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1. Immune-related transcripts, microbiota and vector competence differ in dengue-2 virus-infected geographically distinct Aedes aegypti populations

   https://doi.org/10.1186/s13071-023-05784-3  

   Chen, Tse-Yu; Bozic, Jovana; Mathias, Derrick; Smartt, Chelsea T (December 2023, Parasites & Vectors)

   Abstract BackgroundVector competence inAedes aegyptiis influenced by various factors. Crucial new control methods can be developed by recognizing which factors affect virus and mosquito interactions. MethodsIn the present study we used three geographically distinctAe. aegyptipopulations and compared their susceptibility to infection by dengue virus serotype 2 (DENV-2). To identify any differences among the three mosquito populations, we evaluated expression levels of immune-related genes and assessed the presence of microbiota that might contribute to the uniqueness in their vector competence. ResultsBased on the results from the DENV-2 competence study, we categorized the three geographically distinctAe. aegyptipopulations into a refractory population (Vilas do Atlântico), a susceptible population (Vero) and a susceptible but low transmission population (California). The immune-related transcripts were highly expressed in the California population but not in the refractory population. However, the Rel-1 gene was upregulated in the Vilas do Atlântico population following ingestion of a non-infectious blood meal, suggesting the gene’s involvement in non-viral responses, such as response to microbiota. Screening of the bacteria, fungi and flaviviruses revealed differences between populations, and any of these could be one of the factors that interfere with the vector competence. ConclusionsThe results reveal potential factors that might impact the virus and mosquito interaction, as well as influence theAe. aegyptirefractory phenotype. Graphical Abstract 

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2. Single-Cell Infection of Influenza A Virus Using Drop-Based Microfluidics

   https://doi.org/10.1128/spectrum.00993-22  

   Loveday, Emma Kate; Sanchez, Humberto S.; Thomas, Mallory M.; Chang, Connie B. (October 2022, Microbiology Spectrum)

   Kolawole, Abimbola O. (Ed.)

   ABSTRACT Drop-based microfluidics has revolutionized single-cell studies and can be applied toward analyzing tens of thousands to millions of single cells and their products contained within picoliter-sized drops. Drop-based microfluidics can shed insight into single-cell virology, enabling higher-resolution analysis of cellular and viral heterogeneity during viral infection. In this work, individual A549, MDCK, and siat7e cells were infected with influenza A virus (IAV) and encapsulated into 100-μm-size drops. Initial studies of uninfected cells encapsulated in drops demonstrated high cell viability and drop stability. Cell viability of uninfected cells in the drops remained above 75%, and the average drop radii changed by less than 3% following cell encapsulation and incubation over 24 h. Infection parameters were analyzed over 24 h from individually infected cells in drops. The number of IAV viral genomes and infectious viruses released from A549 and MDCK cells in drops was not significantly different from bulk infection as measured by reverse transcriptase quantitative PCR (RT-qPCR) and plaque assay. The application of drop-based microfluidics in this work expands the capacity to propagate IAV viruses and perform high-throughput analyses of individually infected cells. IMPORTANCE Drop-based microfluidics is a cutting-edge tool in single-cell research. Here, we used drop-based microfluidics to encapsulate thousands of individual cells infected with influenza A virus within picoliter-sized drops. Drop stability, cell loading, and cell viability were quantified from three different cell lines that support influenza A virus propagation. Similar levels of viral progeny as determined by RT-qPCR and plaque assay were observed from encapsulated cells in drops compared to bulk culture. This approach enables the ability to propagate influenza A virus from encapsulated cells, allowing for future high-throughput analysis of single host cell interactions in isolated microenvironments over the course of the viral life cycle. 

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3. Alpha‐mannosidase‐2 modulates arbovirus infection in a pathogen‐ and Wolbachia ‐specific manner in Aedes aegypti mosquitoes

   https://doi.org/10.1111/imb.12904  

   Urakova, Nadya; Joseph, Renuka_E; Huntsinger, Allyn; Macias, Vanessa_M; Jones, Matthew_J; Sigle, Leah_T; Li, Ming; Akbari, Omar_S; Xi, Zhiyong; Lymperopoulos, Konstantinos; et al (March 2024, Insect Molecular Biology)

   Abstract MultipleWolbachiastrains can block pathogen infection, replication and/or transmission inAedes aegyptimosquitoes under both laboratory and field conditions. However,Wolbachiaeffects on pathogens can be highly variable across systems and the factors governing this variability are not well understood. It is increasingly clear that the mosquito host is not a passive player in whichWolbachiagoverns pathogen transmission phenotypes; rather, the genetics of the host can significantly modulateWolbachia‐mediated pathogen blocking. Specifically, previous work linked variation inWolbachiapathogen blocking to polymorphisms in the mosquito alpha‐mannosidase‐2 (αMan2) gene. Here we use CRISPR‐Cas9 mutagenesis to functionally test this association. We developed αMan2 knockouts and examined effects on bothWolbachiaand virus levels, using dengue virus (DENV;Flaviviridae) and Mayaro virus (MAYV;Togaviridae).Wolbachiatitres were significantly elevated in αMan2 knockout (KO) mosquitoes, but there were complex interactions with virus infection and replication. InWolbachia‐uninfected mosquitoes, the αMan2 KO mutation was associated with decreased DENV titres, but in aWolbachia‐infected background, the αMan2 KO mutation significantly increased virus titres. In contrast, the αMan2 KO mutation significantly increased MAYV replication inWolbachia‐uninfected mosquitoes and did not affectWolbachia‐mediated virus blocking. These results demonstrate that αMan2 modulates arbovirus infection inA. aegyptimosquitoes in a pathogen‐ andWolbachia‐specific manner, and thatWolbachia‐mediated pathogen blocking is a complex phenotype dependent on the mosquito host genotype and the pathogen. These results have a significant impact for the design and use ofWolbachia‐based strategies to control vector‐borne pathogens. 

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4. Mouse hepatitis virus JHMV I protein is required for maximal virulence

   https://doi.org/10.1128/jvi.00680-24  

   Lowery, Shea A; Schuster, Noah; Wong, Lok-Yin Roy; Carrillo, Thomas; Peters, Erin; Odle, Abby; Sariol, Alan; Cesarz, Isabella; Li, Pengfei; Perlman, Stanley (September 2024, Journal of Virology)

   Liu, Shan-Lu (Ed.)

   ABSTRACT Betacoronavirusesencode a conserved accessory gene within the +1 open reading frame (ORF) of nucleocapsid called the internal N gene. This gene is referred to as “I” for mouse hepatitis virus (MHV), ORF9b for severe acute respiratory CoV (SARS-CoV) and SARS-CoV-2, and ORF8b for Middle East respiratory syndrome CoV (MERS-CoV). Previous studies have shown ORF8b and ORF9b have immunoevasive properties, while the only known information for MHV I is its localization within the virion of the hepatotropic/neurotropic A59 strain of MHV. Whether MHV I is an innate immune antagonist or has other functions has not been evaluated. In this report, we show that the I protein of the neurotropic JHM strain of MHV (JHMV) lacks a N terminal domain present in other MHV strains, has immunoevasive properties, and is a component of the virion. Genetic deletion of JHMV I (rJHMV^IΔ57-137) resulted in a highly attenuated virus bothin vitroandin vivothat displayed a post RNA replication/transcription defect that ultimately resulted in fewer infectious virions packaged compared with wild-type virus. This phenotype was only seen for rJHMV^IΔ57-137, suggesting the structural changes predicted for A59 I altered its function, as genetic deletion of A59 I did not change viral replication or pathogenicity. Together, these data show that JHMV I both acts as a mild innate immune antagonist and aids in viral assembly and infectious virus production, and suggest that the internal N proteins from different betacoronaviruses have both common and virus strain-specific properties.IMPORTANCECoV accessory genes are largely studied in overexpression assays and have been identified as innate immune antagonists. However, functions identified after overexpression are often not confirmed in the infected animal host. Furthermore, some accessory proteins are components of the CoV virion, but their role in viral replication and release remains unclear. Here, we utilized reverse genetics to abrogate expression of a conserved CoV accessory gene, the internal N (“I”) gene, of the neurotropic JHMV strain of MHV and found that loss of the I gene resulted in a post replication defect that reduced virion assembly and ultimately infectious virus production, while also increasing some inflammatory molecule expression. Thus, the JHMV I protein has roles in virion assembly that were previously underappreciated and in immunoevasion. 

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5. Potential of a Northern Population of Aedes vexans (Diptera: Culicidae) to Transmit Zika Virus

   https://doi.org/10.1093/jme/tjx087  

   O'Donnell, Kyle L (October 2017, Journal of medical entomology)

   ika virus is an emerging arbovirus of humans in the western hemisphere. With its potential spread into new geographical areas, it is important to define the vector competence of native mosquito species. We tested the vector competency of Aedes vexans (Meigen) from the Lake Agassiz Plain of northwestern Minnesota and northeastern North Dakota. Aedes aegypti (L.) was used as a positive control for comparison. Mosquitoes were fed blood containing Zika virus and 2 wk later were tested for viral infection and dissemination. Aedes vexans (n = 60) were susceptible to midgut infection (28% infection rate) but displayed a fairly restrictive midgut escape barrier (3% dissemination rate). Cofed Ae. aegypti (n = 22) displayed significantly higher rates of midgut infection (61%) and dissemination (22%). To test virus transmission, mosquitoes were inoculated with virus and 16-17 d later, tested for their ability to transmit virus into fluid-filled capillary tubes. Unexpectedly, the transmission rate was significantly higher for Ae. vexans (34%, n = 47) than for Ae. aegypti (5%, n = 22). The overall transmission potential for Ae. vexans to transmit Zika virus was 1%. Because of its wide geographic distribution, often extreme abundance, and aggressive human biting activity, Ae. vexans could serve as a potential vector for Zika virus in northern latitudes where the conventional vectors, Ae. aegypti and Ae. albopictus Skuse, cannot survive. However, Zika virus is a primate virus and humans are the only amplifying host species in northern latitudes. To serve as a vector of Zika virus, Ae. vexans must feed repeatedly on humans. Defining the propensity of Ae. vexans to feed repeatedly on humans will be key to understanding its role as a potential vector of Zika virus. 

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