Heparan sulfate binding by natural eastern equine encephalitis viruses promotes neurovirulence
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Abstract:
The Alphavirus genus of the family Togaviridae contains mosquito-vectored viruses that primarily cause either arthritogenic disease or acute encephalitis. North American eastern equine encephalitis virus (NA-EEEV) is uniquely neurovirulent among encephalitic alphaviruses, causing mortality in a majority of symptomatic cases and neurological sequelae in many survivors. Unlike many alphaviruses, NA-EEEV infection of mice yields limited signs of febrile illness typically associated with lymphoid tissue replication. Rather, signs of brain infection, including seizures, are prominent. Use of heparan sulfate (HS) as an attachment receptor increases the neurovirulence of cell culture-adapted strains of Sindbis virus, an arthritogenic alphavirus. However, this receptor is not known to be used by naturally circulating alphaviruses. We demonstrate that wild-type NA-EEEV strain FL91-4679 uses HS as an attachment receptor and that the amino acid sequence of its E2 attachment protein is identical to those of natural isolates sequenced by RT-PCR amplification of field samples. This finding unequivocally confirms the use of HS receptors by naturally circulating NA-EEEV strains. Inactivation of the major HS binding domain in NA-EEEV E2 demonstrated that the HS binding increased brain replication and neurologic disease but reduced lymphoid tissue replication, febrile illness signs, and cytokine/chemokine induction in mice. We propose that HS binding by natural NA-EEEV strains alters tropism in vivo to antagonize/evade immune responses, and the extreme neurovirulence of wild-type NA-EEEV may be a consequence. Therefore, reinvestigation of HS binding by this and other arboviruses is warranted.Keywords:
Togaviridae
Sindbis virus
Alphavirus infection
Spatial and Temporal Analysis of Alphavirus Replication and Assembly in Mammalian and Mosquito Cells
ABSTRACT Sindbis virus (SINV [genus Alphavirus , family Togaviridae ]) is an enveloped, mosquito-borne virus. Alphaviruses cause cytolytic infections in mammalian cells while establishing noncytopathic, persistent infections in mosquito cells. Mosquito vector adaptation of alphaviruses is a major factor in the transmission of epidemic strains of alphaviruses. Though extensive studies have been performed on infected mammalian cells, the morphological and structural elements of alphavirus replication and assembly remain poorly understood in mosquito cells. Here we used high-resolution live-cell imaging coupled with single-particle tracking and electron microscopy analyses to delineate steps in the alphavirus life cycle in both the mammalian host cell and insect vector cells. Use of dually labeled SINV in conjunction with cellular stains enabled us to simultaneously determine the spatial and temporal differences of alphavirus replication complexes (RCs) in mammalian and insect cells. We found that the nonstructural viral proteins and viral RNA in RCs exhibit distinct spatial organization in mosquito cytopathic vacuoles compared to replication organelles from mammalian cells. We show that SINV exploits filopodial extensions for virus dissemination in both cell types. Additionally, we propose a novel mechanism for replication complex formation around glycoprotein-containing vesicles in mosquito cells that produced internally released particles that were seen budding from the vesicles by live imaging. Finally, by characterizing mosquito cell lines that were persistently infected with fluorescent virus, we show that the replication and assembly machinery are highly modified, and this allows continuous production of alphaviruses at reduced levels. IMPORTANCE Reemerging mosquito-borne alphaviruses cause serious human epidemics worldwide. Several structural and imaging studies have helped to define the life cycle of alphaviruses in mammalian cells, but the mode of virus replication and assembly in the invertebrate vector and mechanisms producing two disease outcomes in two types of cells are yet to be identified. Using transmission electron microscopy and live-cell imaging with dual fluorescent protein-tagged SINV, we show that while insect and mammalian cells display similarities in entry and exit, they present distinct spatial and temporal organizations in virus replication and assembly. By characterizing acutely and persistently infected cells, we provide new insights into alphavirus replication and assembly in two distinct hosts, resulting in high-titer virus production in mammalian cells and continuous virus production at reduced levels in mosquito cells—presumably a prerequisite for alphavirus maintenance in nature.
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The structural proteins of Western equine encephalitis virus, a member of the alphavirus group, have been characterized by the determination of their amino acid compositions and by N-terminal sequence analysis. More than 60 residues of the N-terminal sequences of each of the envelope glycoproteins have been determined. A comparison of these sequences with the previously determined sequences of two related alphaviruses. Sindbis virus and Semliki Forest virus, strongly supports the view that all three viruses have evolved from a common ancestor and provides information on the pattern of this evolution. The analysis of the capsid proteins of Western equine encephalitis virus shows that the nucleocapsid of this virus can accommodate a considerable degree of variability in its protein component and that at least some regions of alphavirus capsid proteins show more extensive differences between different viruses than do the envelope glycoproteins.
Sindbis virus
Semliki Forest virus
Togaviridae
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Sindbis virus
Viremia
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Attenuated vaccine
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Alphaviruses are members of the Togaviridae family of icosahedral, enveloped, single-strand, message-sense RNA viruses. The mosquito-borne alpha-viruses are important causes of encephalomyelitis in the Americas and are on the category B list of agents of biodefense concern. Eastern equine encephalitis (EEE), western equine encephalitis (WEE), and Venezuelan equine encephalitis (VEE) viruses are the neurotropic alphaviruses of greatest importance as causes of human encephalomyelitis and were initially recognized for their ability to cause disease in horses. Semliki Forest virus (SFV) and Sindbis virus (SINV) do not usually cause encephalitis in humans, but are studied frequently in mice as model systems for alphavirus encephalomyelitis.
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Sindbis virus
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RNA of Kyzylagach virus (KYZV), a Sindbis-like mosquito-borne alphavirus from Western equine encephalitis virus complex, was detected in four pools (out of 221 pools examined), encompassing 10,784 female Culex modestus mosquitoes collected at a fishpond in south Moravia, Czech Republic, with a minimum infection rate of 0.04%. This alphavirus was never detected in Central Europe before.
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Sindbis virus
Alphavirus infection
Antisense therapy
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Alphaviruses are widely distributed throughout the world. During the last few thousand years, the New World viruses, including Venezuelan equine encephalitis virus (VEEV) and eastern equine encephalitis virus (EEEV), evolved separately from those of the Old World, i.e., Sindbis virus (SINV) and Semliki Forest virus (SFV). Nevertheless, the results of our study indicate that both groups have developed the same characteristic: their replication efficiently interferes with cellular transcription and the cell response to virus replication. Transcriptional shutoff caused by at least two of the Old World alphaviruses, SINV and SFV, which belong to different serological complexes, depends on nsP2, but not on the capsid protein, functioning. Our data suggest that the New World alphaviruses VEEV and EEEV developed an alternative mechanism of transcription inhibition that is mainly determined by their capsid protein, but not by the nsP2. The ability of the VEEV capsid to inhibit cellular transcription appears to be controlled by the amino-terminal fragment of the protein, but not by its protease activity or by the positively charged RNA-binding domain. These data provide new insights into alphavirus evolution and present a plausible explanation for the particular recombination events that led to the formation of western equine encephalitis virus (WEEV) from SINV- and EEEV-like ancestors. The recombination allowed WEEV to acquire capsid protein functioning in transcription inhibition from EEEV-like virus. Identification of the new functions in the New World alphavirus-derived capsids opens an opportunity for developing new, safer alphavirus-based gene expression systems and designing new types of attenuated vaccine strains of VEEV and EEEV.
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Semliki Forest virus
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The enveloped alphaviruses include important and emerging human pathogens such as Chikungunya virus and Eastern equine encephalitis virus. Alphaviruses enter cells by clathrin-mediated endocytosis, and exit by budding from the plasma membrane. While there has been considerable progress in defining the structure and function of the viral proteins, relatively little is known about the host factors involved in alphavirus infection. We used a genome-wide siRNA screen to identify host factors that promote or inhibit alphavirus infection in human cells. Fuzzy homologue (FUZ), a protein with reported roles in planar cell polarity and cilia biogenesis, was required for the clathrin-dependent internalization of both alphaviruses and the classical endocytic ligand transferrin. The tetraspanin membrane protein TSPAN9 was critical for the efficient fusion of low pH-triggered virus with the endosome membrane. FUZ and TSPAN9 were broadly required for infection by the alphaviruses Sindbis virus, Semliki Forest virus, and Chikungunya virus, but were not required by the structurally-related flavivirus Dengue virus. Our results highlight the unanticipated functions of FUZ and TSPAN9 in distinct steps of alphavirus entry and suggest novel host proteins that may serve as targets for antiviral therapy.
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Semliki Forest virus
Alphavirus infection
Togaviridae
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Alphaviruses are mosquito-borne causes of acute encephalitis. In humans, the important alphaviruses causing encephalitis are Eastern equine, Western equine, and Venezuelan equine encephalitis viruses, all found in the Americas. Alphaviruses found in other parts of the world (e. g. , Ross River, Sindbis, Chikungunya, and O'Nyong-nyong viruses) cause syndromes of rash and arthritis without encephalitis (1). However, these Old World viruses often cause encephalitis in experimental animals and serve as important models of acute alphavirus encephalitis (). Sindbis virus (SV), the type strain of the alphaviruses, causes an acute age-dependent encephalomyelitis and is the best studied murine model of alphavirus encephalitis.
Sindbis virus
Alphavirus infection
Togaviridae
Encephalitis Viruses
Arbovirus Infections
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