Autophagy can play an important part in protecting host cells during virus infection, and several viruses have developed strategies by which to evade or even exploit this homeostatic pathway. Tissue culture studies have shown that poliovirus, an enterovirus, modulates autophagy. Herein, we report on in vivo studies that evaluate the effects on autophagy of coxsackievirus B3 (CVB3). We show that in pancreatic acinar cells, CVB3 induces the formation of abundant small autophagy-like vesicles and permits amphisome formation. However, the virus markedly, albeit incompletely, limits the fusion of autophagosomes (and/or amphisomes) with lysosomes, and, perhaps as a result, very large autophagy-related structures are formed within infected cells; we term these structures megaphagosomes. Ultrastructural analyses confirmed that double-membraned autophagy-like vesicles were present in infected pancreatic tissue and that the megaphagosomes were related to the autophagy pathway; they also revealed a highly organized lattice, the individual components of which are of a size consistent with CVB RNA polymerase; we suggest that this may represent a coxsackievirus replication complex. Thus, these in vivo studies demonstrate that CVB3 infection dramatically modifies autophagy in infected pancreatic acinar cells.Macroautophagy-henceforth referred to as autophagy-is an intracellular process that is important for cellular differentiation, homeostasis, and survival. Through autophagy, longlived cytosolic proteins and organelles become encapsulated within double-membraned vesicles, called autophagosomes, which fuse with lysosomes to facilitate degradation of protein and cellular organelles and to promote nutrient recycling/regeneration. Autophagy plays a key role in the host immune response to infection by viruses, bacteria, fungi, and parasites (reviewed in references 10 and 62). Within virus-infected cells, whole virions and/or viral proteins and nucleic acids are captured inside autophagosomes and degraded (following lysosomal fusion) through the process of xenophagy. Moreover, autophagosome fusion with the endosomal/lysosomal pathway facilitates Toll-like receptor recognition of viral materials and delivers endogenous cytosolic viral proteins to the major histocompatibility complex (MHC) class II antigen presentation pathway, which in turn may help to trigger activation of innate immunity (and type I interferon production) and promote antigen presentation to virus-specific CD4 ϩ T cells (reviewed in references 9, 41, 44, 47, 72, and 90). A recent study has shown that autophagy is also involved in the processing and presentation of MHC class I-restricted viral epitopes (13).Given the importance of autophagy in antiviral immunity, it is perhaps not surprising that viruses have evolved mechanisms to evade and/or subvert this pathway (reviewed in references 9, 11, 14, 35, 37, 60, 61, and 77). Several members of the herpesvirus family, most notably herpes simplex virus type 1, inhibit autophagy within an infected cell and encode prote...
Disruption of autophagy – a key homeostatic process in which cytosolic components are degraded and recycled through lysosomes – can cause neurodegeneration in tissue culture and in vivo. Up-regulation of this pathway may be neuroprotective, and much effort is being invested in developing drugs that cross the blood brain barrier and increase neuronal autophagy. One well-recognized way of inducing autophagy is by food restriction, which up-regulates autophagy in many organs including the liver; but current dogma holds that the brain escapes this effect, perhaps because it is a metabolically-privileged site. Here, we have re-evaluated this tenet using a novel approach that allows us to detect, enumerate, and characterize autophagosomes in vivo. We first validate the approach by showing that it allows the identification and characterization of autophagosomes in the livers of food-restricted mice. We use the method to identify constitutive autophagosomes in cortical neurons and Purkinje cells, and we show that short-term fasting leads to a dramatic up-regulation in neuronal autophagy. The increased neuronal autophagy is revealed by changes in autophagosome abundance and characteristics, and by diminished neuronal mTOR activity in vivo, demonstrated by a reduction in levels of phosphorylated S6 ribosomal protein in Purkinje cells. The increased abundance of autophagosomes in Purkinje cells was confirmed using transmission electron microscopy. Our data lead us to speculate that sporadic fasting might represent a simple, safe and inexpensive means to promote this potentially-therapeutic neuronal response.
There is compelling evidence to support the idea that autophagy has a protective function in neurons and its disruption results in neurodegenerative disorders. Neuronal damage is well-documented in the brains of HIV-infected individuals, and evidence of inflammation, oxidative stress, damage to synaptic and dendritic structures, and neuronal loss are present in the brains of those with HIV-associated dementia. We investigated the role of autophagy in microglia-induced neurotoxicity in primary rodent neurons, primate and human models. We demonstrate here that products of simian immunodeficiency virus (SIV)-infected microglia inhibit neuronal autophagy, resulting in decreased neuronal survival. Quantitative analysis of autophagy vacuole numbers in rat primary neurons revealed a striking loss from the processes. Assessment of multiple biochemical markers of autophagic activity confirmed the inhibition of autophagy in neurons. Importantly, autophagy could be induced in neurons through rapamycin treatment, and such treatment conferred significant protection to neurons. Two major mediators of HIV-induced neurotoxicity, tumor necrosis factor-α and glutamate, had similar effects on reducing autophagy in neurons. The mRNA level of p62 was increased in the brain in SIV encephalitis and as well as in brains from individuals with HIV dementia, and abnormal neuronal p62 dot structures immunoreactivity was present and had a similar pattern with abnormal ubiquitinylated proteins. Taken together, these results identify that induction of deficits in autophagy is a significant mechanism for neurodegenerative processes that arise from glial, as opposed to neuronal, sources, and that the maintenance of autophagy may have a pivotal role in neuroprotection in the setting of HIV infection.
Multiple sclerosis (MS) is an inflammatory central nervous system (CNS) disorder characterized by T cell-mediated demyelination. In MS, prolonged T cell survival and increased T cell proliferation have been linked to disease relapse and progression.Recently, the autophagy-related gene 5 (Atg5) has been shown to modulate T cell survival. In this study, we examined the expression of Atg5 using both a mouse model of autoimmune demyelination as well as blood and brain tissues from MS cases. Quantitative real-time PCR analysis of RNA isolated from blood samples of experimental autoimmune encephalomyelitis (EAE) mice revealed a strong correlation between Atg5 expression and clinical disability. Analysis of protein extracted from these cells confirmed both upregulation and post-translational modification of Atg5, the latter of which was positively correlated with EAE severity. Analysis of RNA extracted from T cells isolated by negative selection indicated that Atg5 expression was significantly elevated in individuals with active relapsing-remitting MS compared to non-diseased controls. Brain tissue sections from relapsing-remitting MS cases examined by immunofluorescent histochemistry suggested that encephalitogenic T cells are a source of Atg5 expression in MS brain samples. Together these data suggest that increased T cell expression of Atg5 may contribute to inflammatory demyelination in MS.
Methamphetamine (Meth) abuse increases risky behaviors that contribute to the spread of HIV infection. In addition, because HIV and Meth independently affect physiological systems including the central nervous system, HIV-induced disease may be more severe in drug users. We investigated changes in blood and brain viral load as well as differences in immune cells in chronically simian immunodeficiency virusinfected rhesus macaques that were either administered Meth or used as controls. Although Meth administration did not alter levels of virus in the plasma, viral load in the brain was significantly increased in Meth-treated animals compared with control animals. Meth treatment also resulted in an activation of natural killer cells. Given the prevalence of Meth use in HIV-infected and HIV at-risk populations, these findings reveal the likely untoward effects of Meth abuse in such individuals.
Many viruses encode proteins whose major function is to evade or disable the host T cell response. Nevertheless, most viruses are readily detected by host T cells, and induce relatively strong T cell responses. Herein, we employ transgenic CD4+ and CD8+ T cells as sensors to evaluate in vitro and in vivo antigen presentation by coxsackievirus B3 (CVB3), and we show that this virus almost completely inhibits antigen presentation via the MHC class I pathway, thereby evading CD8+ T cell immunity. In contrast, the presentation of CVB3-encoded MHC class II epitopes is relatively unencumbered, and CVB3 induces in vivo CD4+ T cell responses that are, by several criteria, phenotypically normal. The cells display an effector phenotype and mature into multi-functional CVB3-specific memory CD4+ T cells that expand dramatically following challenge infection and rapidly differentiate into secondary effector cells capable of secreting multiple cytokines. Our findings have implications for the efficiency of antigen cross-presentation during coxsackievirus infection.
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