory sites. In this article, a brief overview is presented of the basic features of reovirus infection, as will the host's humoral and cellular immune response during the infectious cycle. New information regarding the interactions and involvement of immune response molecules during reovirus infection will be presented based on multiple analyte array studies from our laboratory.

Neuropathogenesis in cytomegalovirus infection: indication of the mechanisms using mouse models

Cytomegalovirus (CMV) is the most frequent infectious cause of developmental brain disorders and also causes brain damage in immunocompromised individuals. Although the brain is one of the main targets of CMV infection, little is known about the neuropathogenesis of the brain disorders caused by CMV in humans because of the limitations in studying human subjects. Murine CMV (MCMV) is similar to human CMV (HCMV) in terms of genome structure, pattern of gene expressions, cell tropism and infectious dynamics. In mouse models, it has been shown that neural stem/progenitor cells are the most susceptible to CMV infection in developing brains. During brain development, lytic infection tends to occur in immature glial cells, presumably causing structural disorders of the brain. In the prolonged phase of infection, CMV preferentially infects neuronal cells. Infection of neurons may tend to become persistent by evasion of immune reactions, anti-apoptotic effects and neuron-specific activation of the e1-promoter, presumably causing functional neuronal disorders. It has also been shown that CMV infection in developing brains may become latent in neural immature cells. Brain disorders may occur long after infection by reactivation of the latent infection.

Transepithelial transport and mucosal defence I: the role of M cells

How do cells of the immune system encounter the majority of antigens that enter the body through the gut and airways? The epithelia lining these systems contain a remarkable cell type, the M cell, that delivers antigens across the epithelium to lymphocytes and macrophages. In this article, Marian Neutra and Jean-Pierre Kraehenbuhl describe the structure of the M cell, its function in promoting the immune response and its exploitation by invading pathogens. In the next issue of Trends in Cell Biology, these authors will review the other immunological function of epithelia, secretion of polymeric IgA.

Neurovirological methods and their applications

Over the last 30 years neurovirology has emerged as a major discipline which has much relevance to both human disease and many aspects of neuroscience. This overview of the field aims to define briefly most of the major neurovirological techniques, both "classical" and more recent, and to indicate how these have been used to gain knowledge about the pathogenesis, clinical investigation, and treatment of viral infections of the central nervous system.

Identification and characterization of a baboon reovirus-specific nonstructural protein encoded by the bicistronic s4 genome segment

All characterized orthoreoviruses encode a characteristic spike-like protein on their polycistronic S1 genome segments that mediates virus cell attachment. In the case of baboon reovirus (BRV), the polycistronic S-class genome segment corresponds to the smallest S4 segment. We recently determined that the 5'-proximal open reading frame (ORF) of the bicistronic S4 segment encodes a nonstructural protein responsible for virus-induced syncytium formation. Current analysis indicates that the p16 protein encoded by the 3'-proximal ORF of the BRV S4 genome segment shows no sequence similarity to any other protein encoded by the orthoreoviruses, including the well-characterized sigma1/sigmaC reovirus cell attachment protein. Results indicate that p16 is a BRV-specific nonstructural protein that is not required for virus infection in cell culture and is not involved in viral cell attachment. In conjunction with previous studies of the BRV S1, S2, and S3 genome segments, the current results indicate that, unlike all other orthoreoviruses, BRV does not encode a cell attachment protein in its S-class genome segments. Furthermore, cell binding and infectivity studies suggested BRV may not utilize a functional homolog of the prototypical reovirus sigma1/sigmaC cell receptor-binding protein to mediate endocytic uptake by cells.

Innate immune responses to cytomegalovirus infection in the developing mouse brain and their evasion by virus-infected neurons

Cytomegalovirus (CMV) is the most frequent infectious cause of developmental brain disorders in humans. Here we show the role of innate immune responses caused by natural killer (NK) cells and nitric oxide (NO) derived from brain macrophages during murine CMV (MCMV) infection of the developing brain. Viral replication in the brain of newborn mice was significantly enhanced by administration of anti-asialo-GM1 antibody, specific for NK cells, or L-N6-(1-imminoethyl)-lysine, a specific inhibitor of NO synthase 2 (NOS2). These results suggest that NK cells and NO contribute to the viral clearance from the brain. At 3 days postinfection (dpi) MCMV early antigen (Ag)-positive cells were immunohistochemically detected in the periventricular area, where most of the positive cells were macrophages. At 7 dpi MCMV-Ag was found not only in cells of the periventricular area but also in neurons of the hippocampus and cortex. At 11 dpi MCMV-Ag disappeared from the periventricular area, but persisted in neurons. In the periventricular area, NK cells and NOS2-positive macrophages were associated with MCMV-Ag-positive cells. In contrast, there were very few NK cells and NOS2-positive macrophages around the MCMV-Ag-positive neurons. In situ hybridization for MCMV DNA demonstrated that positive signals were found mostly in the periventricular cells, and rarely in neurons. These results suggest that the innate immune responses are restricted to the virus-replicating cells, and do not affect MCMV-infected neurons. Therefore, evasion of the innate immune responses by MCMV-infected neurons may be an important factor in supporting the viral persistence in the developing brain.

Multitarget ribozyme against the S1 genome segment of reovirus possesses novel cleavage activities and is more efficacious than its constituent mono-ribozymes

Two hammerhead motif containing ribozymes (Rzs) were constructed through recombinant techniques that were directed to cleave at the conserved sites of the reovirus S1 gene segment which encodes the cell attachment protein sigma1. The two mono-ribozymes 553 and 984 cleaved the target RNA in a sequence specific manner, and Rz-553 being the more efficient. When the mono-Rzs were combined in direct tandem to make it a multitarget-Rz, very efficient cleavage of the S1 RNA was achieved that retained the specificity of the two mono-ribozymes. This cleavage was, as expected, Mg(++)-dependent but protein-independent. Almost complete cleavage of the S1 RNA was observed with multitarget ribozyme alone. Although S1-Rz-984 cleaved the short S1 synthetic RNA, it failed to cleave the full length S1 RNA (1.4 kb). On the contrary, Rz-553 cleaved the short synthetic RNA as well as the full length S1 RNA with equal efficiency. Full length S1 RNA was, however, cleaved efficiently by the multitarget-ribozyme-S1-Rz-984-553 that cleaved at both the target sites. Thus, hybridization of one ribozyme (Rz-553) to a full length S1 RNA potentially opened up the 984-Rz target site that was otherwise inaccessible to the mono-Rz-984. Multitarget ribozyme expressing mammalian cells showed reduced amounts of S1 RNA that correlated well with the levels of reovirus sigma1 protein. Potential uses of such multitarget-Rzs are discussed.

Natural pathogens of laboratory mice, rats, and rabbits and their effects on research

Laboratory mice, rats, and rabbits may harbor a variety of viral, bacterial, parasitic, and fungal agents. Frequently, these organisms cause no overt signs of disease. However, many of the natural pathogens of these laboratory animals may alter host physiology, rendering the host unsuitable for many experimental uses. While the number and prevalence of these pathogens have declined considerably, many still turn up in laboratory animals and represent unwanted variables in research. Investigators using mice, rats, and rabbits in biomedical experimentation should be aware of the profound effects that many of these agents can have on research.

Serotype-dependent induction of pulmonary neutrophilia and inflammatory cytokine gene expression by reovirus

Reovirus type 3 Dearing (T3D) causes a prominent neutrophil influx, substantially greater than seen with reovirus type 1 Lang (T1L) in a rat model of viral pneumonia. We sought to measure reovirus-mediated increases in chemokine mRNA expression in pulmonary cells. We found that the neutrophilia induced by T1L and T3D infection in vivo correlated directly with increased levels of chemokine mRNA expression in T3D-infected compared with those of T1IL-infected lungs. In vitro, reovirus-infected normal alveolar macrophages (AMs) and the rat AM cell line NR8383 expressed greater levels of macrophage inflammatory protein 2, KC, and tumor necrosis factor alpha mRNA. A synergism between reovirus and lipopolysaccharide was also detected for macrophage inflammatory protein 2 and KC mRNA expression. Tumor necrosis factor protein secretion was also increased to a greater extent by T3D than by T1L in primary rat AMs and the NR8383 cells. We conclude that the virus-mediated inflammatory cytokine induction suggests a role for these cytokines in the neutrophil influx observed in the rat reovirus pneumonia model.

Receptor proteins on newborn Balb/c mouse brain cells for coxsackievirus B3 are immunologically distinct from those on HeLa cells

Newborn Balb/c mice are highly susceptible to infection by the six coxsackievirus serotypes of group B (CVB) and it is known that receptor for these viruses are in highest concentration in the brain as compared to other tissues. Therefore, proteins from the brain tissues of these animals were solubilized (Brain-Ext) and characterized for the identification of mouse brain receptor (MBR) proteins. Virus-blot analyses of Brain-Ext suggested that each of three virus variants of CVB3-(N, W and RD) recognized four receptor proteins designated p46, p44, p36 and p33 according to their molecular size. Similar analyses of cultured neurons from newborn Balb/c mice revealed the presence of the same four receptor proteins, while astrocytes appeared to possess only p46 and/or p44. Isoelectric focusing of Brain-Ext, focused MBR proteins in the pH range 4.0-8.5, with a peak around pH 5.7. P46 was found to be neuraminidase sensitive. A polyclonal rat antiserum (anti-MBR) protected cultured neurons and astrocytes against infection by CVB3, inhibited virus binding to these cells and recognized the same four receptor proteins on western-blots as detected on virus-blots by CVB3. However, a rabbit polyclonal anti-HeLa cell antiserum, which strongly binds to HeLa cells and protects them from CVB3 infection, neither recognized any of the receptor proteins in western-blot analyses of Brain-Ext nor inhibited CVB3 infection on cultured neurons and astrocytes. Conversely, anti-MBR did not recognize any of the receptor proteins by western-blot analysis of HeLa cell extracts nor did it inhibit CVB3 infection of HeLa cells.(ABSTRACT TRUNCATED AT 250 WORDS)

A pathway for entry of reoviruses into the host through M cells of the respiratory tract

Many microorganisms gain access to the systemic circulation after entering the respiratory tract. The precise pathways used to cross the mucosal barriers of the lungs have not been clearly described. We have used the mammalian reoviruses in order to determine the pathway that a systemic virus uses to penetrate the mucosal barrier and enter the systemic circulation after entering the airways of the lungs. Reoviruses enter through pulmonary M cells, which overlie bronchus-associated lymphoid tissue, and subsequently spread to regional lymph nodes. Thus, the pathway through M cells represents a strategy by which viruses and probably other microorganisms can penetrate the mucosal surface of the respiratory tract and thereby enter the systemic circulation.

Reovirus protein sigma 1: from cell attachment to protein oligomerization and folding mechanisms

The reovirus cell attachment protein sigma 1 is a lollipop-shaped structure with the fibrous tail anchored to the virion. Since it interacts with the cell receptor, sigma 1 is a major determinant of reovirus infectivity and tissue tropism. Studies on its structure-function relationships have been facilitated by the fact that protein sigma 1 produced in any expression system is capable of binding to cell receptors. The use of site-specific and deletion mutants has led to the identification and characterization of its virion anchorage and receptor binding domains. Studies on the oligomeric status of sigma 1 have revealed that sigma 1 is a homotrimer and that two independent trimerization events at different loci (the N- and C-terminal halves, respectively) of the protein, are involved in its generation. This also accounts for a clearly demonstrable dominant negative effect by a mutant subunit in a wild-type/mutant sigma 1 heterotrimer. Current efforts are focused on the involvement of chaperones in the generation of sigma 1 and on events that take place upon sigma 1 binding to the cell receptor. Protein sigma 1 has therefore become an excellent model system for the study of both virus attachment and protein oligomerization and folding mechanisms.

Association of bluetongue virus gene segment 5 with neuroinvasiveness

Two strains (UC-2 and UC-8) of bluetongue virus were used to determine genetic factors influencing neuroinvasiveness. Reassortants were produced in vitro, and the parental origins of their genes were determined by polyacrylamide gel electrophoresis profiles and restriction endonuclease digestion. Gene segment 5 of UC-8 correlated with neuroinvasiveness of reassortants when inoculated subcutaneously into newborn mice.

Virus infection of polarized epithelial cells

This chapter focuses on the interaction of viruses with epithelial cells. The role of specific pathways of virus entry and release in the pathogenesis of viral infection is examined together with the mechanisms utilized by viruses to circumvent the epithelial barrier. Polarized epithelial cells in culture, which can be grown on permeable supports, provide excellent systems for investigating the events in virus entry and release at the cellular level, and much information is being obtained using such systems. Much remains to be learned about the precise routes by which many viruses traverse the epithelial barrier to initiate their natural infection processes, although important information has been obtained in some systems. Another area of great interest for future investigation is the process of virus entry and release from other polarized cell types, including neuronal cells.

Bidirectional entry of poliovirus into polarized epithelial cells

The interactions of viruses with polarized epithelial cells are of some significance to the pathogenesis of disease because these cell types comprise the primary barrier to many virus infections and also serve as the sites for virus release from the host. Poliovirus-epithelial cell interactions are of particular interest since this virus is an important enteric pathogen and the host cell receptor has been identified. In this study, poliovirus was observed to adsorb to both the apical and basolateral surfaces of polarized monkey kidney (Vero C1008) and human intestinal (Caco-2) epithelial cells but exhibited preferential binding to the basolateral surfaces of both cell types. Localization of the poliovirus receptor by a receptor-specific monoclonal antibody (D171) revealed a similar distribution predominantly on basolateral membranes, and treatment of cells with antibody D171 inhibited virus adsorption to both membrane surfaces. Poliovirus was able to initiate infection with similar efficiency following adsorption to either surface, and infection was blocked at both surfaces by D171, indicating that functional receptor molecules are expressed on both surfaces at sufficient density to mediate efficient infection at the apical and basolateral plasma membranes. Poliovirus infection resulted in a decrease in transepithelial resistance which was inhibited by prior treatment with monoclonal antibody D171 and occurred prior to other visible cytopathic effects. These results have interesting implications for viral pathogenesis in the human gut.

The reovirus cell attachment protein possesses two independently active trimerization domains: basis of dominant negative effects

The reovirus cell attachment protein, sigma 1, is a homotrimer with an N-terminal fibrous tail and a C-terminal globular head. By cotranslating full-length and various truncated sigma 1 proteins in vitro, we show that the N- and C-terminal halves of sigma 1 possess independent trimerization and folding domains. Trimerization of sigma 1 is initiated at the N-terminus by the formation of a "loose," protease-sensitive, three-stranded, alpha-helical coiled coil. This serves to bring the three unfolded C-termini into close proximity to one another, facilitating their subsequent trimerization and cooperative folding. Concomitant with, but independent of, this latter process, the N-terminal fiber further matures into a more stable and protease-resistant structure. The coordinated folding of sigma 1 trimers exemplifies the dominant negative effects of mutant subunits in oligomeric complexes.

Infection of bovine fetuses at 120 days' gestation with virulent and avirulent strains of bluetongue virus serotype 11

Bluetongue virus infection in sheep and cattle during fetal development causes neuropathology. Two strains of bluetongue virus serotype 11 designated as UC-2 and UC-8 have different virulence patterns in newborn mice. These viruses have distinctly different electropherotype patterns on polyacrylamide gel electrophoresis indicating a genetic difference in these two viruses of the same serotype. Four bovine fetuses each were inoculated intramuscularly with either UC-2 or UC-8, and one fetus was inoculated with placebo. The inoculation was made intramuscularly through the uterine wall at 120 days' gestation, and the bovine fetuses were recovered by cesarean section 12 or 20 days after inoculation. Fetal blood was collected for virus isolation and serology. Virus was reisolated from brain, blood, lung and liver. Both strains, UC-2 and UC-8, cause severe lesions in the 120 day fetuses. The encephalomalacic lesions occurred earlier and were more severe in fetuses inoculated with UC-8 as compared to those inoculated with UC-2. The subtle differences observed in the fetuses inoculated with the two different strains suggest that there is a difference in pathogenic potential of the two viruses. These differences do not appear to be completely dependent upon the host species.

The N-terminal heptad repeat region of reovirus cell attachment protein sigma 1 is responsible for sigma 1 oligomer stability and possesses intrinsic oligomerization function

The oligomerization domain of the reovirus cell attachment protein (sigma 1) was probed using the type 3 reovirus sigma 1 synthesized in vitro. Trypsin cleaved the sigma 1 protein (49K molecular weight) approximately in the middle and yielded a 26K N-terminal fragment and a 23K C-terminal fragment. Under conditions which allowed for the identification of intact sigma 1 in the oligomeric form (approximately 200K) by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, the N-terminal 26K fragment was found to exist as stable trimers (80K) and, to a less extent, as dimers (54K), whereas the C-terminal fragment remained in the monomeric form. A polypeptide (161 amino acids) containing the N-terminal heptad repeat region synthesized in vitro was capable of forming stable dimers and trimers. Using various criteria, we demonstrated that the stability of the intact sigma 1 oligomer is conferred mainly by the N-terminal heptad repeat region. Our results are summarized in a model in which individual heptad repeats are held together in a three-stranded alpha-helical coiled-coil structure via both hydrophobic and electrostatic interactions.

Clonal analysis of the cytotoxic T-lymphocyte response to reovirus

Reovirus has previously been classified into three serotypes based on hemagglutination inhibition assays. In the present study, the specificity of cytotoxic T lymphocytes (CTL) generated in reovirus type 3-infected C3H/HeN mice was investigated at the population and clonal levels. Short-term CTL lines generated in response to reovirus type 3 preferentially lysed cells infected with reovirus type 1 or 3 and, in some instances, type 2-infected cells as well. Eleven CTL clones established from the lines demonstrated two unique patterns of recognition. A single clone was exquisitely specific for reovirus type 3-infected cells and did not cross-react on reovirus type 1- or 2-infected cells. Ten of the clones recognized reovirus type 1- and type 3-infected cells. These clones had low levels of cross-reactivity on reovirus type 2-infected cells that was revealed only at high effector:target cell ratios. Precursor frequency analysis further revealed that the majority of the CTL generated against reovirus type 3 could cross-react on both reovirus type 1- and type 2-infected cells. Some CTL could be detected that had a more restricted pattern of recognition and recognized reovirus type 3-infected cells exclusively or recognized reovirus type 3-infected cells and either reovirus type 1- or type 2-infected cells. These results indicate that a minimum of four epitopes are recognized by reovirus-specific CTL and that the response is dominated by CTL that recognize an epitope common to all three serotypes of reovirus.

The use of molecular techniques in studying viral pathogenesis in the nervous system

Molecular biological techniques have been used extensively to gain insights into the pathogenesis of a variety of diseases caused by neurotropic viruses. Increasingly sensitive methods for detecting viral nucleic acids and proteins in pathological nervous tissues have clarified the viral aetiology of certain neurological disorders and are now being used to investigate possible viral involvement in others. In addition, a diverse range of molecular techniques has greatly enhanced our understanding of the molecular basis of viral neurotropism and neurovirulence in both humans and experimental animals. This article provides an overview of these various approaches with examples drawn from both clinical neurological disease and animal models.

Cerebral serotonin in viral encephalitis

In order to evaluate central serotonergic function during viral encephalitis biochemical, behavioural and immunohistofluorescence studies were carried out. Mice were inoculated with the moderate virulent strain of venezuelan equine encephalomyelitis virus, Pixuna. Signs of encephalitis were observed in 50-60% of infected animals. Levels of serotonin and 5-hydroxyindolacetic acid, and the ratio of the indolamine and its metabolite in raphe and cortex did not change with respect to sham-inoculated mice. A differential decrease in turnover rate by pharmacological methods, such as pargyline, p-chlorophenylalanine and probenecid administration, was observed in raphe and cortex. The ratio serotonin turnover rate/steady state concentration of serotonin was only decreased in the raphe of sick animals. The response to 5-methoxy-N,N-dimethyltryptamine was greater in infected animals. The duration of immobility in the swim test was shorter in the infected group. A greater number of viral antigen particles was localized in raphe and periraphe areas than in cortex, brain stem or striatum. The results suggest a serotonin presynaptic deficit, a postsynaptic hyperreactivity of serotonin system, and a region-selective distribution of the virus.

Colorectal carcinogenesis

It is generally accepted that genetic and environmental factors combine in the aetiology of bowel cancer. Epidemiological studies have shown that the environmental factors effects are shown more clearly in the left colon, and that they are related to living in western societies whose diets contain high levels of protein, fat and energy. There has been recent awareness that consumption of alcoholic beverages, particularly beer, may be causally related to cancers of the left colon and rectum. This review attempts to relate the general epidemiological data to more specific mechanisms of colorectal carcinogenesis. Dimethylhydrazine (DMH) and N-nitroso chemicals are potent colorectal carcinogens in animals. They have not been thought very relevant to humans because their existence in appropriate forms in the environment has been debatable and analytical methods for the specific detection of non-volatile nitrosamines and nitrosamides have not been available. Recently, however, relevant alkylating activity has been detected in foods incubated in quasi-gastric conditions, and several epidemiological studies have shown a protective effect for Vitamin C, which may inhibit the development of rectal cancer through beer consumption. As Vitamin C prevents nitrosation and as precursors of nitrosamides are present in prepared foods, further dietary studies with hypotheses based on N-nitroso carcinogenesis are required. Unfortunately, these studies will probably not show clear dose-response relationships. Many of the complex reasons for this are discussed; however, one of the most important could be related to an interplay between inherited and environmental factors. The inherited factors demonstrated by chromosomal analysis in cancer and polyposis syndromes are a reminder that other genetic (oncogenetic) changes may occur in sporadic colorectal cancer.(ABSTRACT TRUNCATED AT 250 WORDS)

Binding and entry of animal viruses

Viruses are infectious agents capable of packaging and delivering nucleic acids and proteins to specific populations of cells. To initiate infection, viruses bind to sites, or receptors, on the cell surface and transfer their genome across the limiting membrane of the cell. The mechanisms underlying these events, and viral tropism for particular host cells, are becoming increasingly well understood. Several cell surface proteins have now been identified as viral receptors, and analyses of intact virus particles and sub-viral components are revealing the structures of the binding determinants on the viruses themselves. For many viruses, the events leading to penetration and delivery involve constitutive endocytic properties of the host cell, and the low pH environment in endocytic compartments is a crucial trigger in the penetration process. The knowledge of viral tropism, binding and entry suggests strategies which may be applied to the design of targeted therapeutic agents with appropriate specificities and effective delivery mechanisms.

Binding and transepithelial transport of immunoglobulins by intestinal M cells: demonstration using monoclonal IgA antibodies against enteric viral proteins

M cells of intestinal epithelia overlying lymphoid follicles endocytose luminal macromolecules and microorganisms and deliver them to underlying lymphoid tissue. The effect of luminal secretory IgA antibodies on adherence and transepithelial transport of antigens and microorganisms by M cells is unknown. We have studied the interaction of monoclonal IgA antibodies directed against specific enteric viruses, or the hapten trinitrophenyl (TNP), with M cells. To produce monospecific IgA antibodies against mouse mammary tumor virus (MMTV) and reovirus type 1, Peyer's patch cells from mucosally immunized mice were fused with myeloma cells, generating hybridomas that secreted virus-specific IgA antibodies in monomeric and polymeric forms. One of two anti-MMTV IgA antibodies specifically bound the viral surface glycoprotein gp52, and 3 of 10 antireovirus IgA antibodies immunoprecipitated sigma 3 and mu lc surface proteins. 35S-labeled IgA antibodies injected intravenously into rats were recovered in bile as higher molecular weight species, suggesting that secretory component had been added on passage through the liver. Radiolabeled or colloidal gold-conjugated mouse IgA was injected into mouse, rat, and rabbit intestinal loops containing Peyer's patches. Light microscopic autoradiography and EM showed that all IgA antibodies (antivirus or anti-TNP) bound to M cell luminal membranes and were transported in vesicles across M cells. IgA-gold binding was inhibited by excess unlabeled IgA, indicating that binding was specific. IgG-gold also adhered to M cells and excess unlabeled IgG inhibited IgA-gold binding; thus binding was not isotype-specific. Immune complexes consisting of monoclonal anti-TNP IgA and TNP-ferritin adhered selectively to M cell membranes, while TNP-ferritin alone did not. These results suggest that selective adherence of luminal antibody to M cells may facilitate delivery of virus-antibody complexes to mucosal lymphoid tissue, enhancing subsequent secretory immune responses or facilitating viral invasion.

Biological function of the rotavirus protein VP4: observations on porcine isolates from China

Rotaviruses isolated from pigs in China were grown in MA104 cells. One tissue-culture-adapted isolate consisted of two subpopulations (variants), the RNA profiles of which differed in the relative migration of RNA segment 4 only. The variants were separated by plaque purification and by recovery from limiting dilutions and remained genetically stable. The variant possessing the slower migrating RNA segment 4, called 4S, grew faster and formed large plaques after 4-6 days incubation, whereas the variant possessing the faster migrating RNA segment 4, called 4F, grew more slowly and formed only microscopic plaques after 10-14 days incubation. The protein product of the 4F RNA occurred in much lower concentration in infected cells than the product of the 4S RNA. The RNA segments 4 of the two variants were found to be closely related when tested by dot hybridization under stringent conditions. The 4S RNA is more resistant to denaturation with methyl mercuric hydroxide than is the 4F RNA. The relevance of these findings to the biological functions of rotaviruses is discussed.

Characterization of a common high-affinity receptor for reovirus serotypes 1 and 3 on endothelial cells

During viremia, viruses may be cleared from the bloodstream and taken up by specific organs. The uptake of virus from the bloodstream is dependent on the association of viral particles with endothelial cells that line the luminal surfaces of large and small blood vessels. To understand the nature of this interaction, we have studied the binding of reovirus serotypes 1 and 3 to these cells in vitro. Both serotypes of reovirus productively infected endothelial cells. By using [35S]methionine-biolabeled reovirus as a tracer ligand, we found that both viruses rapidly bind to endothelial cells and that equilibrium is reached after 4 h. The binding of the radiolabeled viruses was saturable and mediated by a homogeneous population of cellular receptors with very high affinity (Kd = 0.5 nM) for the virus ligands. Both serotypes bind to the same receptor, since the attachment of each radiolabeled serotype is inhibited by both the homologous and heterologous unlabeled virus. Exposure of labeled virus to monoclonal antibodies directed against the viral hemagglutinin (sigma 1 protein) inhibited binding, demonstrating that the attachment of reovirus to endothelial cells is mediated by the hemagglutinin for both serotypes. By using a novel ligand-blotting assay, the binding of both viruses to a 54,000-dalton protein could be demonstrated. The binding of each radiolabeled serotype to this protein was inhibited by the homologous and heterologous unlabeled serotype. By using cell fractionation after homogenization, we demonstrated that this 54-kilodalton protein is a membrane protein, in agreement with its proposed role as a cell surface receptor for reovirus serotypes 1 and 3.

Antibody protects against lethal infection with the neurally spreading reovirus type 3 (Dearing)

The mammalian reoviruses have provided a valuable model for studying the pathogenesis of viral infections of the central nervous system (CNS). We have used this model to study the effect of antibody on disease produced by the neurally spreading reovirus type 3 (Dearing) (T3). Polyclonal and monoclonal antibodies protect mice from fatal infection with T3 after either footpad or intracerebral virus challenge. Protection occurs with monoclonal antibodies directed against the viral cell attachment protein sigma 1, and with polyclonal antisera without T3 sigma 1 binding activity. In vivo protection occurs with both neutralizing and nonneutralizing monoclonal antibodies. Antibody-mediated protection does not require serum complement and, under specific circumstances, can occur via Fc-independent mechanisms. Antibody can protect mice when transferred up to 5 days after intracerebral challenge and up to 7 days after footpad challenge, times when high titers of virus are present in the CNS. Thus, antibody mediated protection against this neurally spreading virus does not require neutralizing antibody or serum complement and occurs even in the face of established CNS infection.

Role of glycoprotein gIII of pseudorabies virus in virulence

Deletion mutants of pseudorabies virus unable to express glycoprotein gIII, gI, or gp63 or double and triple mutants defective in these glycoproteins were constructed, and their virulence for day-old chickens inoculated intracerebrally was determined. Mutants of wild-type pseudorabies virus defective in glycoprotein gIII, gI, or gp63 were only slightly less virulent (at most, fivefold) for chickens than was the wild-type virus. However, mutants defective in both gIII and gI or gIII and gp63 were avirulent for chickens, despite their ability to grow in cell culture in vitro to about the same extent as mutants defective in gIII alone (which were virulent). These results show that gIII plays a role in virulence and does so in conjunction with gI or gp63. The effect of gIII on virulence was also shown when the resident gIII gene of variants of the Bartha vaccine strain (which codes for gIIIB) was replaced with a gIII gene derived from a virulent wild-type strain (which codes for gIIIKa); gIIIKa significantly enhanced the virulence of a variant of the Bartha strain to which partial virulence had been previously restored by marker rescue. Our results show that viral functions that play a role in the virulence of the virus (as measured by intracerebral inoculation of chickens) may act synergistically to affect the expression of virulence and that the ability of the virus to grow in cell culture is not necessarily correlated with virulence.

Three-dimensional model of the capsid proteins of two biologically different Theiler virus strains: clustering of amino acid difference identifies possible locations of immunogenic sites on the virion

To explore structural features of the Theiler murine encephalomyelitis virion, we have constructed a three-dimensional model of the capsid proteins (VP1, VP2, and VP3) of the BeAn strain based on the atomic coordinates of the closely related Mengo virus. By superimposition of amino acid differences between BeAn virus and another Theiler virus strain, GDVII, on the three-dimensional model, clusters of differences were found in four distinct sites; the VP1 third corner, the VP2 "puff," and the VP3 first corner and "knob." These clusters, which are found on the surface of the virion, may represent neutralizing immunogenic sites that have come under selective pressure from neutralizing antibodies. Furthermore, the putative viral receptor binding site ("pit") of the two Theiler virus strains was found to be markedly conserved.

Pathogenesis of experimental reovirus tenosynovitis in chickens: influence of the route of infection

Four groups of specific pathogen-free, day-old chicks were infected experimentally with an avian arthrotropic reovirus strain R2 by four different routes:--oral, subcutaneous, foot-pad and intra-articular. These groups were followed sequentially to study: pathological changes in the hock joints and liver; cloacal virus shedding and the presence of virus in hock joints; serological responses as determined by enzyme linked immunosorbent assay (ELISA), agar gel precipitation (AGP) and virus neutralization tests. All 4 infected groups developed arthritis or tenosynovitis with synovial hyperplasia and lymphocytic infiltration. Foot-pad and intra-articular routes of infection were found to advance the disease process by 2 to 3 weeks after infection by these routes were associated with superficial degenerative changes in articular cartilage. Antibodies were detected at 2 to 3 weeks p.i. by all 3 methods, but there were no significant differences between the patterns of serological response in the infected groups. Injection into the foot-pad appears to be the most convenient and effective parenteral route of experimental infection.

Uptake of reovirus serotype 1 by the lungs from the bloodstream is mediated by the viral hemagglutinin

We used the mammalian reoviruses to determine the molecular basis of the clearance of a virus from the bloodstream by specific organs. Reovirus serotypes 1 (T1) and 3 (T3) were radiolabeled with [35S]methionine or 125I, and the viruses were injected intravenously into weanling rats. The distribution of radioactivity within the animals was determined at various times after the injection. Both viruses were cleared rapidly from the bloodstream and concentrated in different organs. Reovirus T1 was found predominantly in the lungs and liver, whereas T3 was found predominantly in the liver, with very little virus in the lungs. Using intertypic reassortants, we determined that the T1 S1 gene, which encodes the viral hemagglutinin (sigma 1 protein), is responsible for the difference in uptake of T1 and T3 by the lungs. The genetic mapping was extended by using several approaches. (i) T1 subjected to limited proteolytic digestion with chymotrypsin was cleared efficiently by the lungs despite the removal of sigma 3 and digestion of mu 1C to delta. (ii) Uptake of T1 by the lungs was totally inhibited by incubation of T1 with an anti-sigma 1 monoclonal antibody or its Fab fragment before injection. (iii) A reovirus T1 variant in the sigma 1 protein was poorly taken up by the lungs. These data indicate that clearance of reovirus from the bloodstream by the lungs is dependent on the presence of the T1 sigma 1 protein.

Sigma 1 protein of mammalian reoviruses extends from the surfaces of viral particles

Electron microscopy revealed structures consisting of long fibers topped with knobs extending from the surfaces of virions of mammalian reoviruses. The morphology of these structures was reminiscent of the fiber protein of adenovirus. Fibers were also seen extending from the reovirus top component and intermediate subviral particles but not from cores, suggesting that the fibers consist of either the mu 1C or sigma 1 outer capsid protein. Amino acid sequence analysis predicts that the reovirus cell attachment protein sigma 1 contains an extended fiber domain (R. Bassel-Duby, A. Jayasuriya, D. Chatterjee, N. Sonenberg, J. V. Maizell, Jr., and B. N. Fields, Nature [London] 315:421-423, 1985). When sigma 1 protein was released from viral particles with mild heat and subsequently obtained in isolation, it was found to have a morphology identical to that of the fiber structures seen extending from the viral particles. The identification of an extended form of sigma 1 has important implications for its function in cell attachment. Other evidence suggests that sigma 1 protein may occur in virions in both an extended and an unextended state.

Isolation and characterization of a monoclonal anti-P30 antibody resistant mutant of Toxoplasma gondii

Of the possible iodine-labelled Toxoplasma gondii surface proteins, P30 (apparent Mr 30,000) is the principal one recognized by acute and convalescent anti-toxoplasma sera. This protein which comprises from 3 to 5% of the total parasite protein was used to raise a panel of parasiticidal monoclonal anti-P30 antibodies. One of these monoclonal antibodies was able to select a resistant mutant from a large population of chemically mutagenized wild-type P strain parasites. This mutant retained the wild type sensitivity to other non-P30 parasiticidal monoclonal antibodies as well as polyclonal anti-P30 rabbit sera. Analysis of surface radioiodinated wild type and mutant parasites showed that the mutant had a quantitative reduction in the amount of P30. A comparison of surface biotin labelled wild type and resistant parasites by two dimensional electrophoresis showed that the mutant lacked one and possibly two of several proteins that make up wild type P30. Western blot analysis indicated that the mutant was devoid of antigenically reactive P30. These findings further support the hypothesis that antigenic variants of T. gondii can be induced and may involve the major surface membrane antigens of the parasite.