The UL16 protein of herpes simplex virus is capsid associated and was previously identified as a binding partner of the membrane-associated UL11 tegument protein (J. S. Loomis, R. J. Courtney, and J. W. Wills, J. Virol. 77:11417-11424, 2003). In those studies, a less-prominent, ϳ65-kDa binding partner of unknown identity was also observed. Mass spectrometry studies have now revealed this species to be UL21, a tegument protein that has been implicated in the transport of capsids in the cytoplasm. The validity of the mass spectrometry results was tested in a variety of coimmunoprecipitation and glutathione S-transferase pull-down experiments. The data revealed that UL21 and UL16 can form a complex in the absence of other viral proteins, even when the assays used proteins purified from Escherichia coli. Moreover, UL11 was able to pull down UL21 only when UL16 was present, suggesting that all three proteins can form a complex. Deletion analyses revealed that the second half of UL21 (residues 268 to 535) is sufficient for the UL16 interaction and packaging into virions; however, attempts to map a subdomain of UL16 were largely unsuccessful, with only the first 40 (of 373) residues being found to be dispensable. Nevertheless, it is clear that UL16 must have two distinct binding sites, because covalent modification of its free cysteines with N-ethylmaleimide blocked binding to UL11 but not UL21. These findings should prove useful for elucidating the molecular machinery used to transmit a signal into a virion when it attaches to cells, a recently discovered mechanism in which UL16 is a central player.Herpes simplex virus (HSV) contains more than 40 different virally encoded proteins that are found in three distinct layers: the capsid containing the viral DNA, the host-derived lipid envelope with embedded glycoproteins, and the tegument, an assortment of proteins located between the nucleocapsid and the envelope (22). While these regions are often discussed as separate structures, there is now clear evidence that the virion as a whole is a machine with interconnected parts that quickly rearrange on the inside in response to glycoprotein-binding events on the outside. Specifically, tegument protein UL16 is triggered to be released from the capsid when HSV attaches to host cells prior to membrane fusion, and the signal responsible for this can be sent in a cell-free manner by binding virions to immobilized heparin (21). It appears that glycoprotein C is involved in transmitting the signal (at least in a cell-free system), but all the other molecular "cogs" that drive this part of the HSV machine are unknown. To identify these components, we have been investigating UL16 and the network of molecular interactions in which it participates.Our interest in UL16 began when we identified it as a binding partner of UL11 (17), a small tegument protein (only 96 amino acids) that is conserved among all herpesviruses. UL11 is peripherally bound to membranes via two fatty acids, myristate and palmitate (16), and trafficks through lipid ...
Arenaviruses are responsible for acute hemorrhagic fevers with high mortality and pose significant threats to public health and biodefense. These enveloped negative-sense RNA viruses replicate in the cell cytoplasm and express four proteins. To better understand how these proteins insinuate themselves into cellular processes to orchestrate productive viral replication, we have identified and characterized novel cytosolic structures involved in arenavirus replication and transcription. In cells infected with the nonpathogenic Tacaribe virus or the attenuated Candid#1 strain of Junín virus, we find that newly synthesized viral RNAs localize to cytosolic puncta containing the nucleoprotein (N) of the virus. Density gradient centrifugation studies reveal that these replication-transcription complexes (RTCs) are associated with cellular membranes and contain full-length genomic-and antigenomic-sense RNAs. Viral mRNAs segregate at a higher buoyant density and are likewise scant in immunopurified RTCs, consistent with their translation on bulk cellular ribosomes. In addition, confocal microscopy analysis reveals that RTCs contain the lipid phosphatidylinositol-4-phosphate and proteins involved in cellular mRNA metabolism, including the large and small ribosomal subunit proteins L10a and S6, the stress granule protein G3BP1, and a subset of translation initiation factors. Elucidating the structure and function of RTCs will enhance our understanding of virus-cell interactions that promote arenavirus replication and mitigate against host cell immunity. This knowledge may lead to novel intervention strategies to limit viral virulence and pathogenesis.V iruses are wholly reliant on the host cell for replication. Viral proteins must access cellular systems to establish a productive environment for generating progeny virions while also evading the innate antiviral response. Viruses have therefore evolved diverse strategies and multifunctional proteins to coopt the host cell infrastructure. Elucidating these virus-cell interactions may suggest novel targets for antiviral intervention.Arenaviruses can cause acute hemorrhagic fevers with high mortality (34, 43). These viruses are endemic in rodent populations worldwide (47) and can be transmitted to humans by contact. Prototype arenavirus species include Lassa fever virus (LASV) in western Africa and Junín virus (JUNV) in the Pampas region of Argentina. These and other hemorrhagic fever arenaviruses pose ongoing threats to public health and raise concerns for biodefense planners. In the absence of licensed vaccines and specific antiviral therapies, these viruses are recognized as NIH category A priority pathogens (39). A critical understanding of the interactions of arenaviral proteins with the host cell will provide insight toward the development of effective therapies against arenavirus hemorrhagic fevers.The arenaviruses are a diverse family of enveloped negativesense RNA viruses that replicate entirely in the cell cytoplasm (9). The S and L RNA segments of the bipartite aren...
Antibodies produced by clonally expanded plasma cells in multiple sclerosis cerebrospinal fluid cause demyelination of spinal cord explants
B cells are implicated in the etiology of multiple sclerosis (MS). Intrathecal IgG synthesis, cerebrospinal fluid (CSF) oligoclonal bands and lesional IgG deposition suggest a role for antibody-mediated pathology. We examined the binding of IgG1 monoclonal recombinant antibodies (rAbs) derived from MS patient CSF expanded B cell clones to central nervous system (CNS) tissue. MS rAbs displaying CNS binding to mouse and human CNS tissue were further tested for their ability to induce complement-mediated tissue injury in ex vivo spinal cord explant cultures. The staining of CNS tissue, primary human astrocytes and human neurons revealed a measurable bias in MS rAb binding to antigens preferentially expressed on astrocytes and neurons. MS rAbs that recognize myelin-enriched antigens were rarely detected. Both myelin-specific and some astrocyte/neuronal-specific MS rAbs caused significant myelin loss and astrocyte activation when applied to spinal cord explant cultures in the presence of complement. Overall, the intrathecal B cell response in multiple sclerosis binds to both glial and neuronal targets and produces demyelination in spinal cord explant cultures implicating intrathecal IgG in MS pathogenesis.
The UL11 tegument protein of herpes simplex virus plays a critical role in the secondary envelopment; however, the mechanistic details remain elusive. Here, we report a new function of UL11 in the budding process in which it directs efficient acquisition of glycoprotein E (gE) via a direct interaction. In vitro binding assays showed that the interaction required only the first 28, membrane-proximal residues of the cytoplasmic tail of gE, and the C-terminal 26 residues of UL11. A second, weaker binding site was also found in the N-terminal half of UL11. The significance of the gE-UL11 interaction was subsequently investigated with viral deletion mutants. In the absence of the gE tail, virion packaging of UL11, but not other tegument proteins such as VP22 and VP16, was reduced by at least 80%. Reciprocally, wild-type gE packaging was also drastically reduced by about 87% in the absence of UL11, and this defect could be rescued in trans by expressing U L 11 at the U L 35 locus. Surprisingly, a mutant that lacks the C-terminal gE-binding site of UL11 packaged nearly normal amounts of gE despite its strong interaction with the gE tail in vitro, indicating that the interaction with the UL11 N terminus may be important. Mutagenesis studies of the UL11 N terminus revealed that the association of UL11 with membrane was not required for this function. In contrast, the UL11 acidic cluster motif was found to be critical for gE packaging and was not replaceable with foreign acidic clusters. Together, these results highlight an important role of UL11 in the acquisition of glycoprotein-enriched lipid bilayers, and the findings may also have important implications for the role of UL11 in gE-mediated cell-to-cell spread.
Varicella-zoster virus (VZV) infection causes varicella, after which the virus becomes latent in ganglionic neurons. In tissue culture, VZV-infected human neurons remain viable at 2 weeks, whereas fibroblasts develop cytopathology. Next-generation RNA sequencing was used to compare VZV transcriptomes in neurons and fibroblasts and identified only 12 differentially transcribed genes of the 70 annotated VZV open reading frames (ORFs), suggesting that defective virus transcription does not account for the lack of cell death in VZV-infected neurons in vitro.V aricella-zoster virus (VZV) is an exclusively human neurotropic alphaherpesvirus that usually produces varicella (chickenpox) upon primary infection, after which the virus becomes latent in ganglionic neurons along the entire neuraxis. In tissue culture, VZV-infected neurons remain viable 2 weeks after infection, while all nonneuronal cells develop a cytopathic effect (CPE). Our earlier studies of VZV-infected neurons derived from induced pluripotent stem (iPS) cells revealed that neurons appeared healthy 2 weeks later, with no detectable infectious virus in the tissue culture medium; analysis of the neurons revealed VZV DNA, transcripts, and proteins corresponding to the VZV immediate early, early, and late kinetic phases of replication (1). Furthermore, ultrastructural examination revealed few complete virions and numerous aberrant viral particles (2). Together, these findings indicate that VZV is not latent in these neurons, despite the lack of CPE, and suggest a deficiency in replication and viral assembly in neurons during the productive infection. Thus, nextgeneration RNA sequencing (NextGen RNA-seq) was used to examine all annotated VZV transcripts in both cell types.Terminally differentiated human neurons derived from human-induced pluripotent stem cells (iCell; Cellular Dynamics International, Madison, WI) and human fetal lung (HFL) fibroblasts were infected at a multiplicity of infection (MOI) of 1 ϫ 10Ϫ3 cell-free vOka strain VZ virions (Zostavax; Merck, Whitehouse Station, NJ) as described previously (2). Total RNA was extracted from VZV-infected fibroblasts when ϳ80% CPE was reached and from VZV-infected neurons 14 days postinfection (dpi), at which time 5 to 10% of the neurons were infected. cDNA libraries were constructed for each sample (3 neuron, 3 fibroblast samples) using the Illumina TruSeq stranded-mRNA sample preparation kit (Illumina, San Diego, CA). The six independently and uniquely indexed libraries were pooled and loaded onto a single lane of a HiSeq2000 flow cell for paired-end, 100-bp DNA sequencing using an Illumina HiSeq2000.NextGen RNA-seq of six cDNA libraries yielded 29.2 to 76.8 million total reads per sample (Fig. 1A). Removal of low-quality FPKMs from all libraries were separated using principal-component analysis (PCA). Principal component 1 (PC1) separated samples by their largest variance and resulted in separation between cell types. PC2 separated samples by the next-largest variance, independent of the first, and result...
The product of the UL11 gene of HSV-1 is a small, membrane-bound tegument protein with features that are conserved among all herpesviruses. For all viruses examined, mutants lacking this protein (or its homolog) have budding defects and accumulate capsids in the cytoplasm of the infected cell. UL11 binds to the cytoplasmic faces of host membranes via N-terminal myristate and nearby palmitate moieties. These fatty-acid modifications are typical of proteins that localize to detergent-resistant membranes (DRMs), and the experiments described here revealed that a small amount (approximately 10%) of UL11 retains the ability to float in sucrose gradients following treatment of cells with Triton X-100. However, mutants lacking sequences previously shown to be involved in the trafficking of UL11 from the plasma membrane (LI and acidic cluster motifs) were found to have a dramatically increased association with DRMs. These findings emphasize the dynamic properties of this poorly-understood but conserved tegument protein.
Varicella zoster virus (VZV) is a ubiquitous, exclusively human alphaherpesvirus. Primary infection usually results in varicella (chickenpox), after which VZV becomes latent in ganglionic neurons along the entire neuraxis. As VZV-specific cell-mediated immunity declines in elderly and immunocompromised individuals, VZV reactivates and causes herpes zoster (shingles), frequently complicated by postherpetic neuralgia. VZV reactivation also produces multiple serious neurological and ocular diseases, such as cranial nerve palsies, meningoencephalitis, myelopathy, and VZV vasculopathy, including giant cell arteritis, with or without associated rash. Herein, we review the clinical, laboratory, imaging, and pathological features of neurological complications of VZV reactivation as well as diagnostic tests to verify VZV infection of the nervous system. Updates on the physical state of VZV DNA and viral gene expression in latently infected ganglia, neuronal, and primate models to study varicella pathogenesis and immunity are presented along with innovations in the immunization of elderly individuals to prevent VZV reactivation.
All herpesviruses encode a homolog of the herpes simplex virus type-1 UL11 tegument protein. Deletion of UL11 disrupts virus envelopment, causes capsid accumulation within the cytoplasm, and reduces virus release. UL11 requires acylation with myristate and palmitate for membrane binding, lipid raft trafficking, and accumulation at the site of virus envelopment. Thus, it was predicted that acylation of UL11 would be necessary for efficient virion production, similar to HIV-1 Gag which requires myristylation for virus production. Accordingly, recombinant viruses were created to express UL11 derivatives that are not acylated, are partially acylated, or contain foreign acylation signals. Unexpectedly, the non-acylated UL11 rescued some growth defects of a UL11-null mutant, even though the unmodified protein was unstable. Furthermore, a myristylated and palmitylated chimera did not fully rescue the null-virus. These results suggest UL11 maintains some function(s) when not membrane-bound, and the sequence context of the acylations is important for UL11 function.
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