Last data update: Apr 29, 2024. (Total: 46658 publications since 2009)
Records 1-12 (of 12 Records) |
Query Trace: Guerrero LW [original query] |
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Isolation and phylogenomic analysis of Buffalopox virus from Human and Buffaloes in India.
Yadav PD , Mauldin MR , Nyayanit DA , Albarino CG , Sarkale P , Shete A , Guerrero LW , Nakazawa Y , Nichol ST , Mourya DT . Virus Res 2019 277 197836 Three genome sequences of Buffalopox virus (BPVX) were retrieved from a human and two buffaloes scab samples. Phylogenomic analysis of the BPXV indicates that it shares a most recent common ancestor with Lister and closely related vaccine strains when compared to potential wild-type VACV strains (like Horsepox virus). |
Rousette Bat Dendritic Cells Overcome Marburg Virus-Mediated Antiviral Responses by Upregulation of Interferon-Related Genes While Downregulating Proinflammatory Disease Mediators.
Prescott J , Guito JC , Spengler JR , Arnold CE , Schuh AJ , Amman BR , Sealy TK , Guerrero LW , Palacios GF , Sanchez-Lockhart M , Albarino CG , Towner JS . mSphere 2019 4 (6) Dysregulated and maladaptive immune responses are at the forefront of human diseases caused by infection with zoonotic viral hemorrhagic fever viruses. Elucidating mechanisms of how the natural animal reservoirs of these viruses coexist with these agents without overt disease, while permitting sufficient replication to allow for transmission and maintenance in a population, is important for understanding the viral ecology and spillover to humans. The Egyptian rousette bat (ERB) has been identified as a reservoir for Marburg virus (MARV), a filovirus and the etiological agent of the highly lethal Marburg virus disease. Little is known regarding how these bats immunologically respond to MARV infection. In humans, macrophages and dendritic cells (DCs) are primary targets of infection, and their dysregulation is thought to play a central role in filovirus diseases, by disturbing their normal functions as innate sensors and adaptive immune response facilitators while serving as amplification and dissemination agents for the virus. The infection status and responses to MARV in bat myeloid-lineage cells are uncharacterized and likely represent an important modulator of the bat's immune response to MARV infection. Here, we generate DCs from the bone marrow of rousette bats. Infection with a bat isolate of MARV resulted in a low level of transcription in these cells and significantly downregulated DC maturation and adaptive immune-stimulatory pathways while simultaneously upregulating interferon-related pathogen-sensing pathways. This study provides a first insight into how the bat immune response is directed toward preventing aberrant inflammatory responses while mounting an antiviral response to defend against MARV infection.IMPORTANCE Marburg viruses (MARVs) cause severe human disease resulting from aberrant immune responses. Dendritic cells (DCs) are primary targets of infection and are dysregulated by MARV. Dysregulation of DCs facilitates MARV replication and virus dissemination and influences downstream immune responses that result in immunopathology. Egyptian rousette bats (ERBs) are natural reservoirs of MARV, and infection results in virus replication and shedding, with asymptomatic control of the virus within weeks. The mechanisms that bats employ to appropriately respond to infection while avoiding disease are unknown. Because DC infection and modulation are important early events in human disease, we measured the transcriptional responses of ERB DCs to MARV. The significance of this work is in identifying cell type-specific coevolved responses between ERBs and MARV, which gives insight into how bat reservoirs are able to harbor MARV and permit viral replication, allowing transmission and maintenance in the population while simultaneously preventing immunopathogenesis. |
Antibody-mediated virus neutralization is not a universal mechanism of Marburg, Ebola or Sosuga virus clearance in Egyptian rousette bats
Schuh AJ , Amman BR , Sealy TK , Kainulainen MH , Chakrabarti AK , Guerrero LW , Nichol ST , Albarino CG , Towner JS . J Infect Dis 2018 219 (11) 1716-1721 Although bats are increasingly being recognized as natural reservoir hosts of emerging zoonotic viruses, little is known about how they control and clear virus infection in the absence of clinical disease. Here, we test >50 convalescent sera from Egyptian rousette bats (ERBs) experimentally primed or prime-boosted with Marburg virus, Ebola virus or Sosuga virus for the presence of virus-specific neutralizing antibodies using infectious reporter viruses. After serum neutralization testing, we conclude that antibody-mediated virus neutralization does not contribute significantly to the control and clearance of Marburg virus, Ebola virus or Sosuga virus infection in ERBs. |
Complete Genome Sequences of Monongahela Hantavirus from Pennsylvania, USA.
Albarino CG , Guerrero LW , Chakrabarti AK , Rollin PE , Nichol ST . Microbiol Resour Announc 2018 7 (11) Monongahela hantavirus was first identified in deer mice and was later found responsible for hantavirus pulmonary syndrome cases in Pennsylvania and West Virginia in the United States. Here, we report the complete sequences of Monongahela virus S, M, and L genomic segments obtained from a fatal clinical case reported in 1997. Copyright © 2018 Microbiology Resource Announcements. All rights reserved. |
The S Genome Segment Is Sufficient to Maintain Pathogenicity in Intra-Clade Lassa Virus Reassortants in a Guinea Pig Model.
Welch SR , Scholte FEM , Albarino CG , Kainulainen MH , Coleman-McCray JD , Guerrero LW , Chakrabarti AK , Klena JD , Nichol ST , Spengler JR , Spiropoulou CF . Front Cell Infect Microbiol 2018 8 240 Genome reassortment in Lassa virus (LASV) has been reported in nature, but phenotypic consequences of this phenomenon are not well described. Here we characterize, both in vitro and in vivo, reassortment between 2 LASV strains: the prototypic 1976 Josiah strain and a more recently isolated 2015 Liberian strain. In vitro analysis showed that although cis- and trans-acting elements of viral RNA synthesis were compatible between strains, reassortants demonstrated different levels of viral replication. These differences were also apparent in vivo, as reassortants varied in pathogenicity in the guinea pig model of LASV infection. The reassortant variant containing the Josiah S segment retained the virulence of the parental Josiah strain, but the reassortant variant containing the S segment of the Liberian isolate was highly attenuated compared to both parental strains. Contrary to observations in reassortants between LASV and other arenavirus species, which suggest that L segment-encoded factors are responsible for virulence, these studies highlight a role for S segment-encoded virulence factors in disease, and also suggest that inefficient interactions between proteins of heterologous strains may limit the prevalence of reassortant LASV variants in nature. |
Identification and characterization of novel mosquito-borne (Kammavanpettai virus) and tick-borne (Wad Medani) reoviruses isolated in India.
Yadav PD , Shete AM , Nyayanit DA , Albarino CG , Jain S , Guerrero LW , Kumar S , Patil DY , Nichol ST , Mourya DT . J Gen Virol 2018 99 (8) 991-1000 In 1954, a virus named Wad Medani virus (WMV) was isolated from Hyalomma marginatum ticks from Maharashtra State, India. In 1963, another virus was isolated from Sturnia pagodarum birds in Tamil Nadu, India, and named Kammavanpettai virus (KVPTV) based on the site of its isolation. Originally these virus isolates could not be identified with conventional methods. Here we describe next-generation sequencing studies leading to the determination of their complete genome sequences, and identification of both virus isolates as orbiviruses (family Reoviridae). Sequencing data showed that KVPTV has an AT-rich genome, whereas the genome of WMV is GC-rich. The size of the KVPTV genome is 18 234 nucleotides encoding proteins ranging 238-1290 amino acids (aa) in length. Similarly, the size of the WMV genome is 16 941 nucleotides encoding proteins ranging 214-1305 amino acids in length. Phylogenetic analysis of the VP1 gene, along with the capsid genes VP5 and VP7, revealed that KVPTV is likely a novel mosquito-borne virus and WMV is a tick-borne orbivirus. This study focuses on the phylogenetic comparison of these newly identified orbiviruses with mosquito-, tick- and Culicoides-borne orbiviruses isolated in India and other countries. |
Lassa and Ebola virus inhibitors identified using minigenome and recombinant virus reporter systems.
Welch SR , Guerrero LW , Chakrabarti AK , McMullan LK , Flint M , Bluemling GR , Painter GR , Nichol ST , Spiropoulou CF , Albarino CG . Antiviral Res 2016 136 9-18 Lassa virus (LASV) and Ebola virus (EBOV) infections are important global health issues resulting in significant morbidity and mortality. While several promising drug and vaccine trials for EBOV are ongoing, options for LASV infection are currently limited to ribavirin treatment. A major factor impeding the development of antiviral compounds to treat these infections is the need to manipulate the virus under BSL-4 containment, limiting research to a few institutes worldwide. Here we describe the development of a novel LASV minigenome assay based on the ambisense LASV S segment genome, with authentic terminal untranslated regions flanking a ZsGreen (ZsG) fluorescent reporter protein and a Gaussia princeps luciferase (gLuc) reporter gene. This assay, along with a similar previously established EBOV minigenome, was optimized for high-throughput screening (HTS) of potential antiviral compounds under BSL-2 containment. In addition, we rescued a recombinant LASV expressing ZsG, which, in conjunction with a recombinant EBOV reporter virus, was used to confirm any potential antiviral hits in vitro. Combining an initial screen to identify potential antiviral compounds at BSL-2 containment before progressing to HTS with infectious virus will reduce the amount of expensive and technically challenging BSL-4 containment research. Using these assays, we identified 6-azauridine as having anti-LASV activity, and demonstrated its anti-EBOV activity in human cells. We further identified 2'-deoxy-2'-fluorocytidine as having potent anti-LASV activity, with an EC50 value 10 times lower than that of ribavirin. |
Ebola Virus Disease Diagnostics, Sierra Leone: Analysis of Real-time Reverse Transcription-Polymerase Chain Reaction Values for Clinical Blood and Oral Swab Specimens.
Erickson BR , Sealy TK , Flietstra T , Morgan L , Kargbo B , Matt-Lebby VE , Gibbons A , Chakrabarti AK , Graziano J , Presser L , Flint M , Bird BH , Brown S , Klena JD , Blau DM , Brault AC , Belser JA , Salzer JS , Schuh AJ , Lo M , Zivcec M , Priestley RA , Pyle M , Goodman C , Bearden S , Amman BR , Basile A , Bergeron E , Bowen MD , Dodd KA , Freeman MM , McMullan LK , Paddock CD , Russell BJ , Sanchez AJ , Towner JS , Wang D , Zemtsova GE , Stoddard RA , Turnsek M , Guerrero LW , Emery SL , Stovall J , Kainulainen MH , Perniciaro JL , Mijatovic-Rustempasic S , Shakirova G , Winter J , Sexton C , Liu F , Slater K , Anderson R , Andersen L , Chiang CF , Tzeng WP , Crowe SJ , Maenner MJ , Spiropoulou CF , Nichol ST , Stroher U . J Infect Dis 2016 214 S258-S262 During the Ebola virus outbreak of 2013-2016, the Viral Special Pathogens Branch field laboratory in Sierra Leone tested approximately 26 000 specimens between August 2014 and October 2015. Analysis of the B2M endogenous control Ct values showed its utility in monitoring specimen quality, comparing results with different specimen types, and interpretation of results. For live patients, blood is the most sensitive specimen type and oral swabs have little diagnostic utility. However, swabs are highly sensitive for diagnostic testing of corpses. |
Virus fitness differences observed between two naturally occurring isolates of Ebola virus Makona variant using a reverse genetics approach.
Albarino CG , Guerrero LW , Chakrabarti AK , Kainulainen MH , Whitmer SL , Welch SR , Nichol ST . Virology 2016 496 237-243 During the large outbreak of Ebola virus disease that occurred in Western Africa from late 2013 to early 2016, several hundred Ebola virus (EBOV) genomes have been sequenced and the virus genetic drift analyzed. In a previous report, we described an efficient reverse genetics system designed to generate recombinant EBOV based on a Makona variant isolate obtained in 2014. Using this system, we characterized the replication and fitness of 2 isolates of the Makona variant. These virus isolates are nearly identical at the genetic level, but have single amino acid differences in the VP30 and L proteins. The potential effects of these differences were tested using minigenomes and recombinant viruses. The results obtained with this approach are consistent with the role of VP30 and L as components of the EBOV RNA replication machinery. Moreover, the 2 isolates exhibited clear fitness differences in competitive growth assays. |
Assessment of Inhibitors of Pathogenic Crimean-Congo Hemorrhagic Fever Virus Strains Using Virus-Like Particles.
Zivcec M , Metcalfe MG , Albarino CG , Guerrero LW , Pegan SD , Spiropoulou CF , Bergeron E . PLoS Negl Trop Dis 2015 9 (12) e0004259 Crimean-Congo hemorrhagic fever (CCHF) is an often lethal, acute inflammatory illness that affects a large geographic area. The disease is caused by infection with CCHF virus (CCHFV), a nairovirus from the Bunyaviridae family. Basic research on CCHFV has been severely hampered by biosafety requirements and lack of available strains and molecular tools. We report the development of a CCHF transcription- and entry-competent virus-like particle (tecVLP) system that can be used to study cell entry and viral transcription/replication over a broad dynamic range (~4 orders of magnitude). The tecVLPs are morphologically similar to authentic CCHFV. Incubation of immortalized and primary human cells with tecVLPs results in a strong reporter signal that is sensitive to treatment with neutralizing monoclonal antibodies and by small molecule inhibitors of CCHFV. We used glycoproteins and minigenomes from divergent CCHFV strains to generate tecVLPs, and in doing so, we identified a monoclonal antibody that can prevent cell entry of tecVLPs containing glycoproteins from 3 pathogenic CCHFV strains. In addition, our data suggest that different glycoprotein moieties confer different cellular entry efficiencies, and that glycoproteins from the commonly used strain IbAr10200 have up to 100-fold lower ability to enter primary human cells compared to glycoproteins from pathogenic CCHFV strains. |
Ebola virus diagnostics: the US Centers for Disease Control and Prevention laboratory in Sierra Leone, August 2014 to March 2015
Flint M , Goodman CH , Bearden S , Blau DM , Amman BR , Basile AJ , Belser JA , Bergeron E , Bowen MD , Brault AC , Campbell S , Chakrabarti AK , Dodd KA , Erickson BR , Freeman MM , Gibbons A , Guerrero LW , Klena JD , Lash RR , Lo MK , McMullan LK , Momoh G , Massally JL , Goba A , Paddock CD , Priestley RA , Pyle M , Rayfield M , Russell BJ , Salzer JS , Sanchez AJ , Schuh AJ , Sealy TK , Steinau M , Stoddard RA , Taboy C , Turnsek M , Wang D , Zemtsova GE , Zivcec M , Spiropoulou CF , Stroher U , Towner JS , Nichol ST , Bird BH . J Infect Dis 2015 212 Suppl 2 S350-8 In August 2014, the Viral Special Pathogens Branch of the US Centers for Disease Control and Prevention established a field laboratory in Sierra Leone in response to the ongoing Ebola virus outbreak. Through March 2015, this laboratory tested >12 000 specimens from throughout Sierra Leone. We describe the organization and procedures of the laboratory located in Bo, Sierra Leone. |
Andes hantavirus variant in rodents, southern Amazon Basin, Peru
Razuri H , Tokarz R , Ghersi BM , Salmon-Mulanovich G , Guezala MC , Albujar C , Mendoza AP , Tinoco YO , Cruz C , Silva M , Vasquez A , Pacheco V , Stroher U , Guerrero LW , Cannon D , Nichol ST , Hirschberg DL , Lipkin WI , Bausch DG , Montgomery JM . Emerg Infect Dis 2014 20 (2) 257-60 We investigated hantaviruses in rodents in the southern Amazon Basin of Peru and identified an Andes virus variant from Neacomys spinosus mice. This finding extends the known range of this virus in South America and the range of recognized hantaviruses in Peru. Further studies of the epizoology of hantaviruses in this region are warranted. |
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