Neurons of the mammalian central nervous system (CNS) are an essential and largely nonrenewable cell population. Thus, virus infections that result in neuronal depletion, either by virus-mediated cell death or by induction of the cytolytic immune response, could cause permanent neurological impairment of the host. In a transgenic mouse model of measles virus (MV) infection of neurons, we have previously shown that the host T-cell response was required for resolution of infection in susceptible adult mice. In this report, we show that this protective response did not result in neuronal death, even during the peak of T-cell infiltration into the brain parenchyma. When susceptible mice were intercrossed with specific immune knockout mice, a critical role for gamma interferon (IFN-␥) was identified in protection against MV infection and CNS disease. Moreover, the addition of previously activated splenocytes or recombinant murine IFN-␥ to MV-infected primary neurons resulted in the inhibition of viral replication in the absence of neuronal death. Together, these data support the hypothesis that the host immune response can promote viral clearance without concomitant neuronal loss, a process that appears to be mediated by cytokines.
In patients with subacute sclerosing panencephalitis (SSPE), which is associated with persistent measles virus (MV) infection in the brain, little infectious virus can be recovered despite the presence of viral RNA and protein. Based on studies of brain tissue from SSPE patients and our work with MV-infected NSE-CD46؉ mice, which express the measles receptor CD46 on neurons, several lines of evidence suggest that the mechanism of viral spread in the central nervous system differs from that in nonneuronal cells. To examine this alternate mechanism of viral spread, as well as the basis for the loss of normal transmission mechanisms, infection and spread of MV Edmonston was evaluated in primary CD46؉ neurons from transgenic mice and differentiated human NT2 neurons. As expected, unlike that between fibroblasts, viral spread between neurons occurred in the absence of syncytium formation and with minimal extracellular virus. Electron microscopy analysis showed that viral budding did not occur from the neuronal surface, although nucleocapsids were present in the cytoplasm and aligned at the cell membrane. We observed many examples of nucleocapsids present in the neuronal processes and aligned at presynaptic neuronal membranes. Cocultures of CD46؉ and CD46؊ neurons showed that cell contact but not CD46 expression is required for MV spread between neurons. Collectively, these results suggest that the neuronal environment prevents the normal mechanisms of MV spread between neurons at the level of viral assembly but allows an alternate, CD46-independent mechanism of viral transmission, possibly through the synapse.After the clearance of acute measles virus (MV) infection in children, a persistent infection of the brain can occur which, after several years, results in the progressive neurological disease subacute sclerosing panencephalitis (SSPE). The symptoms of SSPE consist of gradual deterioration of cognitive and motor functions, and in virtually all cases, the disease is fatal (22). Brain biopsies or postmortem brain analyses from SSPE patients show evidence of astrogliosis, neuronal loss, degeneration of dendrites, demyelination, neurofibrillary tangles, and infiltration of inflammatory cells (2).Despite the long interval between the acute infection and symptoms of SSPE, there is evidence that MV infection of the brain occurs soon after the acute infection, with subsequent spread throughout the brain (3, 19). However, in contrast to MV infection of nonneuronal cells, which is cytopathic and spreads both by extracellular virus and by cell fusion resulting in multinucleated syncytia, little extracellular infectious virus can be recovered from brains of SSPE patients unless tissues are cocultured with permissive fibroblasts (22). Furthermore, high levels of neutralizing antibody are present in the serum and cerebrospinal fluid of SSPE patients (37). Together, these results suggest that extracellular virus might not be responsible for MV spread in the central nervous system (CNS). In support of this hypothesis, extensive...
Barley stripe mosaic virus (BSMV) encodes three movement proteins in an overlapping triple gene block (TGB), but little is known about the physical interactions of these proteins. We have characterized a ribonucleoprotein (RNP) complex consisting of the TGB1 protein and plus-sense BSMV RNAs from infected barley plants and have identified TGB1 complexes in planta and in vitro. Homologous TGB1 binding was disrupted by site-specific mutations in each of the first two N-terminal helicase motifs but not by mutations in two C-terminal helicase motifs. The TGB2 and TGB3 proteins were not detected in the RNP, but affinity chromatography and yeast two-hybrid experiments demonstrated that TGB1 binds to TGB3 and that TGB2 and TGB3 form heterologous interactions. These interactions required the TGB2 glycine 40 and the TGB3 isoleucine 108 residues, and BSMV mutants containing these amino acid substitution were unable to move from cell to cell. Infectivity experiments indicated that TGB1 separated on a different genomic RNA from TGB2 and TGB3 could function in limited cell-to-cell movement but that the rates of movement depended on the levels of expression of the proteins and the contexts in which they are expressed. Moreover, elevated expression of the wild-type TGB3 protein interfered with cell-to-cell movement but movement was not affected by the similar expression of a TGB3 mutant that fails to interact with TGB2. These experiments suggest that BSMV movement requires physical interactions of TGB2 and TGB3 and that substantial deviation from the TGB protein ratios expressed by the wild-type virus compromises movement.For a virus to successfully invade a plant and cause disease, it must have the ability to move from cell to cell, establish localized infection foci, enter and exit the vascular system, and develop systemic infections. To accomplish these activities, plant viruses encode one or more movement proteins (MPs) that facilitate cell-to-cell movement and vascular transport. These proteins generally localize at plasmodesmata (PD) and increase the permeability of the PD sufficiently to permit the movement of macromolecules through the desmotubule (25, 38). Many MPs have RNA binding activities, and some act in concert with other virus-encoded proteins to facilitate virus movement and other activities such as RNA unwinding (18) or suppression of gene silencing (1, 24). Several general classes of viral MPs are known to exist, and these proteins provide tools for investigating a wide range of host-virus interactions and cellular functions (25,26).The most extensively investigated MPs are members of the 30K superfamily that are encoded by a large number of RNA and DNA viruses with different genome organizations (27). Over the past 15 years, studies of the processes carried out by proteins of the 30K movement family have provided great insight into the requirements for local and long-distance transport of Tobacco mosaic virus and a number of other viruses (4,15,25,38). The triple gene block (TGB) superfamily represents anoth...
Although cells of monocytic lineage are the primary source of human immunodeficiency virus type 1 (HIV-1) in the brain, other cell types in the central nervous system, including astrocytes, can harbor a latent or persistent HIV-1 infection. In the present study, we examined whether immature, multipotential human brain-derived progenitor cells (nestin positive) are also permissive for infection. When exposed to IIIB and NL4-3 strains of HIV-1, progenitor cells and progenitor-derived astrocytes became infected, with peak p24 levels of 100 to 500 pg/ml at 3 to 6 days postinfection. After 10 days, virus production was undetectable but could be stimulated by the addition of tumor necrosis factor alpha (TNF-␣). To bypass limitations to receptor entry, we compared the fate of infection in these cell populations by transfection with the infectious HIV-1 clone, pNL4-3. Again, transfected progenitors and astrocytes produced virus for 7 days but diminished to low levels beyond 8 days posttransfection. During the nonproductive phase, TNF-␣ stimulated virus production from progenitors as late as 5 weeks posttransfection. Astrocytes produced 5-to 20-fold more infectious virus (27 ng of p24/10 6 cells) than progenitors at the peak of 3 days posttransfection. Differentiation of infected progenitors toward an astrocyte phenotype increased virus production to levels consistent with infected astrocytes, suggesting a phenotypic difference in viral replication. Using this cell culture system of multipotential human brain-derived progenitor cells, we provide evidence that progenitor cells may be a reservoir for HIV-1 in the brains of AIDS patients.
). We have now extended these analyses by engineering a fusion of GFP to TGB1 to examine the expression and interactions of this protein during infection. BSMV derivatives containing the TGB1 fusion were able to move from cell to cell and establish local lesions in Chenopodium amaranticolor and systemic infections of Nicotiana benthamiana and barley. In these hosts, the GFP-TGB1 fusion protein exhibited a temporal pattern of expression along the advancing edge of the infection front. Microscopic examination of the subcellular localization of the GFP-TGB1 protein indicated an association with the endoplasmic reticulum and with plasmodesmata. The subcellular localization of the TGB1 protein was altered in infections in which sitespecific mutations were introduced into the six conserved regions of the helicase domain and in mutants unable to express the TGB2 and/or TGB3 proteins. These results are compatible with a model suggesting that movement requires associations of the TGB1 protein with cytoplasmic membranes that are facilitated by the TGB2 and TGB3 proteins.
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