Last data update: Nov 04, 2024. (Total: 48056 publications since 2009)
Records 1-11 (of 11 Records) |
Query Trace: Hatta M[original query] |
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Transmission of a human isolate of clade 2.3.4.4b A(H5N1) virus in ferrets
Pulit-Penaloza JA , Belser JA , Brock N , Kieran TJ , Sun X , Pappas C , Zeng H , Carney P , Chang J , Bradley-Ferrell B , Stevens J , De La Cruz JA , Hatta Y , Di H , Davis CT , Tumpey TM , Maines TR . Nature 2024 Since 2020, there has been unprecedented global spread of highly pathogenic avian influenza A(H5N1) in wild bird populations with spillover into a variety of mammalian species and sporadically humans(1). In March 2024, clade 2.3.4.4b A(H5N1) virus was first detected in dairy cattle in the U.S., with subsequent detection in numerous states(2), leading to over a dozen confirmed human cases(3,4). In this study, we employed the ferret model, a well-characterized species that permits concurrent investigation of viral pathogenicity and transmissibility(5) in the evaluation of A/Texas/37/2024 (TX/37) A(H5N1) virus isolated from a dairy farm worker in Texas(6). Here, we show that the virus has a remarkable ability for robust systemic infection in ferrets, leading to high levels of virus shedding and spread to naïve contacts. Ferrets inoculated with TX/37 rapidly exhibited a severe and fatal infection, characterized by viremia and extrapulmonary spread. The virus efficiently transmitted in a direct contact setting and was capable of indirect transmission via fomites. Airborne transmission was corroborated by the detection of infectious virus shed into the air by infected animals, albeit at lower levels compared to the highly transmissible human seasonal and swine-origin H1 subtype strains. Our results show that despite maintaining an avian-like receptor binding specificity, TX/37 displays heightened virulence, transmissibility, and airborne shedding relative to other clade 2.3.4.4b virus isolated prior to the 2024 cattle outbreaks(7), underscoring the need for continued public health vigilance. |
Interferon as an immunoadjuvant to enhance antibodies following influenza B infection and vaccination in ferrets
Rowe T , Fletcher A , Svoboda P , Pohl J , Hatta Y , Jasso G , Wentworth DE , Ross TM . NPJ Vaccines 2024 9 (1) 199 Despite annual vaccination, influenza B viruses (IBV) continue to cause significant morbidity and mortality in humans. We have found that IBV infection resulted in a weaker innate and adaptive immune response than influenza A viruses (IAV) in ferrets. To understand and overcome the weak immune responses to IBV in ferrets, we administered type-I or type-III interferon (IFN) to ferrets following infection or vaccination and evaluated their effects on the immune response. IFN signaling following viral infection plays an important role in the initial innate immune response and affects subsequent adaptive immune responses. In the respiratory tract, IFN lambda (IFNL) has regulatory effects on adaptive immunity indirectly through thymic stromal lymphopoietin (TSLP), which then acts on immune cells to stimulate the adaptive response. Following IBV infection or vaccination, IFN treatment (IFN-Tx) upregulated gene expression of early inflammatory responses in the upper respiratory tract and robust IFN, TSLP, and inflammatory responses in peripheral blood cells. These responses were sustained following challenge or vaccination in IFN-Tx animals. Serum IFNL and TSLP levels were enhanced in IFN-Tx animals following challenge/rechallenge over mock-Tx; however, this difference was not observed following vaccination. Antibody responses in serum of IFN-Tx animals following IBV infection or vaccination increased more quickly and to higher titers and were sustained longer than mock-Tx animals over 3 months. Following rechallenge of infected animals 3 months post treatment, antibody levels remained higher than mock-Tx. However, IFN-Tx did not have an effect on antibody responses following challenge of vaccinated animals. A strong direct correlation was found between TSLP levels and antibody responses following challenge-rechallenge and vaccination-challenge indicating it as a useful tool for predicting adaptive immune responses following IBV infection or vaccination. The effects of IFN on strengthening both innate and adaptive responses to IBV may aid in development of more effective treatments following infection and improved influenza vaccines. |
Robustness of the ferret model for influenza risk assessment studies: a cross-laboratory exercise (preprint)
Belser JA , Lau EHY , Barclay W , Barr IG , Chen H , Fouchier RAM , Hatta M , Herfst S , Kawaoka Y , Lakdawala SS , Lee LYY , Neumann G , Peiris M , Perez DR , Russell C , Subbarao K , Sutton TC , Webby RJ , Yang H , Yen HL . bioRxiv 2022 2022.04.02.486825 Ferrets represent the preferred animal model for assessing the transmission potential of newly emerged zoonotic influenza viruses. However, heterogeneity among established experimental protocols and facilities across different laboratories may lead to variable results, complicating interpretation of transmission experimental data. Between 2018-2020, a global exercise was conducted by 11 participating laboratories to assess the range of variation in ferret transmission experiments using two common stock H1N1 influenza viruses that possess different transmission characteristics in ferrets. Inoculation route, dose, and volume were standardized, and all participating laboratories followed the same experimental conditions for respiratory droplet transmission, including a strict 1:1 donor:contact ratio. Additional host and environmental parameters likely to affect influenza transmission kinetics were monitored throughout. Overall transmission outcomes for both viruses across 11 laboratories were concordant, suggesting the robustness of the ferret model for zoonotic influenza risk assessment. To attain high confidence in identifying zoonotic influenza viruses with moderate-to-high or low transmissibility, our analyses support that as few as three but as many as five laboratories, respectively, would need to independently perform viral transmission experiments with concordant results. This exercise facilitates the development of a more homogenous protocol for ferret transmission experiments that are employed for the purposes of risk assessment.Competing Interest StatementThe authors have declared no competing interest. |
Differential neutralization and inhibition of SARS-CoV-2 variants by antibodies elicited by COVID-19 mRNA vaccines (preprint)
Wang L , Kainulainen MH , Jiang N , Di H , Bonenfant G , Mills L , Currier M , Shrivastava-Ranjan P , Calderon BM , Sheth M , Hossain J , Lin X , Lester S , Pusch E , Jones J , Cui D , Chatterjee P , Jenks HM , Morantz E , Larson G , Hatta M , Harcourt J , Tamin A , Li Y , Tao Y , Zhao K , Burroughs A , Wong T , Tong S , Barnes JR , Tenforde MW , Self WH , Shapiro NI , Exline MC , Files DC , Gibbs KW , Hager DN , Patel M , Laufer Halpin AS , Lee JS , Xie X , Shi PY , Davis CT , Spiropoulou CF , Thornburg NJ , Oberste MS , Dugan V , Wentworth DE , Zhou B , Batra D , Beck A , Caravas J , Cintron-Moret R , Cook PW , Gerhart J , Gulvik C , Hassell N , Howard D , Knipe K , Kondor RJ , Kovacs N , Lacek K , Mann BR , McMullan LK , Moser K , Paden CR , Martin BR , Schmerer M , Shepard S , Stanton R , Stark T , Sula E , Tymeckia K , Unoarumhi Y . bioRxiv 2021 30 The evolution of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) has resulted in the emergence of many new variant lineages that have exacerbated the COVID-19 pandemic. Some of those variants were designated as variants of concern/interest (VOC/VOI) by national or international authorities based on many factors including their potential impact on vaccines. To ascertain and rank the risk of VOCs and VOIs, we analyzed their ability to escape from vaccine-induced antibodies. The variants showed differential reductions in neutralization and replication titers by post-vaccination sera. Although the Omicron variant showed the most escape from neutralization, sera collected after a third dose of vaccine (booster sera) retained moderate neutralizing activity against that variant. Therefore, vaccination remains the most effective strategy to combat the COVID-19 pandemic. |
Bivalent mRNA vaccine improves antibody-mediated neutralization of many SARS-CoV-2 Omicron lineage variants (preprint)
Jiang N , Wang L , Hatta M , Feng C , Currier M , Lin X , Hossain J , Cui D , Mann BR , Kovacs NA , Wang W , Atteberry G , Wilson M , Chau R , Lacek KA , Paden CR , Hassell N , Rambo-Martin B , Barnes JR , Kondor RJ , Self WH , Rhoads JP , Baughman A , Chappell JD , Shapiro NI , Gibbs KW , Hager DN , Lauring AS , Surie D , McMorrow ML , Thornburg NJ , Wentworth DE , Zhou B . bioRxiv 2023 09 The early Omicron lineage variants evolved and gave rise to diverging lineages that fueled the COVID-19 pandemic in 2022. Bivalent mRNA vaccines, designed to broaden protection against circulating and future variants, were authorized by the U.S. Food and Drug Administration (FDA) in August 2022 and recommended by the U.S. Centers for Disease Control and Prevention (CDC) in September 2022. The impact of bivalent vaccination on eliciting neutralizing antibodies against homologous BA.4/BA.5 viruses as well as emerging heterologous viruses needs to be analyzed. In this study, we analyze the neutralizing activity of sera collected after a third dose of vaccination (2-6 weeks post monovalent booster) or a fourth dose of vaccination (2-7 weeks post bivalent booster) against 10 predominant/recent Omicron lineage viruses including BA.1, BA.2, BA.5, BA.2.75, BA.2.75.2, BN.1, BQ.1, BQ.1.1, XBB, and XBB.1. The bivalent booster vaccination enhanced neutralizing antibody titers against all Omicron lineage viruses tested, including a 10-fold increase in neutralization of BQ.1 and BQ.1.1 viruses that predominated in the U.S. during the last two months of 2022. Overall, the data indicate the bivalent vaccine booster strengthens protection against Omicron lineage variants that evolved from BA.5 and BA.2 progenitors. Copyright The copyright holder for this preprint is the author/funder, who has granted bioRxiv a license to display the preprint in perpetuity. This article is a US Government work. It is not subject to copyright under 17 USC 105 and is also made available for use under a CC0 license. |
Robustness of the ferret model for influenza risk assessment studies: A cross-laboratory exercise
Belser JA , Lau EHY , Barclay W , Barr IG , Chen H , Fouchier RAM , Hatta M , Herfst S , Kawaoka Y , Lakdawala SS , Lee LYY , Neumann G , Peiris M , Perez DR , Russell C , Subbarao K , Sutton TC , Webby RJ , Yang H , Yen HL . mBio 2022 13 (4) e0117422 Past pandemic influenza viruses with sustained human-to-human transmissibility have emerged from animal influenza viruses. Employment of experimental models to assess the pandemic risk of emerging zoonotic influenza viruses provides critical information supporting public health efforts. Ferret transmission experiments have been utilized to predict the human-to-human transmission potential of novel influenza viruses. However, small sample sizes and a lack of standardized protocols can introduce interlaboratory variability, complicating interpretation of transmission experimental data. To assess the range of variation in ferret transmission experiments, a global exercise was conducted by 11 laboratories using two common stock H1N1 influenza viruses with different transmission characteristics in ferrets. Parameters known to affect transmission were standardized, including the inoculation route, dose, and volume, as well as a strict 1:1 donor/contact ratio for respiratory droplet transmission. Additional host and environmental parameters likely to affect influenza transmission kinetics were monitored and analyzed. The overall transmission outcomes for both viruses across 11 laboratories were concordant, suggesting the robustness of the ferret model for zoonotic influenza risk assessment. Among environmental parameters that varied across laboratories, donor-to-contact airflow directionality was associated with increased transmissibility. To attain high confidence in identifying viruses with moderate to high transmissibility or low transmissibility under a smaller number of participating laboratories, our analyses support the notion that as few as three but as many as five laboratories, respectively, would need to independently perform viral transmission experiments with concordant results. This exercise facilitates the development of a more homogenous protocol for ferret transmission experiments that are employed for the purposes of risk assessment. IMPORTANCE Following detection of a novel virus, rapid characterization efforts (both in vitro and in vivo) are undertaken at numerous laboratories worldwide to evaluate the relative risk posed to human health. Aggregation of these data are critical, but the use of nonstandardized protocols can make interpretation of divergent results a challenge. For evaluation of virus transmissibility, a multifactorial trait which can only be evaluated in vivo, identifying intrinsic levels of variability between groups can improve the utility of these data, as well as ensure that experiments are performed with sufficient replication to ensure high confidence in compiled results. Using the ferret transmission model and two influenza A viruses, we conducted a multicenter standardization exercise to improve the interpretation of transmission data generated during risk assessment activities; this exercise serves as a model for future efforts employing both in vitro and in vivo models against possible pandemic pathogens. |
Differential neutralization and inhibition of SARS-CoV-2 variants by antibodies elicited by COVID-19 mRNA vaccines.
Wang L , Kainulainen MH , Jiang N , Di H , Bonenfant G , Mills L , Currier M , Shrivastava-Ranjan P , Calderon BM , Sheth M , Mann BR , Hossain J , Lin X , Lester S , Pusch EA , Jones J , Cui D , Chatterjee P , Jenks MH , Morantz EK , Larson GP , Hatta M , Harcourt JL , Tamin A , Li Y , Tao Y , Zhao K , Lacek K , Burroughs A , Wang W , Wilson M , Wong T , Park SH , Tong S , Barnes JR , Tenforde MW , Self WH , Shapiro NI , Exline MC , Files DC , Gibbs KW , Hager DN , Patel M , Halpin AL , McMullan LK , Lee JS , Xia H , Xie X , Shi PY , Davis CT , Spiropoulou CF , Thornburg NJ , Oberste MS , Dugan VG , Wentworth DE , Zhou B . Nat Commun 2022 13 (1) 4350 The evolution of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) has resulted in the emergence of new variant lineages that have exacerbated the COVID-19 pandemic. Some of those variants were designated as variants of concern/interest (VOC/VOI) by national or international authorities based on many factors including their potential impact on vaccine-mediated protection from disease. To ascertain and rank the risk of VOCs and VOIs, we analyze the ability of 14 variants (614G, Alpha, Beta, Gamma, Delta, Epsilon, Zeta, Eta, Theta, Iota, Kappa, Lambda, Mu, and Omicron) to escape from mRNA vaccine-induced antibodies. The variants show differential reductions in neutralization and replication by post-vaccination sera. Although the Omicron variant (BA.1, BA.1.1, and BA.2) shows the most escape from neutralization, sera collected after a third dose of vaccine (booster sera) retain moderate neutralizing activity against that variant. Therefore, vaccination remains an effective strategy during the COVID-19 pandemic. |
Mutations in the Neuraminidase-Like Protein of Bat Influenza H18N11 Virus Enhance Virus Replication in Mammalian Cells, Mice, and Ferrets.
Zhong G , Fan S , Hatta M , Nakatsu S , Walters KB , Lopes TJS , Wang JI , Ozawa M , Karasin A , Li Y , Tong S , Donis RO , Neumann G , Kawaoka Y . J Virol 2019 94 (5) To characterize bat influenza H18N11 virus, we propagated a reverse genetics-generated H18N11 virus in MDCK II cells and detected two adapting mutations in the neuraminidase (NA)-like protein (NA-F144C and NA-T342A, N2 numbering) that increased virus titers in three mammalian cell lines (i.e., Madin-Darby canine kidney, Madin-Darby canine kidney II, and human lung adenocarcinoma Calu-3 cells). In mice, wild-type H18N11 virus replicated only in the lungs of the infected animals, whereas the NA-T342A and NA-F144C/T342A mutant viruses were detected in the nasal turbinates in addition to the lungs. Bat influenza viruses have not been tested for their virulence and organ tropism in ferrets. We detected wild-type and single mutant viruses each possessing NA-F144C or NA-T342A in the nasal turbinates of one or several infected ferret(s), respectively. A mutant virus possessing both NA-F144C and T342A was isolated from both the lung and trachea, suggesting broader organ tropism compared with wild-type virus. However, none of the H18N11 viruses caused symptoms in mice or ferrets. The NA-F144C/T342A double mutation did not substantially affect virion morphology or the release of virions from cells. Collectively, our data demonstrate that propagation of bat influenza H18N11 virus in mammalian cells can result in mammalian-adapting mutations that could increase virus replicative ability and/or organ tropism; overall, however, these viruses did not replicate to high titers throughout the respiratory tract of mice and ferrets.IMPORTANCE Bats are reservoirs for several severe zoonotic pathogens. The genomes of influenza A viruses of the H17N10 and H18N11 subtypes were identified in bats, but no live virus has been isolated. The characterization of artificially generated bat influenza H18N11 virus in mammalian cell lines and animal models revealed that this virus can acquire mammalian-adapting mutations that could increase its zoonotic potential; however, the wild-type and mutant viruses did not replicate in the lungs of all infected animals. |
Selection of antigenically advanced variants of seasonal influenza viruses
Li C , Hatta M , Burke DF , Ping J , Zhang Y , Ozawa M , Taft AS , Das SC , Hanson AP , Song J , Imai M , Wilker PR , Watanabe T , Watanabe S , Ito M , Iwatsuki-Horimoto K , Russell CA , James SL , Skepner E , Maher EA , Neumann G , Klimov AI , Kelso A , McCauley J , Wang D , Shu Y , Odagiri T , Tashiro M , Xu X , Wentworth DE , Katz JM , Cox NJ , Smith DJ , Kawaoka Y . Nat Microbiol 2016 1 (6) 16058 Influenza viruses mutate frequently, necessitating constant updates of vaccine viruses. To establish experimental approaches that may complement the current vaccine strain selection process, we selected antigenic variants from human H1N1 and H3N2 influenza virus libraries possessing random mutations in the globular head of the haemagglutinin protein (which includes the antigenic sites) by incubating them with human and/or ferret convalescent sera to human H1N1 and H3N2 viruses. We also selected antigenic escape variants from human viruses treated with convalescent sera and from mice that had been previously immunized against human influenza viruses. Our pilot studies with past influenza viruses identified escape mutants that were antigenically similar to variants that emerged in nature, establishing the feasibility of our approach. Our studies with contemporary human influenza viruses identified escape mutants before they caused an epidemic in 2014-2015. This approach may aid in the prediction of potential antigenic escape variants and the selection of future vaccine candidates before they become widespread in nature. |
Phylogeographical analysis of the dominant multidrug-resistant H58 clade of Salmonella Typhi identifies inter- and intracontinental transmission events.
Wong VK , Baker S , Pickard DJ , Parkhill J , Page AJ , Feasey NA , Kingsley RA , Thomson NR , Keane JA , Weill FX , Edwards DJ , Hawkey J , Harris SR , Mather AE , Cain AK , Hadfield J , Hart PJ , Thieu NT , Klemm EJ , Glinos DA , Breiman RF , Watson CH , Kariuki S , Gordon MA , Heyderman RS , Okoro C , Jacobs J , Lunguya O , Edmunds WJ , Msefula C , Chabalgoity JA , Kama M , Jenkins K , Dutta S , Marks F , Campos J , Thompson C , Obaro S , MacLennan CA , Dolecek C , Keddy KH , Smith AM , Parry CM , Karkey A , Mulholland EK , Campbell JI , Dongol S , Basnyat B , Dufour M , Bandaranayake D , Naseri TT , Singh SP , Hatta M , Newton P , Onsare RS , Isaia L , Dance D , Davong V , Thwaites G , Wijedoru L , Crump JA , De Pinna E , Nair S , Nilles EJ , Thanh DP , Turner P , Soeng S , Valcanis M , Powling J , Dimovski K , Hogg G , Farrar J , Holt KE , Dougan G . Nat Genet 2015 47 (6) 632-9 The emergence of multidrug-resistant (MDR) typhoid is a major global health threat affecting many countries where the disease is endemic. Here whole-genome sequence analysis of 1,832 Salmonella enterica serovar Typhi (S. Typhi) identifies a single dominant MDR lineage, H58, that has emerged and spread throughout Asia and Africa over the last 30 years. Our analysis identifies numerous transmissions of H58, including multiple transfers from Asia to Africa and an ongoing, unrecognized MDR epidemic within Africa itself. Notably, our analysis indicates that H58 lineages are displacing antibiotic-sensitive isolates, transforming the global population structure of this pathogen. H58 isolates can harbor a complex MDR element residing either on transmissible IncHI1 plasmids or within multiple chromosomal integration sites. We also identify new mutations that define the H58 lineage. This phylogeographical analysis provides a framework to facilitate global management of MDR typhoid and is applicable to similar MDR lineages emerging in other bacterial species. |
The draft genome sequence of the ferret (Mustela putorius furo) facilitates study of human respiratory disease.
Peng X , Alfoldi J , Gori K , Eisfeld AJ , Tyler SR , Tisoncik-Go J , Brawand D , Law GL , Skunca N , Hatta M , Gasper DJ , Kelly SM , Chang J , Thomas MJ , Johnson J , Berlin AM , Lara M , Russell P , Swofford R , Turner-Maier J , Young S , Hourlier T , Aken B , Searle S , Sun X , Yi Y , Suresh M , Tumpey TM , Siepel A , Wisely SM , Dessimoz C , Kawaoka Y , Birren BW , Lindblad-Toh K , Di Palma F , Engelhardt JF , Palermo RE , Katze MG . Nat Biotechnol 2014 32 (12) 1250-5 The domestic ferret (Mustela putorius furo) is an important animal model for multiple human respiratory diseases. It is considered the 'gold standard' for modeling human influenza virus infection and transmission. Here we describe the 2.41 Gb draft genome assembly of the domestic ferret, constituting 2.28 Gb of sequence plus gaps. We annotated 19,910 protein-coding genes on this assembly using RNA-seq data from 21 ferret tissues. We characterized the ferret host response to two influenza virus infections by RNA-seq analysis of 42 ferret samples from influenza time-course data and showed distinct signatures in ferret trachea and lung tissues specific to 1918 or 2009 human pandemic influenza virus infections. Using microarray data from 16 ferret samples reflecting cystic fibrosis disease progression, we showed that transcriptional changes in the CFTR-knockout ferret lung reflect pathways of early disease that cannot be readily studied in human infants with cystic fibrosis disease. |
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