Your search keyword '"Suman R. Das"' showing total 10 results

1. Influence of Sex on Respiratory Syncytial Virus Genotype Infection Frequency and Nasopharyngeal Microbiome

Author

Yi Tan, Meghan H. Shilts, Christian Rosas-Salazar, Vinita Puri, Nadia Fedorova, Rebecca A. Halpin, Siyuan Ma, Larry J. Anderson, R. Stokes Peebles, Tina V. Hartert, and Suman R. Das

Subjects

Virology, Insect Science, Immunology, Microbiology

Abstract

Respiratory syncytial virus (RSV) is one of the leading causes of lower respiratory tract infections in young children and is responsible for high hospitalization rates and morbidity in infants and the elderly. To understand how the emergence of RSV viral genotypes and viral-respiratory microbiome interactions contribute to infection frequency and severity, we utilized an observational cohort designed to capture the first infant RSV infection we employed multi-omics approaches to sequence 349 RSV complete genomes and matched nasopharyngeal microbiomes.

Published

2023

2. Mucosal Gene Expression in Response to SARS-CoV-2 Is Associated with Viral Load

Author

Seesandra V. Rajagopala, Britton A. Strickland, Suman B. Pakala, Kyle S. Kimura, Meghan H. Shilts, Christian Rosas-Salazar, Hunter M. Brown, Michael H. Freeman, Bronson C. Wessinger, Veerain Gupta, Elizabeth Phillips, Simon A. Mallal, Justin H. Turner, and Suman R. Das

Subjects

Virology, Insect Science, Immunology, Microbiology

Abstract

Several prior studies have shown that SARS-CoV-2 viral load can predict the likelihood of disease spread and severity. A higher detectable SARS-CoV-2 plasma viral load was associated with worse respiratory disease severity.

Published

2023

3. Deep Sequencing of Influenza A Virus from a Human Challenge Study Reveals a Selective Bottleneck and Only Limited Intrahost Genetic Diversification

Author

Timothy B. Stockwell, Micah T. McClain, Amy Ransier, Katia Koelle, Christopher W. Woods, Rebecca A. Halpin, Gavin J. D. Smith, Anthony Gilbert, Suman R. Das, Xudong Lin, Ashley Sobel Leonard, Geoffrey S. Ginsburg, Rob Lambkin-Williams, and David E. Wentworth

Subjects

0301 basic medicine, Nonsynonymous substitution, Zygote, viruses, Immunology, Genome, Viral, Biology, medicine.disease_cause, Microbiology, Virus, Deep sequencing, Evolution, Molecular, 03 medical and health sciences, Virology, Influenza, Human, Genetic variation, Influenza A virus, medicine, Animals, Humans, Selection, Genetic, Spotlight, Genetics, Genetic diversity, Models, Genetic, Influenza A Virus, H3N2 Subtype, Genetic Variation, High-Throughput Nucleotide Sequencing, Nucleoprotein, 030104 developmental biology, Genetic Diversity and Evolution, Insect Science, Viral evolution, RNA, Viral, Chickens

Abstract

Knowledge of influenza virus evolution at the point of transmission and at the intrahost level remains limited, particularly for human hosts. Here, we analyze a unique viral data set of next-generation sequencing (NGS) samples generated from a human influenza challenge study wherein 17 healthy subjects were inoculated with cell- and egg-passaged virus. Nasal wash samples collected from 7 of these subjects were successfully deep sequenced. From these, we characterized changes in the subjects' viral populations during infection and identified differences between the virus in these samples and the viral stock used to inoculate the subjects. We first calculated pairwise genetic distances between the subjects' nasal wash samples, the viral stock, and the influenza virus A/Wisconsin/67/2005 (H3N2) reference strain used to generate the stock virus. These distances revealed that considerable viral evolution occurred at various points in the human challenge study. Further quantitative analyses indicated that (i) the viral stock contained genetic variants that originated and likely were selected for during the passaging process, (ii) direct intranasal inoculation with the viral stock resulted in a selective bottleneck that reduced nonsynonymous genetic diversity in the viral hemagglutinin and nucleoprotein, and (iii) intrahost viral evolution continued over the course of infection. These intrahost evolutionary dynamics were dominated by purifying selection. Our findings indicate that rapid viral evolution can occur during acute influenza infection in otherwise healthy human hosts when the founding population size of the virus is large, as is the case with direct intranasal inoculation. IMPORTANCE Influenza viruses circulating among humans are known to rapidly evolve over time. However, little is known about how influenza virus evolves across single transmission events and over the course of a single infection. To address these issues, we analyze influenza virus sequences from a human challenge experiment that initiated infection with a cell- and egg-passaged viral stock, which appeared to have adapted during its preparation. We find that the subjects' viral populations differ genetically from the viral stock, with subjects' viral populations having lower representation of the amino-acid-changing variants that arose during viral preparation. We also find that most of the viral evolution occurring over single infections is characterized by further decreases in the frequencies of these amino-acid-changing variants and that only limited intrahost genetic diversification through new mutations is apparent. Our findings indicate that influenza virus populations can undergo rapid genetic changes during acute human infections.

Published

2016

4. Introduction, Evolution, and Dissemination of Influenza A Viruses in Exhibition Swine in the United States during 2009 to 2013

Author

David E. Wentworth, Andrew S. Bowman, Suman R. Das, Mary Lea Killian, Martha I. Nelson, Nídia S. Trovão, Sarah W. Nelson, Karla M. Stucker, Srinand Sreevatsan, Vivien G. Dugan, Seth Schobel, and Jacqueline M. Nolting

Subjects

0301 basic medicine, Swine, viruses, Sus scrofa, Immunology, Population, Biology, medicine.disease_cause, Microbiology, Virus, Evolution, Molecular, Exhibition, 03 medical and health sciences, Orthomyxoviridae Infections, Virology, Pandemic, Reassortant Viruses, Influenza A virus, medicine, Animals, Humans, education, Phylogeny, Swine Diseases, education.field_of_study, Transmission (medicine), Influenza A Virus, H3N2 Subtype, Bayes Theorem, United States, 030104 developmental biology, Genetic Diversity and Evolution, Insect Science, Viral evolution

Abstract

The swine-human interface created at agricultural fairs, along with the generation of and maintenance of influenza A virus diversity in exhibition swine, presents an ongoing threat to public health. Nucleotide sequences of influenza A virus isolates collected from exhibition swine in Ohio ( n = 262) and Indiana ( n = 103) during 2009 to 2013 were used to investigate viral evolution and movement within this niche sector of the swine industry. Phylogenetic and Bayesian analyses were employed to identify introductions of influenza A virus to exhibition swine and study viral population dynamics. In 2013 alone, we identified 10 independent introductions of influenza A virus into Ohio and/or Indiana exhibition swine. Frequently, viruses from the same introduction were identified at multiple fairs within the region, providing evidence of rapid and widespread viral movement within the exhibition swine populations of the two states. While pigs moving from fair to fair to fair is possible in some locations, the concurrent detection of nearly identical strains at several fairs indicates that a common viral source was more likely. Importantly, we detected an association between the high number of human variant H3N2 (H3N2v) virus infections in 2012 and the widespread circulation of influenza A viruses of the same genotype in exhibition swine in Ohio fairs sampled that year. The extent of viral diversity observed in exhibition swine and the rapidity with which it disseminated across long distances indicate that novel strains of influenza A virus will continue to emerge and spread within exhibition swine populations, presenting an ongoing threat to humans. IMPORTANCE Understanding the underlying population dynamics of influenza A viruses in commercial and exhibition swine is central to assessing the risk for human infections with variant viruses, including H3N2v. We used viral genomic sequences from isolates collected from exhibition swine during 2009 to 2013 to understand how the peak of H3N2v cases in 2012 relates to long-term trends in the population dynamics of pandemic viruses recently introduced into commercial and exhibition swine in the United States. The results of our spatial analysis underscore the key role of rapid viral dispersal in spreading multiple genetic lineages throughout a multistate network of agricultural fairs, providing opportunities for divergent lineages to coinfect, reassort, and generate new viral genotypes. The higher genetic diversity of genotypes cocirculating in exhibition swine since 2013 could facilitate the evolution of new reassortants, potentially with even greater ability to cause severe infections in humans or cause human-to-human transmission, highlighting the need for continued vigilance.

Published

2016

5. Multiple Introductions and Antigenic Mismatch with Vaccines May Contribute to Increased Predominance of G12P[8] Rotaviruses in the United States

Author

Mathew D. Esona, James D. Chappell, Meghan H. Shilts, Christopher Fonnesbeck, Slavica Mijatovic-Rustempasic, Nadia Fedorova, Rendie McHenry, John T. Patton, Daniel C. Payne, Yi Tan, Natasha B. Halasa, Asmik Akopov, Rebecca A. Halpin, Kathryn M. Edwards, Laura S Stewart, Suman R. Das, Bhinnata Piya, Maximilian H. Carter, and Kristen M. Ogden

Subjects

Rotavirus, Genotyping Techniques, viruses, Immunology, medicine.disease_cause, Microbiology, Epitope, Rotavirus Infections, 03 medical and health sciences, Immune system, fluids and secretions, Antigen, Virology, Genotype, medicine, Humans, Antigens, Viral, Phylogeny, 030304 developmental biology, 0303 health sciences, biology, 030306 microbiology, Sequence Analysis, RNA, Rotavirus Vaccines, virus diseases, Infant, Rotavirus vaccine, United States, Vaccination, Genetic Diversity and Evolution, Insect Science, Child, Preschool, Population Surveillance, biology.protein, Capsid Proteins, Antibody

Abstract

Rotavirus is the leading global cause of diarrheal mortality for unvaccinated children under 5 years of age. The outer capsid of rotavirus virions consists of VP7 and VP4 proteins, which determine viral G and P types, respectively, and are primary targets of neutralizing antibodies. Successful vaccination depends upon generating broadly protective immune responses following exposure to rotaviruses presenting a limited number of G- and P-type antigens. Vaccine introduction resulted in decreased rotavirus disease burden but also coincided with the emergence of uncommon G and P genotypes, including G12. To gain insight into the recent predominance of G12P[8] rotaviruses in the United States, we evaluated 142 complete rotavirus genome sequences and metadata from 151 clinical specimens collected in Nashville, TN, from 2011 to 2013 through the New Vaccine Surveillance Network. Circulating G12P[8] strains were found to share many segments with other locally circulating strains but to have distinct constellations. Phylogenetic analyses of G12 sequences and their geographic sources provided evidence for multiple separate introductions of G12 segments into Nashville, TN. Antigenic epitopes of VP7 proteins of G12P[8] strains circulating in Nashville, TN, differ markedly from those of vaccine strains. Fully vaccinated children were found to be infected with G12P[8] strains more frequently than with other rotavirus genotypes. Multiple introductions and significant antigenic mismatch may in part explain the recent predominance of G12P[8] strains in the United States and emphasize the need for continued monitoring of rotavirus vaccine efficacy against emerging rotavirus genotypes. IMPORTANCE Rotavirus is an important cause of childhood diarrheal disease worldwide. Two immunodominant proteins of rotavirus, VP7 and VP4, determine G and P genotypes, respectively. Recently, G12P[8] rotaviruses have become increasingly predominant. By analyzing rotavirus genome sequences from stool specimens obtained in Nashville, TN, from 2011 to 2013 and globally circulating rotaviruses, we found evidence of multiple introductions of G12 genes into the area. Based on sequence polymorphisms, VP7 proteins of these viruses are predicted to present themselves to the immune system very differently than those of vaccine strains. Many of the sick children with G12P[8] rotavirus in their diarrheal stools also were fully vaccinated. Our findings emphasize the need for continued monitoring of circulating rotaviruses and the effectiveness of the vaccines against strains with emerging G and P genotypes.

Published

2018

6. Large-Scale Complete-Genome Sequencing and Phylodynamic Analysis of Eastern Equine Encephalitis Virus Reveals Source-Sink Transmission Dynamics in the United States

Author

Albert J. Auguste, Suman R. Das, Scott Hennigan, Thomas R. Unnasch, Alexander T. Ciota, Meghan H. Shilts, Lea Heberlein-Larson, Sandra Smole, Vinita Puri, Theodore G. Andreadis, Philip M. Armstrong, Laura D. Kramer, Scott C. Weaver, Nadia Fedorova, Timothy B. Stockwell, Robert B. Tesh, Tommy Tsan-Yuk Lam, Rebecca A. Halpin, and Yi Tan

Subjects

Encephalomyelitis, Equine, 0301 basic medicine, Eastern equine encephalitis virus, Immunology, New York, Zoology, Genome, Viral, Biology, medicine.disease_cause, Microbiology, Genome, 03 medical and health sciences, Genome Size, Virology, medicine, Animals, Horses, Phylogeny, Whole genome sequencing, Genetic diversity, Whole Genome Sequencing, Phylogenetic tree, Genetic Variation, High-Throughput Nucleotide Sequencing, Phylogeography, 030104 developmental biology, Viral phylodynamics, Genetic Diversity and Evolution, Massachusetts, Insect Science, Florida, Encephalitis Virus, Eastern Equine, Enzootic

Abstract

Eastern equine encephalitis virus (EEEV) has a high case-fatality rate in horses and humans, and Florida has been hypothesized to be the source of EEEV epidemics for the northeastern United States. To test this hypothesis, we sequenced complete genomes of 433 EEEV strains collected within the United States from 1934 to 2014. Phylogenetic analysis suggested EEEV evolves relatively slowly and that transmission is enzootic in Florida, characterized by higher genetic diversity and long-term local persistence. In contrast, EEEV strains in New York and Massachusetts were characterized by lower genetic diversity, multiple introductions, and shorter local persistence. Our phylogeographic analysis supported a source-sink model in which Florida is the major source of EEEV compared to the other localities sampled. In sum, this study revealed the complex epidemiological dynamics of EEEV in different geographic regions in the United States and provided general insights into the evolution and transmission of other avian mosquito-borne viruses in this region. IMPORTANCE Eastern equine encephalitis virus (EEEV) infections are severe in horses and humans on the east coast of the United States with a >90% mortality rate in horses, an ∼33% mortality rate in humans, and significant brain damage in most human survivors. However, little is known about the evolutionary characteristics of EEEV due to the lack of genome sequences. By generating large collection of publicly available complete genome sequences, this study comprehensively determined the evolution of the virus, described the epidemiological dynamics of EEEV in different states in the United States, and identified Florida as one of the major sources. These results may have important implications for the control and prevention of other mosquito-borne viruses in the Americas.

Published

2018

7. Diversifying Selection Analysis Predicts Antigenic Evolution of 2009 Pandemic H1N1 Influenza A Virus in Humans

Author

Ann R. Falsey, Brian D. Aevermann, Suman R. Das, Theresa Fitzgerald, David J. Topham, Richard H. Scheuermann, Brett E. Pickett, Wei Wang, and Alexandra J. Lee

Subjects

Adult, Male, Models, Molecular, Immunology, Hemagglutinin (influenza), Hemagglutinin Glycoproteins, Influenza Virus, Biology, medicine.disease_cause, Microbiology, Virus, Epitope, Antigenic drift, Evolution, Molecular, Young Adult, Influenza A Virus, H1N1 Subtype, Virology, Influenza, Human, Influenza A virus, medicine, Humans, Selection, Genetic, Original antigenic sin, Antigens, Viral, Pandemics, Phylogeny, Aged, Genetics, Middle Aged, Acquired immune system, Genetic Diversity and Evolution, Insect Science, Viral evolution, Mutation, biology.protein, Epitopes, B-Lymphocyte, Female

Abstract

Although a large number of immune epitopes have been identified in the influenza A virus (IAV) hemagglutinin (HA) protein using various experimental systems, it is unclear which are involved in protective immunity to natural infection in humans. We developed a data mining approach analyzing natural H1N1 human isolates to identify HA protein regions that may be targeted by the human immune system and can predict the evolution of IAV. We identified 16 amino acid sites experiencing diversifying selection during the evolution of prepandemic seasonal H1N1 strains and found that 11 sites were located in experimentally determined B-cell/antibody (Ab) epitopes, including three distinct neutralizing Caton epitopes: Sa, Sb, and Ca2 [A. J. Caton, G. G. Brownlee, J. W. Yewdell, and W. Gerhard, Cell 31:417–427, 1982, http://dx.doi.org/10.1016/0092-8674(82)90135-0 ]. We predicted that these diversified epitope regions would be the targets of mutation as the 2009 H1N1 pandemic (pH1N1) lineage evolves in response to the development of population-level protective immunity in humans. Using a chi-squared goodness-of-fit test, we identified 10 amino acid sites that significantly differed between the pH1N1 isolates and isolates from the recent 2012-2013 and 2013-2014 influenza seasons. Three of these sites were located in the same diversified B-cell/Ab epitope regions as identified in the analysis of prepandemic sequences, including Sa and Sb. As predicted, hemagglutination inhibition (HI) assays using human sera from subjects vaccinated with the initial pH1N1 isolate demonstrated reduced reactivity against 2013-2014 isolates. Taken together, these results suggest that diversifying selection analysis can identify key immune epitopes responsible for protective immunity to influenza virus in humans and thereby predict virus evolution. IMPORTANCE The WHO estimates that approximately 5 to 10% of adults and 20 to 30% of children in the world are infected by influenza virus each year. While an adaptive immune response helps eliminate the virus following acute infection, the virus rapidly evolves to evade the established protective memory immune response, thus allowing for the regular seasonal cycles of influenza virus infection. The analytical approach described here, which combines an analysis of diversifying selection with an integration of immune epitope data, has allowed us to identify antigenic regions that contribute to protective immunity and are therefore the key targets of immune evasion by the virus. This information can be used to determine when sequence variations in seasonal influenza virus strains have affected regions responsible for protective immunity in order to decide when new vaccine formulations are warranted.

Published

2014

8. Spread and persistence of influenza A viruses in waterfowl hosts in the North American Mississippi migratory flyway

Author

H. Lisle Gibbs, Xudong Lin, Anthony C. Fries, Timothy B. Stockwell, Jacqueline M. Nolting, David E. Wentworth, Rebecca A. Halpin, Nadia Fedorova, Andrew S. Bowman, Richard D. Slemons, Vivien G. Dugan, Eric Wester, and Suman R. Das

Subjects

Gene Flow, Disease reservoir, Genes, Viral, animal diseases, Immunology, Reassortment, Bird migration, Microbiology, Mississippi, Rivers, Virology, Flyway, Anseriformes, Waterfowl, Animals, Humans, Panzootic, Disease Reservoirs, biology, Ecology, virus diseases, Genetic Variation, biology.organism_classification, Phylogeography, Genetic Diversity and Evolution, Influenza A virus, Insect Science, Host-Pathogen Interactions, North America, Biological dispersal, Animal Migration, Seasons, Environmental Monitoring

Abstract

While geographic distance often restricts the spread of pathogens via hosts, this barrier may be compromised when host species are mobile. Migratory waterfowl in the order Anseriformes are important reservoir hosts for diverse populations of avian-origin influenza A viruses (AIVs) and are assumed to spread AIVs during their annual continental-scale migrations. However, support for this hypothesis is limited, and it is rarely tested using data from comprehensive surveillance efforts incorporating both the temporal and spatial aspects of host migratory patterns. We conducted intensive AIV surveillance of waterfowl using the North American Mississippi Migratory Flyway (MMF) over three autumn migratory seasons. Viral isolates ( n = 297) from multiple host species were sequenced and analyzed for patterns of gene dispersal between northern staging and southern wintering locations. Using a phylogenetic and nucleotide identity framework, we observed a larger amount of gene dispersal within this flyway rather than between the other three longitudinally identified North American flyways. Across seasons, we observed patterns of regional persistence of diversity for each genomic segment, along with limited survival of dispersed AIV gene lineages. Reassortment increased with both time and distance, resulting in transient AIV constellations. This study shows that within the MMF, AIV gene flow favors spread along the migratory corridor within a season, and also that intensive surveillance during bird migration is important for identifying virus dispersal on time scales relevant to pandemic responsiveness. In addition, this study indicates that comprehensive monitoring programs to capture AIV diversity are critical for providing insight into AIV evolution and ecology in a major natural reservoir. IMPORTANCE Migratory birds are a reservoir for antigenic and genetic diversity of influenza A viruses (AIVs) and are implicated in the spread of virus diversity that has contributed to previous pandemic events. Evidence for dispersal of avian-origin AIVs by migratory birds is rarely examined on temporal scales relevant to pandemic or panzootic threats. Therefore, characterizing AIV movement by hosts within a migratory season is important for implementing effective surveillance strategies. We conducted surveillance following birds along a major North American migratory route and observed that within a migratory season, AIVs rapidly reassorted and gene lineages were dispersed primarily within the migratory corridor. Patterns of regional persistence were observed across seasons for each gene segment. We show that dispersal of AIV gene lineages by migratory birds occurs quickly along migratory routes and that surveillance for AIVs threatening human and animal health should focus attention on these routes.

Published

2014

9. Influenza A virus hemagglutinin trimerization completes monomer folding and antigenicity

Author

Suman R. Das, James Stevens, Gregory M. Frank, Hana Golding, Javier G. Magadán, Jonathan W. Yewdell, Jack R. Bennink, and Surender Khurana

Subjects

Models, Molecular, Antigenicity, Protein Folding, Immunology, Hemagglutinin (influenza), Trimer, Hemagglutinin Glycoproteins, Influenza Virus, Antibodies, Viral, Microbiology, Epitope, Antigenic drift, Cell Line, Epitopes, Mice, Protein structure, Dogs, Virology, Vaccines and Antiviral Agents, Animals, Humans, Protein Structure, Quaternary, Antigens, Viral, biology, Immunogenicity, Antibodies, Monoclonal, Molecular biology, Cell biology, Influenza A virus, Insect Science, biology.protein, Protein folding

Abstract

Influenza A virus (IAV) remains an important human pathogen largely because of antigenic drift, the rapid emergence of antibody escape mutants that precludes durable vaccination. The most potent neutralizing antibodies interact with cognate epitopes in the globular “head” domain of hemagglutinin (HA), a homotrimeric glycoprotein. The H1 HA possesses five distinct regions defined by a large number of mouse monoclonal antibodies (MAbs), i.e., Ca1, Ca2, Cb, Sa, and Sb. Ca1-Ca2 sites require HA trimerization to attain full antigenicity, consistent with their locations on opposite sides of the trimer interface. Here, we show that full antigenicity of Cb and Sa sites also requires HA trimerization, as revealed by immunofluorescence microscopy of IAV-infected cells and biochemically by pulse-chase radiolabeling experiments. Surprisingly, epitope antigenicity acquired by HA trimerization persists following acid triggering of the globular domains dissociation and even after proteolytic release of monomeric heads from acid-treated HA. Thus, the requirement for HA trimerization by trimer-specific MAbs mapping to the Ca, Cb, and Sa sites is not dependent upon the bridging of adjacent monomers in the native HA trimer. Rather, complete antigenicity of HA (and, by inference, immunogenicity) requires a final folding step that accompanies its trimerization. Once this conformational change occurs, HA trimers themselves would not necessarily be required to induce a highly diverse neutralizing response to epitopes in the globular domain.

Published

2013

10. UPF1 is crucial for the infectivity of human immunodeficiency virus type 1 progeny virions

Author

Christian K. Roy, Suman R. Das, Heinrich G. Göttlinger, Elena Popova, Ogooluwa A. Ojelabi, and Anna Kristina P. Serquiña

Subjects

Infectivity, Subfamily, biology, Immunology, Helicase, Endogeny, Virus Replication, Microbiology, Virology, Reverse transcriptase, Cofactor, Virus-Cell Interactions, Viral replication, Insect Science, Host-Pathogen Interactions, biology.protein, HIV-1, Trans-Activators, Humans, Mutant Proteins, RNA Helicases

Abstract

The SF1 helicase MOV10 is an antiviral factor that is incorporated into human immunodeficiency virus type 1 (HIV-1) virions. We now report that HIV-1 virions also incorporate UPF1, which belongs to the same SF1 helicase subfamily as MOV10 and functions in the nonsense-mediated decay (NMD) pathway. Unlike ectopic MOV10, the overexpression of UPF1 does not impair the infectivity of HIV-1 progeny virions. However, UPF1 becomes a potent inhibitor of HIV-1 progeny virion infectivity when residues required for its helicase activity are mutated. In contrast, equivalent mutations abolish the antiviral activity of MOV10. Importantly, cells depleted of endogenous UPF1, but not of another NMD core component, produce HIV-1 virions of substantially lower specific infectivity. The defect is at the level of reverse transcription, the same stage of the HIV-1 life cycle inhibited by ectopic MOV10. Thus, whereas ectopic MOV10 restricts HIV-1 replication, the related UPF1 helicase functions as a cofactor at an early postentry step.

Published

2013