The Severity of Murray Valley Encephalitis in Mice Is Linked to Neutrophil Infiltration and Inducible Nitric Oxide Synthase Activity in the Central Nervous System

A study of immunopathology in the central nervous system (CNS) during infection with a virulent strain of Murray Valley encephalitis virus (MVE) in weanling Swiss mice following peripheral inoculation is presented. It has previously been shown that virus enters the murine CNS 4 days after peripheral inoculation, spreads to the anterior olfactory nucleus, the pyriform cortex, and the hippocampal formation at 5 days postinfection (p.i.), and then spreads throughout the cerebral cortex, caudate putamen, thalamus, and brain stem between 6 and 9 days p.i. (P. C. McMinn, L. Dalgarno, and R. C. Weir, Virology 220:414-423, 1996). Here we show that the encephalitis which develops in MVE-infected mice from 5 days p.i. is associated with the development of a neutrophil inflammatory response in perivascular regions and in the CNS parenchyma. Infiltration of neutrophils into the CNS was preceded by increased expression of tumor necrosis factor alpha and the neutrophil-attracting chemokine N51/KC within the CNS. Depletion of neutrophils with a cytotoxic monoclonal antibody (RB6-8C5) resulted in prolonged survival and decreased mortality in MVE-infected mice. In addition, neutrophil infiltration and disease onset correlated with expression of the enzyme-inducible nitric oxide synthase (iNOS) within the CNS. Inhibition of iNOS by aminoguanidine resulted in prolonged survival and decreased mortality in MVE-infected mice. This study provides strong support for the hypothesis that Murray Valley encephalitis is primarily an immunopathological disease.     

Changes in cerebral level of monoamines by Japanese encephalitis virus infection

The changes in monoamine levels of different brain regions following Japanese encephalitis virus (JEV) intraperitoneal inoculation were examined in experimentally JEV-infected mice. In addition, virus distribution was studied using infectivity assay and immuno-histochemistry of viral antigen. 1) The level of monoamines in brain tissues was not affected by 48 hours after viral inoculation, but marked effects were elicited at 96 hours after the inoculation. The cerebral concentration of 5-hydroxyindole-3-acetic acid (5 HIAA) was increased, while that of dopamine (DA) showed a decrease. Especially these alteration were observed in the cerebral cortex, but not in the cerebellum. 2) The viral growth in the brain was observed at 48 hours after the inoculation. The growth in the cerebellum, however, was found to be lower than those in other cerebral regions. 3) The viral antigen was detected in the cerebral cortex, hippocampus, mesencephalon and diencephalon in addition to the substantia nigra and striatum. From these results, it is presumed that clinical manifestation of JEV infection may involve the changes in the metabolism of neurotransmitter, especially those of DA and serotonin in the brain.     

Severity of neurological signs and degree of inflammatory lesions in the brains of rats with Borna disease correlate with the induction of nitric oxide synthase.

The putative role of nitric oxide in the neuropathogenesis of Borna disease was investigated by determining changes in the expression of inducible nitric oxide synthase (iNOS) mRNA and constitutively expressed NOS (cNOS) mRNA in brains of Borna disease virus (BDV)-infected rats. iNOS mRNA was not detected in normal rat brain but was identified in BDV-infected brain at 14 days postinfection (p.i.), reaching maximum levels at 21 days p.i., when neurological signs and inflammatory reactions in the brain were also at a peak. cNOS mRNA was expressed in both normal brain and infected brain, increasing markedly at 17 days p.i. and reaching a peak at 21 days p.i. In situ hybridization analysis revealed iNOS mRNA in some, but not all, BDV-infected regions of the brain, particularly in the basolateral cortex and the hippocampus. iNOS-positive cells, as identified immunohistologically, were preferentially localized in perivascular areas of the hippocampus and in outer cortical layers. These iNOS-positive cells resembled monocytes/macrophages in morphology and distribution pattern but were significantly fewer. The correlation of iNOS and cNOS mRNA expression with the development of neurological disease, as well as the enhanced expression of iNOS within brain regions with inflammatory lesions, strongly suggests that NO may contribute to pathogenesis of Borna disease.     

Role of plasminogen in propagation of scrapie

To investigate whether plasminogen may feature in scrapie infection, we inoculated plasminogen-deficient (Plg(-/-)), heterozygous plasminogen-deficient (Plg(+/-)), and wild-type (Plg(+/+)) mice by the intracerebral or intraperitoneal (i.p.) route with the RML scrapie strain and monitored the onset of neurological signs of disease, survival time, brain, and accumulation of scrapie disease-associated forms of the prion protein (PrP(Sc)). Only after i.p. inoculation, a slight, although significant, difference in survival (P < 0.05) between Plg(-/-) and Plg(+/+) mice was observed. Neuropathological examination and Western blot analysis were carried out when the first signs of disease appeared in Plg(+/+) animals (175 days after i.p. inoculation) and when mice reached the terminal stage of illness. At the onset of symptoms, PrP(Sc) accumulation was higher in the brain and spleen of Plg(+/+) and Plg(+/-) mice than in those of Plg(-/-) mice, and these differences were paralleled by differences in the severity of spongiform changes and astrogliosis in the cerebral cortex and subcortical gray structures. Immunohistochemical analysis of the spleens before inoculation did not show any impairment of the immune system affecting follicular dendritic or lymphoid cells in Plg(-/-) mice. Once the disease progressed and mice began to die of infection, differences were no longer apparent in either brains or spleens. In conclusion, our data indicate that plasminogen has no major effect on the survival of scrapie agent-infected mice.     

Long‐term infection of adult mice with murine polyomavirus following stereotaxic inoculation into the brain

Murine polyomavirus is used in various models of persistent virus infection. This study was undertaken to assess the spatial and temporal patterns of MPyV infection in the brains of immunocompetent (BALB/c) and immunocompromised (KSN nude) mice. MPyV was stereotaxically microinfused into the brain parenchyma, and the kinetics of infection were examined by quantitative PCR. In BALB/c mice, the amount of viral DNA in the brain peaked at 4 days p.i. and then rapidly diminished. In contrast, MPyV DNA levels increased up to 4 days and then gradually decreased over the 30‐day observation period in the brain of KSN mice. In both mouse strains, viral DNA was readily detected around the sites of inoculation from 2 to 6 days p.i., and continued to be detected for up to 30 days p.i. In addition, MPyV infection did not lead to a drastic induction of innate immune response in the brains, nor did MPyV‐inoculated mice show any signs of disease. These results indicate that MPyV establishes an asymptomatic long‐term infection in the mouse brain.     

The monkey pathogenicity of the Columbia Sk virus and the mouse-adapted lansing strain of poliomyelitis virus,and the influence of monkey passage on the characteristics of the virus

Summary The intracerebral inoculation of cynomolgus monkeys with Columbia SK virus (mouse brain suspension) produced flaccid paralysis after an incubation period of 3 to 5 days. In the spinal cord leucocytic infiltrations, acute necrosis and neuronophagia of anterior horn cells were found. Similar lesions, but far less extensive were found in the medulla and the brain stem, whereas leucocytic perivascular infiltrations were present in the motor area of the cerebral cortex. Small accumulations of leucocytes were observed in the heart muscle and in the epicardium. The Lansing strain of poliomyelitis virus produced essentially similar lesions, though less extensive, and the incubation period was 14 days. In the heart muscle and the epicardium of a Lansing-infected monkey small mononuclear infiltrations were found. The mouse infectivity titer of the ColSK virus decreased rapidly after monkey passage, and there was a simultaneous decrease of the hemagglutination titer with sheep red cells. No close antigenic relationship between the Y-SK and the ColSK virus was demonstrated by the hemagglutination inhibition reaction with sera from monkeys immunized against Y-SK and ColSK virus. The question is discussed, whether or not the ColSK group of viruses, which should be considered to be of animal origin, has to be classed into the family of poliomyelitis viruses as a fourth immunological type.     

Localization of measles virus antigens in subacute sclerosing panencephalitis in ferrets

Young adult male ferrets were inoculated intracerebrally (i.c.) with a cell-associated encephalitogenic subacute sclerosing panencephalitis (SSPE) virus strain to study the pathogenesis of the disease at the ultrastructural level. Most became acutely ill in 8-13 days. Areas of the brain were examined with indirect immunoperoxidase labeling techniques to detect measles antigen. None of these animals showed the characteristic viral nucleocapsids or marked inflammatory response associated with SSPE. However, all had positive immunolabeling of unstructured virus antigen, especially in post-synaptic regions in all areas of the brain that were examined. One ferret, immunized with measles vaccine 40 days prior to challenge with SSPE, became ill 18 days post inoculation (p.i.). Perivascular cuffings of inflammatory cells and large cytoplasmic inclusions of fuzzy nucleocapsids were found in the brain and spinal cord. The study indicates that ferrets which become acutely ill after inoculation with cell-associated SSPE virus do so before there is a marked cellular immune response or formation of virus nucleocapsids.     

Retrograde axonal transport: a major transmission route of enterovirus 71 in mice

Inoculation of enterovirus 71 (EV71) by the oral (p.o.), intramuscular (i.m.), or intracranial route resulted in brain infection, flaccid paralysis, pulmonary dysfunction, and death of 7-day-old mice. The lag time of disease progression indicated that neuroinvasion from the inoculation sites was a prerequisite for the development of the clinical signs. Although EV71 p.o. inoculation led to a persistent viremia and a transient increase in blood-brain barrier permeability at the early stage of the infection, only low levels of virus, which led to neither severe infection nor clinical illness, could be detected in the brain, suggesting that hematogenous transport might not represent a major transmission route. In the spinal cord, following both p.o. and hind limb i.m. inoculation, the virus first appeared and increased rapidly in the lower segments, especially at the anterior horn areas, and then spread to the upper segments and brain in the presence of viremia. A reverse pattern, with the virus being first detected in the upper segment, was observed when the virus was i.m. inoculated in the forelimb. Colchicine, a fast axonal transport inhibitor, but not sciatic nerve transection reduced EV71 neuroinvasion in a dose-dependent manner, indicating a neuronal transmission of the virus.     

Pathogenesis of Borna disease in rats: evidence that intra-axonal spread is the major route for virus dissemination and the determinant for disease incubation.

Borna disease virus is an uncharacterized agent that causes sporadic but fatal neurological disease in horses and sheep in Europe. Studies of the infection in rats have shown that the agent has a strict tropism for neural tissues, in which it persists indefinitely. Inoculated rats developed encephalitis after an incubation period of 17 to 90 days. This report shows that the incubation period is the time required for transport of the agent in dendritic-axonal processes from the site of inoculation to the hippocampus. The immune responses to the agent had no effect on replication or transport of the virus. The neural conduit to the brain was proven by intranasal inoculation of virus that resulted in rapid transport of the agent via olfactory nerves to the hippocampus and in development of disease in 20 days. Virus inoculation into the feet resulted in spread along nerve fibers from neuron to neuron. There was sequential replication in neurons of the dorsal root ganglia adjacent to the lumbar spinal cord, the gracilis nucleus in the medulla, and pyramidal cells in the cerebral cortex, followed by infection of the hippocampal neurons and onset of disease. This progression required 50 to 60 days. The exclusiveness of the neural conduit was proven by failure to cause infection after injection of the virus intravenously or into the feet of neurectomized rats.     

Axonal and transsynaptic (transneuronal) spread of Herpesvirus simiae (B virus) in experimentally infected mice.

In order to study the pathogenesis of B virus infection of the nervous system, newborn and young mice were inoculated by four different routes: 1. Intramuscular (i.m.) in the forelimb; 2. I.m. in the hindlimb; 3. Subcutaneous (s.c.) in the abdominal wall; 4. Intraperitoneal (i.p.). Spread of virus was followed by immunohistochemical demonstration of viral antigen in tissue sections of the peripheral and central nervous system. Three distinct patterns emerged: 1. After i.m. limb inoculations, virus progressed along the ipsilateral dorsal column, the bilateral spinothalamic and bilateral spinoreticular systems and along central autonomic pathways. 2. After s.c. inoculation, the dorsal column was spared, otherwise the spread was similar to that following i.m. inoculations. 3. After i.p. inoculation, virus spread in the spinal cord bilaterally, mainly along spinothalamic and central autonomic pathways. The peripheral motoneurons were conspicuously spared, even in the i.m. inoculation mode. In the brain stem, B virus antigen appeared bilaterally, at multiple sites. In the cerebrum, virus infected cells appeared first in the thalamus, hypothalamus and the motor cortex. The mode of spread from spinal levels was mainly orthograde along the ascending systems (dorsal columns, spinothalamic, spinoreticular tracts), but also retrograde along descending systems (pyramidal tract, central autonomic pathways). Oligosynaptic systems transmitted virus more quickly than the polysynaptic ones. In the involvement of various neuronal systems in virus spread, a certain selectivity, sparing the peripheral motoneuron and the cerebellar systems, could be assessed.     

BIOCHEMICAL EFFECTS OF THYROID DEFICIENCY ON THE DEVELOPING BRAIN

Abstract— The effects of neonatal thyroidectomy on some constituents of the cerebrum, cerebellum and liver of the rat have been studied during the first 7 weeks of life. In the normal rat between the 6th and 14th post-natal days the RNA content per unit of DNA in the brain increased by 70 per cent. Although the brain continued to grow from the 14th to the 35th day, the amount of RNA relative to DNA decreased by about 20 per cent. The ratio of protein to DNA increased during the whole period studied and in the cerebral cortex it was more than trebled between the age of 6 and 35 days. The growth of the cerebellum extended over a longer period than that of the cerebrum, its weight increasing by 88 per cent between the ages of 14 and 35 days as compared with a cerebral increase of 34 per cent. The DNA content showed a 50 per cent increase during this period. Qualitatively these maturational changes were not affected by neonatal thyroidectomy. Quantitative changes, which applied equally to the cerebral cortex and brain as a whole, were observed. At the age of 35 days, the weights of the cerebral hemispheres and cerebellum were reduced by thyroidectomy by 20 per cent; the overall DNA content per organ did not change, but the amounts of protein and RNA relative to DNA decreased significantly. It is therefore inferred that thyroid deficiency affects the size of the cells in brain and cerebellum rather than their total number. Conversely, the cell population of the liver was only a quarter of that in the control. There was a small but significant decrease in the hepatic protein and RNA content in the hypothyroid animal. The activities of the following enzymes which served as markers for subcellular fractions in homogenates of cerebral cortex were determined: lactate dehydrogenase for the supernatant, glutamate dehydrogenase for the mitochondrial and glutamate decarboxylase for the synaptosomal fractions. When the activities were expressed on a fresh weight basis a significant decrease by comparison with the control values was observed only in the case of glutamate decarboxylase (—15 per cent at the age of 17–32 days); when the activities were based on DNA content all values were reduced, probably as a result of the general decrease in cell size. Pyrimidine metabolism of brain and liver, studied after the administration of [6-¹⁴C]-orotic acid, was not affected in either tissue by neonatal thyroidectomy. A small but significant reduction in the incorporation of labelled pyrimidine nucleotides in liver RNA was observed, but no significant decrease in the incorporation in cerebral RNA was found in the hypothyroid rats.     

THE ACCUMULATION OF RADIOACTIVE ACETYLCHOLINE BY A SYMPATHETIC GANGLION AND BY BRAIN: FAILURE TO LABEL ENDOGENOUS STORES

Abstract— The accumulation of radioactively labelled acetylcholine (ACh) by perfused superior cervical ganglia of cats and by incubated brain slices from rats was studied in the presence of diisopropylphosphorofluoridate. Ganglia accumulated more labelled ACh than an extracellular marker (inulin), but the amount of ACh accumulated did not increase when ACh turnover was increased by preganglionic nerve stimulation. The ACh that accumulated in ganglia was not released when the preganglionic nerve was subsequently stimulated. Sliced cerebral cortex also accumulated labelled ACh but this was not released when the tissue was subsequently exposed to a high K⁺ medium. Thus accumulated ACh does not appear to mix with releasable transmitter stores. Chronically (7 days) decentralized ganglia lost most of their transmitter store but retained their ability to accumulate labelled ACh. Uptake of ACh by sliced cerebellum was not less than uptake of ACh by sliced cerebral cortex and the amount of ACh accumulated by synaptosomes isolated from cerebellum was similar to the amount of ACh accumulated by synaptosomes isolated from cerebral cortex. It is concluded that ACh uptake is not specifically into cholinergic nerve endings. Hexamethonium reduced ACh uptake by cerebral cortex slices but did not increase the amount of ACh collected from slices stimulated by raised K⁺.     

Kinetics of cytokine profile during intraperitoneal inoculation of Japanese encephalitis virus in BALB/c mice model

Infection with Japanese encephalitis virus (JEV) is mostly asymptomatic/subclinical in 90% of the individuals. Host immune response during subclinical JEV infection is poorly understood. We assessed iNOS, IFN-gamma, TNF-alpha, IL-10 and IL-4 production in spleen, brain and sera of intraperitoneally challenged BALB/c mice by RT-PCR and ELISA along with brain histopathology at different days post inoculation (d.p.i.). In spleen of virus infected mice, expression of all cytokines including iNOS mRNA were upregulated till 5d.p.i. followed by decline. At 5d.p.i., IL-10 expression outcompeted TNF-alpha, IFN-gamma and IL-4. However, in the virus infected mice sera, IL-4 production predominated over TNF-alpha and IL-10 at 5d.p.i. Conversely, cytokines expression and iNOS mRNA remained unchanged in the brain of virus infected mice from 1 to 7d.p.i. A significant increase in the cytokine expression was observed at 11d.p.i. (P<0.05) in virus infected mice brain, with the predominance of IL-10 along with the presence of meningeal inflammation and viral RNA by histology and RT-PCR, respectively. We report a biased pattern of cytokine production in sera, brain and spleen of mice intraperitoneally challenged with JEV. IL-10 exerts neuroprotective function during JEV and regulates deleterious effects of proinflammatory cytokines; however, its mechanism needs further investigation.     

Susceptibility of chickens to avian encephalomyelitis virus. III. Behavior of the virus in growing chicks.

A chick embryo-adapted strain of avian encephalomyelitis virus was inoculated subcutaneously and orally into 40-day-old (middle-aged) and 110-day-old (advanced-aged) chicks to examine the behavior of the virus in the chick body. In the middle-aged chicks, the virus appeared in the muscle at the site of inoculation, liver, spleen, pancreas, lumbar and cervical portions of the spinal cord, and brain 1 approximately 9 days after subcutaneous inoculation, and remained mostly in the central nervous system up to 17 days after the inoculation. The virus was found in large amounts in the muscle at the site of inoculation (10(3.1)), lumbar portion (10(2.5)) and cervical portion (10(2.1)) of the spinal cord, brain (10(1.9)), and in minute amounts in the other organs examined. It appeared in 11 of 21 organs examined. In the middle-aged chicks inoculated by the oral route, the virus was detected transiently in small amounts from esophagus, pancreas, and rectum 4 approximately 14 days after inoculation. In the advanced-aged chicks inoculated by the subcutaneous route, the virus was detected in titer of 10(2.1) approximately 10(3.0) from the muscle at the site of inoculation 2 approximately 7 days after inoculation. The virus was also found sporadically in several organs up to 17 days after inoculation. In the advanced-aged chicks inoculated by the oral route, no virus appeared in any organ, but these chicks turned to be weakly positive for neutralizing antibody in the 4th or later week after inoculation.     

Susceptibility of chickens to avian encephalomyelitis virus. II. Behavior of the virus in day-old chicks.

The VR strain of avian encephalomyelitis virus, which had been adapted to embryonated hen's eggs, was inoculated into 2-day-old chicks by the subcutaneous route (10(2.5) approximately 10(3.0) EID50) or by the oral route (10(4.8) EID50). The chicks were examined chronologically for the distribution of the virus in the body. As a result, minute amounts of the virus were detected from the liver, spleen, pancreas, and muscle at the site of inoculation one day after inoculation and various amounts from almost all the organs 3 days and more after inoculation. The virus titer could nearly reach a maximum 7 to 9 days after inoculation. Above all, such high virus titers as ranging from 10(4.3) to 10(5.8) EID50/0.1 g were demonstrated in the brain, heart, liver, spleen, and pancreas. After that, there was a tendency for virus titer to decrease in most organs and for virus to multiply persistently in the pancreas, brain, and eyeball. Virus titer was maintained at a level of 10(2.3) approximately 10(2.8) EID50/0.1 g in these three organs even 21 days after inoculation. In the group of subcutaneous inoculation, all the chicks manifested clinical signs of infection 5 to 10 days after inoculation. On the other hand, no chicks were involved in clinical infection in the group of oral inoculation. Multiplication of the virus was delayed in the body of these chicks. Small amounts of the virus were detected from the spleen and pancreas 11 days after inoculation. Low titers (10(2.7) EID50/0.1 g at the highest) of the virus were only detected from the brain, spinal cord, spleen, pancreas, esophagus, and other organs 14 and 21 days after inoculation.     

Influence of Prenatal Hypoxia on Brain Development: Effects on Body Weight, Brain Weight, DNA, Protein, Acetylcholinesterase, 3-Quinuclidinyl Benzilate Binding, and In Vivo Incorporation of [14C]Lysine into Subcellular Fractions

Abstract: The influence of prenatal hypoxia on subsequent brain development in the young rat was investigated by examining body and brain weight, cerebral cortex wet weight, protein and DNA concentrations, acetylcholinesterase (AChE) activity, 3-quinuclidinyl benzilate (QNB)-binding levels, the relative amounts of protein in various subcellular fractions, and the in vivo incorporation of [¹⁴C]lysine into the protein of homogenate and subcellular fractions. Exposure of pregnant females to a mild hypoxia (9.1% Os, 10 h per day for the 9-11 days preceding birth) resulted in a reduced body weight in the pups at days 1 and 5 after birth; total cortical DNA was reduced but brain weight and protein content were unaffected, leading to a higher protein/DNA ratio in prenatally hypoxic pups. By 10 days of age these differences between prenatally hypoxic and control animals were no longer apparent. There were no differences between prenatally hypoxic and control animals in AChE and QNB binding per milligram cortex protein. The relative amount of synaptic membrane protein from the cerebral cortex was reduced at day 1 in prenatally hypoxic animals and the synaptic membrane fraction showed a higher level of incorporation of [¹⁴C]lysine on days 1, 5, and 10. The developmental profile of [¹⁴C]lysine incorporation showed a peak on day 10 which was higher in prenatally hypoxic rats. By 46 days after birth little difference could be found between prenatally hypoxic and control animals.     

Enhanced Brain Cell Proliferation Following Early Adrenalectomy in Rats

We have previously demonstrated an increase in adult brain DNA content in rats adrenalectomized on postnatal day 11. The present studies examined cell proliferation in cerebral cortex, cerebellum, hippocampus, and midbrain-diencephalon following adrenalectomy at this age. Compared to sham-operated controls, adrenalectomized animals showed increased [3H]thymidine incorporation into DNA (measured at 1 h following a pulse injection) in all brain regions at 7 and 14 days postsurgery. In some areas, the effect was already present as early as 2 days following adrenalectomy. Chronic replacement with corticosterone prevented this increase in DNA labelling in a dose-dependent manner. When cell proliferation in the cerebral cortex and cerebellum was independently assessed by measuring changes in thymidine kinase activity, enzyme activity was significantly elevated in both areas at 7 and 14 days postsurgery. Finally, histological examination of the cerebellar cortex suggested a delayed disappearance of the external granular layer in several cerebellar lobules of adrenalectomized animals. Overall, these findings indicate that day-11 adrenalectomy leads to a prolonged stimulation of mitotic activity in areas where cell formation at this time is exclusively glial (i.e., cerebral cortex and mid-brain-diencephalon) as well as in areas where postnatal neurogenesis is also occurring (cerebellum and hippocampus). It is hypothesized that this stimulation results from the removal of a tonic inhibitory effect exerted by circulating glucocorticoids in the normal intact animal.     

Growth Curve and Distribution of Rous Sarcoma Virus (Bryan) in Japanese Quail

On primary infection with the Bryan strain of Rous sarcoma virus (RSV), the growth curve of the virus in the brain of Japanese quail was similar to that observed in chicks and turkey poults. Infectious virus disappeared from the brain after inoculation. After an eclipse period during which no virus was detectable, infectious virus began to appear at 2 days and reached maximal titers in the brain samples at 7 days after inoculation. When Japanese quail were infected intracerebrally with RSV, relatively high titers of virus were recovered from brain tissue but not from liver, lung, kidney, or blood of moribund birds. Only tumors produced in the wing web of quail infected subcutaneously yielded high titers of virus. Other tissues yielded no virus, even though wing web tumors appeared as early as in chicks similarly infected. RSV could be propagated in the wing web of quail for at least 14 passages without any loss of infectivity. On the other hand, serial passage in quail brain resulted in a progressive loss of infectivity until virus was completely lost.