Global ETD Search

1	Clearing up Culex Confusion : A Basis for Virus Vector Discrimination in Europe Hesson, Jenny C. January 2014 (has links) Mosquito species of the Culex genus are the enzootic vectors for several bird-associated viruses that cause disease in humans. In Europe, these viruses include Sindbis (SINV), West Nile and Usutu viruses. The morphologically similar females of Cx. torrentium and Cx. pipiens are potential vectors of these viruses, but difficulties in correctly identifying the mosquito species have caused confusion regarding their respective distribution, abundance, ecology, and consequently their importance as vectors. Species-specific knowledge from correctly identified field material is however of crucial importance since previous research shows that the relatively unknown Cx. torrentium is a far more efficient SINV vector than the widely recognized Cx. pipiens. The latter is involved in the transmission of several other viruses, but its potential importance for SINV transmission is debated. In this thesis I describe the development of a molecular method for species identification, based on reliably identified males of Cx. torrentium and Cx. pipiens. This identification method was then used in consecutive studies on the distribution and relative abundance of the two species in Sweden and 12 other European countries, SINV field infection rates in mosquitoes identified to species level, and evaluation of potential trap bias associated with common sampling techniques. The results showed that Cx. torrentium is a far more common species in Europe than previously assumed. In Sweden and Finland, it is the dominant species, accounting for 89% of the sampled Culex population. In central Europe, it is equally common to Cx. pipiens, while Cx. pipiens dominates south of the Alps Mountain range. Larvae of both species are often found together in both artificial containers (e.g. car tires) and natural sites. Also, a trapping bias against Cx. torrentium was revealed for CDC-traps. For the first time, SINV was isolated from species-identified Cx. torrentium and Cx. pipiens mosquitoes caught in the field, with Cx. torrentium being superior in infection rates (36/1,000 vs. 8.2/1,000). Future studies on SINV, as well as other mosquito-borne bird viruses in Europe, can hopefully gain from the baseline information provided here, and from principles of vector discrimination discussed in the thesis. Culex torrentium Culex pipiens mosquitoes vector ornithophilic Sindbis virus West Nile virus
2	The C-Terminal Region of Hepatitis C Core Protein Is Required for FAS-Ligand Independent Apoptosis in Jurkat Cells by Facilitating FAS Oligomerization Moorman, Jonathan P., Prayther, Deborah, McVay, Derek, Hahn, Young S., Hahn, Chang S. 01 August 2003 (has links) Hepatitis C virus (HCV) is remarkable for its ability to establish persistent infection. Studies suggest that HCV core protein modulates immune responses to viral infection and can bind Fas receptor in vitro. To further examine the role of HCV core protein in Fas signaling, full-length (aa 1-192) and truncated (aa 1-152) HCV core proteins were expressed in Jurkat lymphocytes and cells were assayed for apoptotic response, caspase activation, and Fas activation. Jurkat expressing full-length but not truncated core protein exhibited ligand-independent apoptosis. Cytoplasmic targeting of truncated core protein recapitulated its ability to induce apoptosis. Activation of caspases 8 and 3 was necessary and sufficient for full-length core to induce apoptosis. Jurkat cells expressing full-length but not truncated core protein induced Fas receptor aggregation. HCV core activates apoptotic pathways in Jurkat via Fas and requires cytoplasmic localization of core. Infection of host lymphocytes by HCV may alter apoptotic signaling and skew host responses to acute infection. apoptosis caspase core protein fas hepatitis C immune evasion lymphocyte sindbis virus viral persistence Internal Medicine
3	Different cortical projections from three subdivisions of the rat lateral posterior thalamic nucleus: a single neuron tracing study with viral vectors / ラット視床後外側核を構成する３つの亜核は固有の皮質投射様式を示す：ウイルスベクターによる単一ニューロンの標識・再構築・形態学的解析 Nakamura, Hisashi 25 July 2016 (has links) Final publication is available at http://dx.doi.org/10.1111/ejn.12882 / 京都大学 / 0048 / 新制・論文博士 / 博士(医学) / 乙第13040号 / 論医博第2115号 / 新制\|\|医\|\|1017(附属図書館) / 33032 / 京都大学大学院医学研究科医学専攻 / (主査)教授渡邉大, 教授影山龍一郎, 教授髙橋良輔 / 学位規則第4条第2項該当 / Doctor of Medical Science / Kyoto University / DFAM axonal arborization extrageniculate pathway Sindbis virus single neuron labeling 490
4	Two Odorant-Binding Protein Genes in Mosquitoes: Comparative Genomics, Expression, and Function Sengul, Meryem Senay 22 April 2008 (has links) Insect Odorant-Binding Proteins (OBPs) are small, water-soluble molecules that solubilize hydrophobic odorant molecules in the sensillum lymph and transport them to their cognate receptors in the olfactory receptor neurons. With the availability of the genome sequence of the African malaria mosquito, Anopheles gambiae, there has been a profound interest in the characterization and functional analyses of Obp genes in order to understand the molecular basis of mosquito host-seeking behavior. However, no direct evidence has been found for specific functions of any mosquito OBPs. In this study, I describe the comparative genomics and expression analyses on two mosquito Obp genes (Obp1 and Obp7) as well as efforts to determine their functions. Both of these Obp genes were identified in Anopheles stephensi and only Obp7 gene was identified in Anopheles quadriannulatus by screening bacterial artificial chromosome (BAC) libraries of these species. Comparative analyses revealed several interesting features including segments of conserved non-coding sequences (CNSs) that contain potential regulatory elements relevant to olfactory tissue development and blood-feeding. The expression profiles of these genes were examined in detail in the Asian malaria mosquito An. stephensi. Obp1 and Obp7 transcripts were significantly higher in females than male mosquitoes and they were predominantly found in the antenna, which is the primary olfactory organ of mosquitoes. Twenty-four hours after a blood meal, mRNA levels of these two genes were significantly reduced in the maxillary palp and proboscis, referred to as secondary olfactory organs of mosquitoes. These findings collectively indicate that Obp1 and Obp7 genes in An. stephensi likely function in female olfactory response and may be involved in behaviors related to blood-feeding. To investigate the function of these Obp genes more directly, a Sindbis virus based expression system is established to knockdown the two Obp gene orthologs in Aedes aegypti. The effective knockdown of Obp1 and Obp7 genes (8 and 100-fold, respectively) is accomplished in female mosquito olfactory tissues. The potential for a systematic analysis of the molecular players involved in mosquito olfaction using this newly developed technique is discussed. Such analysis will provide the foundation for interfering with mosquito host-seeking behavior for the prevention of disease transmission. / Ph. D. gene knockdown Sindbis virus gene expression mosquito olfaction odorant-binding protein genes
5	Bird-parasite interactions : Using Sindbis virus as a model system Lindström, Karin M. January 2000 (has links) <p>This thesis focuses on the evolutionary interactions between birds and a parasite, the mosquito-borne Sindbis virus (Togaviridae, <i>Alphavirus</i>). In conclusion, the results show that the Sindbis virus is widespread among birds, and that the fitness of infected hosts may be reduced by the virus. Furthermore, viruclearance ability was revealed by male plumage traits, and viraemia was related to hormonal- and social status.</p><p>The distribution of Sindbis virus infections among passerine birds was examined in five areas in Sweden. Almost all species tested were infected, and three species of thrushes weridentified as the main hosts. In a series of experimental infections, greenfinches (<i>Carduelis chloris</i>) kept in aviaries were used ahosts. First, the behavioural consequences of an infection were investigated. During the infection, birds tended to reduce thespontaneous locomotion activity, and when escaping from a simulated predator attack, infected birds had reduced take-off spee Furthermore, when comparing virus clearance rate between male greenfinches, I found that males with large yellow tail ornaments hafaster virus clearance rates as compared to those with smaller ornaments. Thus, male virus clearance ability was honestly revealed by the size of an ornament. Moreover, males with experimentally elevated testosterone levels experienced a delayed, but not increased viraemia as compared to controls. When the relationship between male social ranand viraemia was examined, I found no evidence that high-ranked males suffered reduced rank during the infection. Nevertheless, viraemipatterns of males were related to their social rank, so that low-ranked birds had a delayed viraemia as compared to high-ranked birds. </p> Developmental biology Carduelis chloris Sindbis virus host-parasite interaction ornament social dominance testosterone sexual selection Utvecklingsbiologi Developmental biology Utvecklingsbiologi
6	Bird-parasite interactions : Using Sindbis virus as a model system Lindström, Karin M. January 2000 (has links) This thesis focuses on the evolutionary interactions between birds and a parasite, the mosquito-borne Sindbis virus (Togaviridae, Alphavirus). In conclusion, the results show that the Sindbis virus is widespread among birds, and that the fitness of infected hosts may be reduced by the virus. Furthermore, viruclearance ability was revealed by male plumage traits, and viraemia was related to hormonal- and social status. The distribution of Sindbis virus infections among passerine birds was examined in five areas in Sweden. Almost all species tested were infected, and three species of thrushes weridentified as the main hosts. In a series of experimental infections, greenfinches (Carduelis chloris) kept in aviaries were used ahosts. First, the behavioural consequences of an infection were investigated. During the infection, birds tended to reduce thespontaneous locomotion activity, and when escaping from a simulated predator attack, infected birds had reduced take-off spee Furthermore, when comparing virus clearance rate between male greenfinches, I found that males with large yellow tail ornaments hafaster virus clearance rates as compared to those with smaller ornaments. Thus, male virus clearance ability was honestly revealed by the size of an ornament. Moreover, males with experimentally elevated testosterone levels experienced a delayed, but not increased viraemia as compared to controls. When the relationship between male social ranand viraemia was examined, I found no evidence that high-ranked males suffered reduced rank during the infection. Nevertheless, viraemipatterns of males were related to their social rank, so that low-ranked birds had a delayed viraemia as compared to high-ranked birds. Developmental biology Carduelis chloris Sindbis virus host-parasite interaction ornament social dominance testosterone sexual selection Utvecklingsbiologi Developmental biology Utvecklingsbiologi
7	Réponse cellulaire à l'infection par les arbovirus Sindbis et Zika. Effets d'un facteur environnemental : le cadmium / Cellular response to Sindbis and Zika arbovirus infection Effects of an environmental factor : the cadmium Frumence, Étienne 08 July 2016 (has links) Les arbovirus sont un groupe de virus transmis par des vecteurs arthropodes contaminant chaque année plusieurs centaines de millions de personnes à travers le monde. De nombreux facteurs environnementaux, comme les xénobiotiques peuvent influencer la propagation des infections virales, la susceptibilité de l'hôte et la sévérité de l'infection. Parmi eux, le cadmium, métal toxique est connu pour moduler la résistance de l'hôte lors des infections par les arbovirus. Ces travaux de thèse se sont portés sur l'étude de l'alphavirus Sindbis et du flavivirus Zika infectant des cellules épithéliales humaines. Les résultats de cette thèse ont permis de démontrer que les cellules A549 étaient permissives à la souche épidémique de 2013 du virus Zika. Le virus se réplique efficacement et induit une apoptose de type mitochondriale dans les cellules A549. La réponse immunitaire innée des cellules a été caractérisée et le rôle des interférons de type I a été mis en avant. Ces résultats peuvent contribuer à une meilleure compréhension des mécanismes de pathogénicité de ce virus chez l'homme. Par la suite, les effets d'une exposition au cadmium lors des infections par les virus Sindbis et Zika ont été évalués. L'infection par le virus Zika n'a pas été modulée par l'exposition au cadmium in vitro. Mais de façon surprenante dans le cas de l'infection des cellules HEK 293, le cadmium a protégé les cellules des effets cytopathiques induits par le virus Sindbis. En présence de cadmium, l'apoptose induite par le virus a été inhibée et la réplication du virus Sindbis a été réduite. / Arboviruses are a group of viruses transmitted by arthropod vectors infecting hundreds of millions of people each year worldwide. Many environmental factors including xenobiotics can influence the spread, the susceptibility and the outcome of viral infections. Among them, cadmium, a toxic metal is known to affect the host resistance against arboviral infection. In this thesis, our work has been focused on studying the infection capability of the Sindbis alphavirus and the Zika flavivirus in human epithelial cells. The results demonstrated that A549 cells was permissive to the 2013 epidemic strain of Zika virus. The virus replicates efficiently leading to mitochondrial apoptosis. The innate immune response was characterized and the crucial role of type I interferon was highlighted. These results may contribute to a better understanding of Zika virus pathogenesis in humans. Thereafter, the effects of cadmium exposure on Sindbis virus and Zika virus infection was evaluated. Zika virus infection was not modulated by cadmium in vitro. Interestingly, cadmium protected the HEK 293 cells from the cytopathic effect induced by Sindbis virus. Cadmium exposure inhibited the apoptosis and reduced the viral replication. Arbovirus Virus Sindbis Virus Zika Réponse cellulaire Interféron Apoptose Cadmium Arbovirus Sindbis virus Zika virus Cell response Interferon Apoptosis Admium
8	Sindbis Virus Entry of Mosquito Midgut Epithelia...Is NRAMP Involved? Chim, Florence Yi Ting 01 January 2015 (has links) Sindbis virus (SINV) is an arthropod-borne Alphavirus in the family Togaviridae. Sindbis virus has a broad host range that includes avian, mammalian, and human hosts; therefore, its receptor(s) is/are highly conserved. When the mosquito imbibes a viremic blood meal, the virus infects the midgut cells, disseminates into the hemolymph, and eventually infects the salivary glands. The midgut is an organ of transmission and the virus must overcome the midgut epithelia infection- and escape-barriers. Sindbis virus infection is determined by the chance collision of the glycoproteins with a compatible receptor. Research has supported the involvement of high-affinity laminin receptor and heparan sulfate in SINV binding to host cells. However, it has been suggested that not all strains of SINV are dependent on heparan sulfate for attachment/entry and that SINV could be utilizing multiple receptors. A study using Drosophila demonstrated that, of the nine genes that encode for proteins that enhance SINV infection, only natural resistance-associated macrophage protein (NRAMP) was conserved. A symporter of divalent metals and hydrogen ions, NRAMP is ubiquitously expressed. Overexpression of NRAMP led to an increase in SINV infection of human cells while deletion of NRAMP in mouse and Drosophila decreased SINV infection. Sindbis virus could be utilizing this protein to overcome the infection barriers of mosquito midgut epithelia. In this study, NRAMP was localized to Aedes aegypti and Anopheles quadrimaculatus tissues via immunofluorescence assay and TR339-TaV-eGFP was detected in the midgut epithelia and visceral muscles. We suspect that NRAMP was detected on midguts and/or Malpighian tubules of Aedes aegypti and Anopheles quadrimaculatus. The similarities between the pattern of NRAMP labeling and TR339-TaV-eGFP infection of the midgut suggest that SINV infection is influenced by NRAMP in the midgut epithelia. Because NRAMP is ubiquitously expressed, this research provides insight into the attachment and entry phase of the arbovirus lifecycle. Thesis University of North Florida UNF Dissertations Dissertations Academic -- UNF -- Biology Sindbis virus Alphavirus Togaviridae Aedes aegypti Anopheles quadrimaculatus NRAMP Biology Life Sciences
9	Characterization of zoonotic flavi- and alphaviruses in sentinel animals in South Africa Human, Stacey 02 January 2012 (has links) In South Africa (SA), the arboviruses West Nile virus (WNV), Wesselsbron virus (WSLV), Sindbis virus (SINV) and Middelburg virus (MIDV) are considered the most important flavi- and alphaviruses. Clinical presentation and importance of these viruses as animal pathogens in SA remains ambiguous. Although widely endemic in SA, lineage 2 (L2) WNV has rarely been associated with cases of neurological disease and was therefore assumed to be non-pathogenic. However, fatal encephalitis in a foal was diagnosed as L2 WNV in SA, 1996, leading to the thought that L2 cases were possibly being missed. As the above-mentioned arboviruses have the same transmission vectors, Culex mosquitoes for WNV and SINV and Aedes mosquitoes for WSLV and MIDV, co-screening for these viruses is important. We hypothesise that horses could be used as sentinels for virus activity in SA and cases of unexplained neurological disease or fever in animals overlooked, rather than being non-existent. To this end, the study aimed to screen horses displaying unexplained neurological disease or fever with Flavivirus family-specific RT-PCR. Additionally, samples were screened with an Alphavirus family-specific RT-PCR to determine whether co-circulating viruses could be responsible for neurological symptoms in horses. The results would aid in establishing the molecular epidemiology and disease description of each virus, virus distribution and disease seasonality in SA. In total 261 clinical specimens were collected from horses displaying these symptoms (2008 - 2010). Samples were screened with Flavi- and Alphavirus differential diagnostic RT-PCR and acute serum was screened for WNV-IgM and neutralizing antibodies. Serological screening (WNV haemagglutination inhibition, WNV IgG and/or WNV neutralization) identified 62 suspected WNV cases while 34 cases could be confirmed by RT-PCR (16/34), WNV IgM and neutralization assays (18/34) and virus isolation. Neurological disease made up 91% (31/34) of the cases, mortality was calculated at 44% (15/34). Phylogenetically 12/16 RT-PCR positives grouped with L2 SA strains. The first detection of L1 WNV and horse-associated abortion in SA was reported when a pregnant mare aborted her foetus in Ceres, Western Cape. The first cases of WSLV-associated disease in horses were identified by sequencing Flavivirus RT-PCR positive products from 2 horses displaying severe neurological disease; one being fatal. This suggests missed cases in the past. To elucidate virulence factors of WSLV, a human encephalitic strain AV259, was subjected to Roche FLX454 full-genome sequencing and compared to a previously sequenced febrile strain (H177). Several structural amino acid changes occurred in proteins NS2A, NS4B and NS5 of AV259; necessary for Flavivirus replication. Phylogenetically AV259, clinical horse strains and WSLV strains previously isolated from animals, humans and arthropods were similar. Additionally and in concurrence with other studies, WSLV clusters with Sepik virus (SEPV) within the YFV group of the Flaviviridae family. Alphavirus screening identified 17 cases; 6/17 SINV and 11/17 MIDV. SINV-WNV co-infections resulted in fatal neurological disease; remaining SINV cases recovered after displaying fever and/or mild neurological disease. MIDV symptoms varied from “three-day-stiffness” to severe neurological symptoms, with 2 fatalities. Co-infections with equine encephalosis and Shuni virus were identified. MIDV strains identified in this study were phylogenetically distinct from older strains. Results highlight the use of horses as sentinels for virus activity and suggest that these arboviruses may have been previously missed as horse pathogens in Africa. These viruses should be considered as the aetiological agents in animals displaying unexplained neurological or hepatic disease, fevers or abortions. Awareness of flavi- and alphaviruses and the disease manifestation they may have in horses was illustrated. These findings suggest that a WNV vaccine may be beneficial for horses in SA. / Dissertation (MSc)--University of Pretoria, 2011. / Medical Virology / Unrestricted Wesselsbron virus (WSLV) West Nile virus (WNV) Flavivirus Encephalitis Horses South Africa (SA) Middelburg virus (MIDV) Alphavirus Sindbis virus (SINV) UCTD
10	Utilizing Proteomic Techniques to Discover Host Protein Interactions with the E1 Glycoprotein of Venezuelan Equine Encephalitis Virus (VEEV) for Anti-Viral Discovery Panny, Lauren E. 27 June 2023 (has links) Venezuelan equine encephalitis virus (VEEV) is an alphavirus that causes disease in humans and equines eliciting both an agricultural and public health threat. In humans, the disease typically presents as a febrile illness with common signs of fever and malaise. Four to fourteen percent of Venezuelan equine encephalitis (VEE) cases are associated with severe neurological complications due to encephalitis caused by VEEV's propensity to infect the brain. Public health concerns are exacerbated by VEEV's aerosolization capabilities, low infectious dose and affordability to mass produce. These qualities drove interest in the pathogen as a bioweapon by the US and the former Soviet Union during the cold war. As a precautionary response to VEEV's notoriety as a biothreat, the National Institute of Allergies and Infectious Diseases has classified VEEV as a category B priority pathogen, and the Human Health Services and United States Department of Agriculture list live virulent strains of VEEV as a select agent and require the pathogen to be manipulated in highly regulated biosafety level 3 (BSL3) facilities. There are currently no FDA approved vaccines or antivirals to target VEEV or other closely related alphaviruses associated with clinical disease in humans. The research performed in this dissertation aimed to elucidate new antiviral targets and treatments to help bridge gaps in current understanding of alphaviruses. The current market lacks available antibodies for E1 specific isolation. In response, a recombinant VEEV TC-83 was produced with a V5 tag at the C-terminal of the E1 sequence to enable VEEV E1 detection. Sequencing was used to verify V5 insertion in the plasmid and immunoprecipitation was used to verify V5 insertion within the E1 glycoprotein. Replication kinetics experiments verified the virus replicated similarly to the parental VEEV TC-83 strain, while passaging experiments verified the tag was highly stable for up to 10 passages. This research produced a cost-effective and highly efficient means to probe and isolate the E1 glycoprotein without modifying the viability of the virus. Knowledge of host protein interactions with VEEV E1 glycoprotein has been limited, with most E1 research focusing on its fusion capabilities. Utilizing 293-T cells infected with E1-V5 TC-83, co-immunoprecipitation was performed to isolate E1 and associated interactors. A total of 486 host and 5 viral protein interactors of E1 were discovered after normalization to the negative control. The top peptide spectrum matches (PSMs) revealed a number of chaperone proteins and ubiquitin proteins as top interactors of VEEV E1. These results effectively revealed a number of previously unknown alphavirus interactions that can be targeted by antivirals and explored further for implications in viral replication. LC-MS/MS results showed that protein disulfide isomerase family A member 6 (PDIA6) interacted with E1. High PSMs, presence in all 3 replicates, similar cellular localization to E1 and known associations between other viruses and protein disulfide isomerase (PDI) family members made this protein an optimum target for further analysis. Co-immunoprecipitation and co-localization experiments were used to validate the LC-MS/MS results. Involvement of PDIs in VEEV replication were explored utilizing two known PDI inhibitors, LOC14 and Nitazoxanide. LOC14, a non-FDA approved broad-spectrum PDI inhibitor, showed broad-spectrum alphavirus antiviral potential, decreasing titers of VEEV TC-83, VEEV Trinidad Donkey strain, eastern equine encephalitis virus (EEEV), chikungunya virus (CHIKV) and Sindbis (SINV) virus in a dose dependent manner. Nitazoxanide, an FDA approved drug known to inhibit PDIA3, was shown to have minimal toxicity and effectively reduced VEEV TC-83 and EEEV titers at concentrations with 100% cell viability. Time of addition assays, E1 expression time course studies, and early event assays showed PDI inhibition with these drugs effects early viral production events. RNA quantification, confocal microscopy and biotin switch assay experiments show that the drugs also prevented proper folding of the E1 glycoprotein and decreased expression of E1 on the peripheral membrane. With no current treatments for alphaviruses, these data provide an effective broad-spectrum target that affects viral replication at multiple stages in-vitro. Nitazoxanide also presents as a promising, non-toxic drug that could be repurposed to combat a number of clinically relevant alphaviruses. Valosin containing protein (VCP) was also shown to interact with the E1 glycoprotein. Exploration of VCP's interaction with alphavirus E1 has never been explored, yet it was previously shown to be involved in alphavirus replication. Co-localization and co-immunoprecipitation experiments were performed validating the interaction between VCP and E1. siRNA knockdown of VCP in 293-T cells and U87-MG cells showed a significant reduction in VEEV TC-83 titers. The allosteric VCP inhibitor, NMS-873, also reduced VEEV TC-83 titers, but was shown to be less effective against CHIKV, SINV and EEEV, suggesting the NMS-873 mechanism is more selective for VEEV. Mechanism experiments showed that reduction of VCP with NMS-873 inhibits early events of VEEV replication. These results elucidate VCP's association with E1 and show that VCP can be targeted to decrease VEEV viral replication. / Doctor of Philosophy / Venezuelan equine encephalitis virus (VEEV) causes disease in humans, as well as horses, donkeys and other closely related animals. In humans, the virus causes a flu-like disease and sometimes swelling of the brain. This can be associated with symptoms such as light sensitivity, confusion and sometimes coma. Prior to the Cold War, VEEV was researched by the US and previous Soviet Union's militaries in hopes to deploy the virus as a bioweapon. Current treaties prevent active production of such weapons, yet allows for defensive research to continue in preparation for a worst-case scenario. Currently no FDA approved medications or vaccines exist to combat the virus further exacerbating concerns. In order to protect laboratorians and prevent unintentional or intentional introduction of the virus into the community, the virus is only manipulated in highly secure facilities with barriers that separate the virus from personnel and the outside environment. A component of the virus called E1, allows for the virus to be released from a structure, called an endosome, that transports the virus into the cell. Currently, E1 is mostly known for this function, yet our research found that E1 interacts with 486 protein components of the host cell, suggesting a more elaborate role of E1 than previously understood. This list of interactors provides numerous new targets for potential medications to combat VEEV and other closely related viruses. Discovered E1 interactors, protein disulfide isomerase family A member 6 (PDIA6) and valosin containing protein (VCP), were validated through extensive experimentation and their function in viral replication was further explored. Protein disulfide isomerases (PDI), such as PDIA6, play an important role in folding proteins, which are cellular components made of organic building blocks called amino acids. PDIs do so by creating organic pillars, called disulfide bonds, between two cysteine amino acid residues. These disulfide bonds contribute to the 3D shape of the proteins they fold which are essential for the protein's function. E1 of VEEV has a total of eight disulfide bonds within its structure, highlighting that disulfide bonds are likely essential for the protein's structure, and therefore, function. We verified that E1 could not properly fold without PDI function by using two compounds that prevented PDI from forming or breaking disulfide bonds, specifically LOC14 and FDA approved drug nitazoxanide. Cells treated with one of either compound before and after infection with VEEV, were found to produce E1 protein with significantly less disulfide bonds therefore producing less viable virus. Further experiments also showed that the compounds also affected early stages in the virus production cycle. These two mechanisms explain the significant reduction in production of VEEV and related viruses when PDI is inhibited. These results provide a new VEEV drug target, PDIs, as well as two compounds that can potentially be used to combat VEEV and other related viruses that have no current treatment options. Another host interactor, VCP, functions throughout the cell and is known for unfolding of numerous substrates, including proteins. It is involved in numerous cellular functions thus making this interactor a promising target for drug treatment. Cells with reduced VCP function were shown to produce less progeny VEEV. Cells treated with NMS-873, a compound that reduces VCP function was also shown to reduce VEEV production. NMS-863 inhibition of VCP was shown to effect early events in VEEV replication. These results further emphasize the E1 interactors discovered are invaluable novel targets for VEEV drug treatment. Venezuelan equine encephalitis virus alphavirus E1 host interactors LC/MS/MS protein disulfide isomerase valosin containing protein PDIA6 eastern equine encephalitis virus Sindbis virus Chikungunya virus

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