Last data update: Jan 27, 2025. (Total: 48650 publications since 2009)
Records 1-30 (of 59 Records) |
Query Trace: Barnes JR[original query] |
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Highly pathogenic avian influenza A(H5N1) virus infections in humans
Garg S , Reinhart K , Couture A , Kniss K , Davis CT , Kirby MK , Murray EL , Zhu S , Kraushaar V , Wadford DA , Drehoff C , Kohnen A , Owen M , Morse J , Eckel S , Goswitz J , Turabelidze G , Krager S , Unutzer A , Gonzales ER , Abdul Hamid C , Ellington S , Mellis AM , Budd A , Barnes JR , Biggerstaff M , Jhung MA , Richmond-Crum M , Burns E , Shimabukuro TT , Uyeki TM , Dugan VG , Reed C , Olsen SJ . N Engl J Med 2024 BACKGROUND: Highly pathogenic avian influenza A(H5N1) viruses have caused widespread infections in dairy cows and poultry in the United States, with sporadic human cases. We describe characteristics of human A(H5N1) cases identified from March through October 2024 in the United States. METHODS: We analyzed data from persons with laboratory-confirmed A(H5N1) virus infection using a standardized case-report form linked to laboratory results from the Centers for Disease Control and Prevention influenza A/H5 subtyping kit. RESULTS: Of 46 case patients, 20 were exposed to infected poultry, 25 were exposed to infected or presumably infected dairy cows, and 1 had no identified exposure; that patient was hospitalized with nonrespiratory symptoms, and A(H5N1) virus infection was detected through routine surveillance. Among the 45 case patients with animal exposures, the median age was 34 years, and all had mild A(H5N1) illness; none were hospitalized, and none died. A total of 42 patients (93%) had conjunctivitis, 22 (49%) had fever, and 16 (36%) had respiratory symptoms; 15 (33%) had conjunctivitis only. The median duration of illness among 16 patients with available data was 4 days (range, 1 to 8). Most patients (87%) received oseltamivir; oseltamivir was started a median of 2 days after symptom onset. No additional cases were identified among the 97 household contacts of case patients with animal exposures. The types of personal protective equipment (PPE) that were most commonly used by workers exposed to infected animals were gloves (71%), eye protection (60%), and face masks (47%). CONCLUSIONS: In the cases identified to date, A(H5N1) viruses generally caused mild illness, mostly conjunctivitis, of short duration, predominantly in U.S. adults exposed to infected animals; most patients received prompt antiviral treatment. No evidence of human-to-human A(H5N1) transmission was identified. PPE use among occupationally exposed persons was suboptimal, which suggests that additional strategies are needed to reduce exposure risk. (Funded by the Centers for Disease Control and Prevention.). |
An influenza mRNA vaccine protects ferrets from lethal infection with highly pathogenic avian influenza A(H5N1) virus
Hatta M , Hatta Y , Choi A , Hossain J , Feng C , Keller MW , Ritter JM , Huang Y , Fang E , Pusch EA , Rowe T , De La Cruz JA , Johnson MC , Liddell J , Jiang N , Stadlbauer D , Liu L , Bhattacharjee AK , Rouse JR , Currier M , Wang L , Levine MZ , Kirby MK , Steel J , Di H , Barnes JR , Henry C , Davis CT , Nachbagauer R , Wentworth DE , Zhou B . Sci Transl Med 2024 16 (778) eads1273 ![]() The global spread of the highly pathogenic avian influenza (HPAI) A(H5N1) virus poses a serious pandemic threat, necessitating the swift development of effective vaccines. The success of messenger RNA (mRNA) vaccine technology in the COVID-19 pandemic, marked by its rapid development and scalability, demonstrates its potential for addressing other infectious threats, such as HPAI A(H5N1). We therefore evaluated mRNA vaccine candidates targeting panzootic influenza A(H5) clade 2.3.4.4b viruses, which have been shown to infect a range of mammalian species, including most recently being detected in dairy cattle. Ferrets were immunized with mRNA vaccines encoding either hemagglutinin alone or hemagglutinin and neuraminidase, derived from a 2.3.4.4b prototype vaccine virus recommended by the World Health Organization. Kinetics of the immune responses, as well as protection against a lethal challenge dose of A(H5N1) virus, were assessed. Two doses of mRNA vaccination elicited robust neutralizing antibody titers against a 2022 avian isolate and a 2024 human isolate. Further, mRNA vaccination conferred protection from lethal challenge, whereas all unvaccinated ferrets succumbed to infection. It also reduced viral titers in the upper and lower respiratory tracts of infected ferrets. These results underscore the effectiveness of mRNA vaccines against HPAI A(H5N1), showcasing their potential as a vaccine platform for future influenza pandemics. |
Discriminating north American swine influenza viruses with a portable, one-step, triplex real-time RT-PCR assay, and portable sequencing
Kirby MK , Shu B , Keller MW , Wilson MM , Rambo-Martin BL , Jang Y , Liddell J , Salinas Duron E , Nolting JM , Bowman AS , Davis CT , Wentworth DE , Barnes JR . Viruses 2024 16 (10) ![]() ![]() Swine harbors a genetically diverse population of swine influenza A viruses (IAV-S), with demonstrated potential to transmit to the human population, causing outbreaks and pandemics. Here, we describe the development of a one-step, triplex real-time reverse transcription-polymerase chain reaction (rRT-PCR) assay that detects and distinguishes the majority of the antigenically distinct influenza A virus hemagglutinin (HA) clades currently circulating in North American swine, including the IAV-S H1 1A.1 (α), 1A.2 (β), 1A.3 (γ), 1B.2.2 (δ1) and 1B.2.1 (δ2) clades, and the IAV-S H3 2010.1 clade. We performed an in-field test at an exhibition swine show using in-field viral concentration and RNA extraction methodologies and a portable real-time PCR instrument, and rapidly identified three distinct IAV-S clades circulating within the N.A. swine population. Portable sequencing is used to further confirm the results of the in-field test of the swine triplex assay. The IAV-S triplex rRT-PCR assay can be easily transported and used in-field to characterize circulating IAV-S clades in North America, allowing for surveillance and early detection of North American IAV-S with human outbreak and pandemic potential. |
Antigenic drift and subtype interference shape A(H3N2) epidemic dynamics in the United States
Perofsky AC , Huddleston J , Hansen CL , Barnes JR , Rowe T , Xu X , Kondor R , Wentworth DE , Lewis N , Whittaker L , Ermetal B , Harvey R , Galiano M , Daniels RS , McCauley JW , Fujisaki S , Nakamura K , Kishida N , Watanabe S , Hasegawa H , Sullivan SG , Barr IG , Subbarao K , Krammer F , Bedford T , Viboud C . Elife 2024 13 ![]() ![]() ![]() Influenza viruses continually evolve new antigenic variants, through mutations in epitopes of their major surface proteins, hemagglutinin (HA) and neuraminidase (NA). Antigenic drift potentiates the reinfection of previously infected individuals, but the contribution of this process to variability in annual epidemics is not well understood. Here, we link influenza A(H3N2) virus evolution to regional epidemic dynamics in the United States during 1997-2019. We integrate phenotypic measures of HA antigenic drift and sequence-based measures of HA and NA fitness to infer antigenic and genetic distances between viruses circulating in successive seasons. We estimate the magnitude, severity, timing, transmission rate, age-specific patterns, and subtype dominance of each regional outbreak and find that genetic distance based on broad sets of epitope sites is the strongest evolutionary predictor of A(H3N2) virus epidemiology. Increased HA and NA epitope distance between seasons correlates with larger, more intense epidemics, higher transmission, greater A(H3N2) subtype dominance, and a greater proportion of cases in adults relative to children, consistent with increased population susceptibility. Based on random forest models, A(H1N1) incidence impacts A(H3N2) epidemics to a greater extent than viral evolution, suggesting that subtype interference is a major driver of influenza A virus infection ynamics, presumably via heterosubtypic cross-immunity. | Seasonal influenza (flu) viruses cause outbreaks every winter. People infected with influenza typically develop mild respiratory symptoms. But flu infections can cause serious illness in young children, older adults and people with chronic medical conditions. Infected or vaccinated individuals develop some immunity, but the viruses evolve quickly to evade these defenses in a process called antigenic drift. As the viruses change, they can re-infect previously immune people. Scientists update the flu vaccine yearly to keep up with this antigenic drift. The immune system fights flu infections by recognizing two proteins, known as antigens, on the virus’s surface, called hemagglutinin (HA) and neuraminidase (NA). However, mutations in the genes encoding these proteins can make them unrecognizable, letting the virus slip past the immune system. Scientists would like to know how these changes affect the size, severity and timing of annual influenza outbreaks. Perofsky et al. show that tracking genetic changes in HA and NA may help improve flu season predictions. The experiments compared the severity of 22 flu seasons caused by the A(H3N2) subtype in the United States with how much HA and NA had evolved since the previous year. The A(H3N2) subtype experiences the fastest rates of antigenic drift and causes more cases and deaths than other seasonal flu viruses. Genetic changes in HA and NA were a better predictor of A(H3N2) outbreak severity than the blood tests for protective antibodies that epidemiologists traditionally use to track flu evolution. However, the prevalence of another subtype of influenza A circulating in the population, called A(H1N1), was an even better predictor of how severe A(H3N2) outbreaks would be. Perofsky et al. are the first to show that genetic changes in NA contribute to the severity of flu seasons. Previous studies suggested a link between genetic changes in HA and flu season severity, and flu vaccines include the HA protein to help the body recognize new influenza strains. The results suggest that adding the NA protein to flu vaccines may improve their effectiveness. In the future, flu forecasters may want to analyze genetic changes in both NA and HA to make their outbreak predictions. Tracking how much of the A(H1N1) subtype is circulating may also be useful for predicting the severity of A(H3N2) outbreaks. | eng |
Wastewater surveillance for influenza A virus and H5 subtype concurrent with the highly pathogenic avian influenza A(H5N1) virus outbreak in cattle and poultry and associated human cases - United States, May 12-July 13, 2024
Louis S , Mark-Carew M , Biggerstaff M , Yoder J , Boehm AB , Wolfe MK , Flood M , Peters S , Stobierski MG , Coyle J , Leslie MT , Sinner M , Nims D , Salinas V , Lustri L , Bojes H , Shetty V , Burnor E , Rabe A , Ellison-Giles G , Yu AT , Bell A , Meyer S , Lynfield R , Sutton M , Scholz R , Falender R , Matzinger S , Wheeler A , Ahmed FS , Anderson J , Harris K , Walkins A , Bohra S , O'Dell V , Guidry VT , Christensen A , Moore Z , Wilson E , Clayton JL , Parsons H , Kniss K , Budd A , Mercante JW , Reese HE , Welton M , Bias M , Webb J , Cornforth D , Santibañez S , Soelaeman RH , Kaur M , Kirby AE , Barnes JR , Fehrenbach N , Olsen SJ , Honein MA . MMWR Morb Mortal Wkly Rep 2024 73 (37) 804-809 ![]() ![]() As part of the response to the highly pathogenic avian influenza A(H5N1) virus outbreak in U.S. cattle and poultry and the associated human cases, CDC and partners are monitoring influenza A virus levels and detection of the H5 subtype in wastewater. Among 48 states and the District of Columbia that performed influenza A testing of wastewater during May 12-July 13, 2024, a weekly average of 309 sites in 38 states had sufficient data for analysis, and 11 sites in four states reported high levels of influenza A virus. H5 subtype testing was conducted at 203 sites in 41 states, with H5 detections at 24 sites in nine states. For each detection or high level, CDC and state and local health departments evaluated data from other influenza surveillance systems and partnered with wastewater utilities and agriculture departments to investigate potential sources. Among the four states with high influenza A virus levels detected in wastewater, three states had corresponding evidence of human influenza activity from other influenza surveillance systems. Among the 24 sites with H5 detections, 15 identified animal sources within the sewershed or adjacent county, including eight milk-processing inputs. Data from these early investigations can help health officials optimize the use of wastewater surveillance during the upcoming respiratory illness season. |
Late-season influenza vaccine effectiveness against medically attended outpatient illness, United States, December 2022-April 2023
Chung JR , Shirk P , Gaglani M , Mutnal MB , Nowalk MP , Moehling Geffel K , House SL , Curley T , Wernli KJ , Kiniry EL , Martin ET , Vaughn IA , Murugan V , Lim ES , Saade E , Faryar K , Williams OL , Walter EB , Price AM , Barnes JR , DaSilva J , Kondor R , Ellington S , Flannery B . Influenza Other Respir Viruses 2024 18 (6) e13342 ![]() BACKGROUND: The 2022-23 US influenza season peaked early in fall 2022. METHODS: Late-season influenza vaccine effectiveness (VE) against outpatient, laboratory-confirmed influenza was calculated among participants of the US Influenza VE Network using a test-negative design. RESULTS: Of 2561 participants enrolled from December 12, 2022 to April 30, 2023, 91 laboratory-confirmed influenza cases primarily had A(H1N1)pdm09 (6B.1A.5a.2a.1) or A(H3N2) (3C.2a1b.2a.2b). Overall, VE was 30% (95% confidence interval -9%, 54%); low late-season activity precluded estimation for most subgroups. CONCLUSIONS: 2022-23 late-season outpatient influenza VE was not statistically significant. Genomic characterization may improve the identification of influenza viruses that circulate postinfluenza peak. |
Outbreak of highly pathogenic avian influenza A(H5N1) viruses in U.S. dairy cattle and detection of two human cases - United States, 2024
Garg S , Reed C , Davis CT , Uyeki TM , Behravesh CB , Kniss K , Budd A , Biggerstaff M , Adjemian J , Barnes JR , Kirby MK , Basler C , Szablewski CM , Richmond-Crum M , Burns E , Limbago B , Daskalakis DC , Armstrong K , Boucher D , Shimabukuro TT , Jhung MA , Olsen SJ , Dugan V . MMWR Morb Mortal Wkly Rep 2024 73 (21) 501-505 ![]() ![]() |
Antigenic characterization of circulating and emerging SARS-CoV-2 variants in the U.S. Throughout the Delta to Omicron waves
Di H , Pusch EA , Jones J , Kovacs NA , Hassell N , Sheth M , Lynn KS , Keller MW , Wilson MM , Keong LM , Cui D , Park SH , Chau R , Lacek KA , Liddell JD , Kirby MK , Yang G , Johnson M , Thor S , Zanders N , Feng C , Surie D , DeCuir J , Lester SN , Atherton L , Hicks H , Tamin A , Harcourt JL , Coughlin MM , Self WH , Rhoads JP , Gibbs KW , Hager DN , Shapiro NI , Exline MC , Lauring AS , Rambo-Martin B , Paden CR , Kondor RJ , Lee JS , Barnes JR , Thornburg NJ , Zhou B , Wentworth DE , Davis CT . Vaccines (Basel) 2024 12 (5) ![]() ![]() Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) has evolved into numerous lineages with unique spike mutations and caused multiple epidemics domestically and globally. Although COVID-19 vaccines are available, new variants with the capacity for immune evasion continue to emerge. To understand and characterize the evolution of circulating SARS-CoV-2 variants in the U.S., the Centers for Disease Control and Prevention (CDC) initiated the National SARS-CoV-2 Strain Surveillance (NS3) program and has received thousands of SARS-CoV-2 clinical specimens from across the nation as part of a genotype to phenotype characterization process. Focus reduction neutralization with various antisera was used to antigenically characterize 143 SARS-CoV-2 Delta, Mu and Omicron subvariants from selected clinical specimens received between May 2021 and February 2023, representing a total of 59 unique spike protein sequences. BA.4/5 subvariants BU.1, BQ.1.1, CR.1.1, CQ.2 and BA.4/5 + D420N + K444T; BA.2.75 subvariants BM.4.1.1, BA.2.75.2, CV.1; and recombinant Omicron variants XBF, XBB.1, XBB.1.5 showed the greatest escape from neutralizing antibodies when analyzed against post third-dose original monovalent vaccinee sera. Post fourth-dose bivalent vaccinee sera provided better protection against those subvariants, but substantial reductions in neutralization titers were still observed, especially among BA.4/5 subvariants with both an N-terminal domain (NTD) deletion and receptor binding domain (RBD) substitutions K444M + N460K and recombinant Omicron variants. This analysis demonstrated a framework for long-term systematic genotype to antigenic characterization of circulating and emerging SARS-CoV-2 variants in the U.S., which is critical to assessing their potential impact on the effectiveness of current vaccines and antigen recommendations for future updates. |
Highly pathogenic avian influenza A(H5N1) virus infection in a dairy farm worker
Uyeki TM , Milton S , Abdul Hamid C , Reinoso Webb C , Presley SM , Shetty V , Rollo SN , Martinez DL , Rai S , Gonzales ER , Kniss KL , Jang Y , Frederick JC , De La Cruz JA , Liddell J , Di H , Kirby MK , Barnes JR , Davis CT . N Engl J Med 2024 ![]() ![]() |
Genetic drift and purifying selection shape within-host influenza A virus populations during natural swine infections
VanInsberghe D , McBride DS , DaSilva J , Stark TJ , Lau MSY , Shepard SS , Barnes JR , Bowman AS , Lowen AC , Koelle K . PLoS Pathog 2024 20 (4) e1012131 ![]() ![]() Patterns of within-host influenza A virus (IAV) diversity and evolution have been described in natural human infections, but these patterns remain poorly characterized in non-human hosts. Elucidating these dynamics is important to better understand IAV biology and the evolutionary processes that govern spillover into humans. Here, we sampled an IAV outbreak in pigs during a week-long county fair to characterize viral diversity and evolution in this important reservoir host. Nasal wipes were collected on a daily basis from all pigs present at the fair, yielding up to 421 samples per day. Subtyping of PCR-positive samples revealed the co-circulation of H1N1 and H3N2 subtype swine IAVs. PCR-positive samples with robust Ct values were deep-sequenced, yielding 506 sequenced samples from a total of 253 pigs. Based on higher-depth re-sequenced data from a subset of these initially sequenced samples (260 samples from 168 pigs), we characterized patterns of within-host IAV genetic diversity and evolution. We find that IAV genetic diversity in single-subtype infected pigs is low, with the majority of intrahost Single Nucleotide Variants (iSNVs) present at frequencies of <10%. The ratio of the number of nonsynonymous to the number of synonymous iSNVs is significantly lower than under the neutral expectation, indicating that purifying selection shapes patterns of within-host viral diversity in swine. The dynamic turnover of iSNVs and their pronounced frequency changes further indicate that genetic drift also plays an important role in shaping IAV populations within pigs. Taken together, our results highlight similarities in patterns of IAV genetic diversity and evolution between humans and swine, including the role of stochastic processes in shaping within-host IAV dynamics. |
In-field detection and characterization of B/Victoria lineage deletion variant viruses causing early influenza activity and an outbreak in Louisiana, 2019
Shu B , Wilson MM , Keller MW , Tran H , Sokol T , Lee G , Rambo-Martin BL , Kirby MK , Hassell N , Haydel D , Hand J , Wentworth DE , Barnes JR . Influenza Other Respir Viruses 2024 18 (1) e13246 ![]() ![]() BACKGROUND: In 2019, the Louisiana Department of Health reported an early influenza B/Victoria (B/VIC) virus outbreak. METHOD: As it was an atypically large outbreak, we deployed to Louisiana to investigate it using genomics and a triplex real-time RT-PCR assay to detect three antigenically distinct B/VIC lineage variant viruses. RESULTS: The investigation indicated that B/VIC V1A.3 subclade, containing a three amino acid deletion in the hemagglutinin and known to be antigenically distinct to the B/Colorado/06/2017 vaccine virus, was the most prevalent circulating virus within the specimens evaluated (86/88 in real-time RT-PCR). CONCLUSION: This work underscores the value of portable platforms for rapid, onsite pathogen characterization. |
Genetic and potential antigenic evolution of influenza A(H1N1)pdm09 viruses circulating in Kenya during 2009-2018 influenza seasons
Owuor DC , de Laurent ZR , Nyawanda BO , Emukule GO , Kondor R , Barnes JR , Nokes DJ , Agoti CN , Chaves SS . Sci Rep 2023 13 (1) 22342 ![]() ![]() Influenza viruses undergo rapid evolutionary changes, which requires continuous surveillance to monitor for genetic and potential antigenic changes in circulating viruses that can guide control and prevention decision making. We sequenced and phylogenetically analyzed A(H1N1)pdm09 virus genome sequences obtained from specimens collected from hospitalized patients of all ages with or without pneumonia between 2009 and 2018 from seven sentinel surveillance sites across Kenya. We compared these sequences with recommended vaccine strains during the study period to infer genetic and potential antigenic changes in circulating viruses and associations of clinical outcome. We generated and analyzed a total of 383 A(H1N1)pdm09 virus genome sequences. Phylogenetic analyses of HA protein revealed that multiple genetic groups (clades, subclades, and subgroups) of A(H1N1)pdm09 virus circulated in Kenya over the study period; these evolved away from their vaccine strain, forming clades 7 and 6, subclades 6C, 6B, and 6B.1, and subgroups 6B.1A and 6B.1A1 through acquisition of additional substitutions. Several amino acid substitutions among circulating viruses were associated with continued evolution of the viruses, especially in antigenic epitopes and receptor binding sites (RBS) of circulating viruses. Disease severity declined with an increase in age among children aged < 5 years. Our study highlights the necessity of timely genomic surveillance to monitor the evolutionary changes of influenza viruses. Routine influenza surveillance with broad geographic representation and whole genome sequencing capacity to inform on prioritization of antigenic analysis and the severity of circulating strains are critical to improved selection of influenza strains for inclusion in vaccines. |
Targeted amplification and genetic sequencing of the severe acute respiratory syndrome coronavirus 2 surface glycoprotein
Keller MW , Keong LM , Rambo-Martin BL , Hassell N , Lacek KA , Wilson MM , Kirby MK , Liddell J , Owuor DC , Sheth M , Madden J , Lee JS , Kondor RJ , Wentworth DE , Barnes JR . Microbiol Spectr 2023 e0298223 ![]() ![]() The COVID-19 pandemic was accompanied by an unprecedented surveillance effort. The resulting data were and will continue to be critical for surveillance and control of SARS-CoV-2. However, some genomic surveillance methods experienced challenges as the virus evolved, resulting in incomplete and poor quality data. Complete and quality coverage, especially of the S-gene, is important for supporting the selection of vaccine candidates. As such, we developed a robust method to target the S-gene for amplification and sequencing. By focusing on the S-gene and imposing strict coverage and quality metrics, we hope to increase the quality of surveillance data for this continually evolving gene. Our technique is currently being deployed globally to partner laboratories, and public health representatives from 79 countries have received hands-on training and support. Expanding access to quality surveillance methods will undoubtedly lead to earlier detection of novel variants and better inform vaccine strain selection. |
Author Correction: Multiplexed CRISPR-based microfluidic platform for clinical testing of respiratory viruses and identification of SARS-CoV-2 variants
Welch NL , Zhu M , Hua C , Weller J , Mirhashemi ME , Nguyen TG , Mantena S , Bauer MR , Shaw BM , Ackerman CM , Thakku SG , Tse MW , Kehe J , Uwera MM , Eversley JS , Bielwaski DA , McGrath G , Braidt J , Johnson J , Cerrato F , Moreno GK , Krasilnikova LA , Petros BA , Gionet GL , King E , Huard RC , Jalbert SK , Cleary ML , Fitzgerald NA , Gabriel SB , Gallagher GR , Smole SC , Madoff LC , Brown CM , Keller MW , Wilson MM , Kirby MK , Barnes JR , Park DJ , Siddle KJ , Happi CT , Hung DT , Springer M , MacInnis BL , Lemieux JE , Rosenberg E , Branda JA , Blainey PC , Sabeti PC , Myhrvold C . Nat Med 2023 ![]() In the version of the article originally published, some of the oligonucleotide sequences in Supplementary Table 4, on the “21 viruses” and “RVP” tabs, were mislabeled. The Supplementary Tables file has now been corrected. |
Avian influenza A viruses reassort and diversify differently in mallards and mammals (preprint)
Ganti K , Bagga A , DaSilva J , Shepard SS , Barnes JR , Shriner S , Koelle K , Lowen AC . bioRxiv 2021 2021.02.08.430042 Reassortment among co-infecting influenza A viruses (IAVs) is an important source of viral diversity and can facilitate expansion into novel host species. Indeed, reassortment played a key role in the evolution of the last three pandemic IAVs. Observed patterns of reassortment within a coinfected host are likely to be shaped by several factors, including viral load, the extent of viral mixing within the host and the stringency of selection. These factors in turn are expected to vary among the diverse host species that IAV infects. To investigate host differences in IAV reassortment, here we examined reassortment of two distinct avian IAV within their natural host (mallards) and a mammalian model system (guinea pigs). Animals were co-inoculated with A/wildbird/California/187718-36/2008 (H3N8) and A/mallard/Colorado/P66F1-5/2008 (H4N6) viruses. Longitudinal samples were collected from the cloaca of mallards or the nasal tract of guinea pigs and viral genetic exchange was monitored by genotyping clonal isolates from these samples. Relative to those in guinea pigs, viral populations in mallards showed higher frequencies of reassortant genotypes and were characterized by higher genotype richness and diversity. In line with these observations, analysis of pairwise segment combinations revealed lower linkage disequilibrium in mallards as compared to guinea pigs. No clear longitudinal patterns in richness, diversity or linkage disequilibrium were present in either host. Our results reveal mallards to be a highly permissive host for IAV reassortment and suggest that reduced viral mixing limits avian IAV reassortment in a mammalian host.Competing Interest StatementThe authors have declared no competing interest. |
Characterizing the countrywide epidemic spread of influenza A(H1N1)pdm09 virus in Kenya between 2009 and 2018 (preprint)
Owuor DC , de Laurent ZR , Kikwai GK , Mayieka LM , Ochieng M , Müller NF , Otieno NA , Emukule GO , Hunsperger EA , Garten R , Barnes JR , Chaves SS , Nokes DJ , Agoti CN . medRxiv 2021 2021.03.30.21254587 Background The spatiotemporal patterns of spread of influenza A(H1N1)pdm09 viruses on a countrywide scale are unclear in many tropical/subtropical regions mainly because spatiotemporally representative sequence data is lacking.Methods We isolated, sequenced, and analyzed 383 influenza A(H1N1)pdm09 viral genomes isolated from hospitalized patients between 2009 and 2018 from seven locations across Kenya. Using these genomes and contemporaneously sampled global sequences, we characterized the spread of the virus in Kenya over several seasons using phylodynamic methods.Results The transmission dynamics of influenza A(H1N1)pdm09 virus in Kenya was characterized by: (i) multiple virus introductions into Kenya over the study period, although these were remarkably few, with only a few of those introductions instigating seasonal epidemics that then established local transmission clusters; (ii) persistence of transmission clusters over several epidemic seasons across the country; (iii) seasonal fluctuations in effective reproduction number (Re) associated with lower number of infections and seasonal fluctuations in relative genetic diversity after an initial rapid increase during the early pandemic phase, which broadly corresponded to epidemic peaks in the northern and southern hemispheres; (iv) high virus genetic diversity with greater frequency of seasonal fluctuations in 2009-11 and 2018 and low virus genetic diversity with relatively weaker seasonal fluctuations in 2012-17; and (v) virus migration from multiple geographical regions to multiple geographical destinations in Kenya.Conclusion Considerable influenza virus diversity circulates within Africa, as demonstrated in this report, including virus lineages that are unique to the region, which may be capable of dissemination to other continents through a globally migrating virus population. Further knowledge of the viral lineages that circulate within understudied low-to-middle income tropical and subtropical regions is required to understand the full diversity and global ecology of influenza viruses in humans and to inform vaccination strategies within these regions.Competing Interest StatementThe authors have declared no competing interest.Funding StatementFunding: The authors D.C.O. and C.N.A. were supported by the Initiative to Develop African Research Leaders (IDeAL) through the DELTAS Africa Initiative [DEL-15-003]. The DELTAS Africa Initiative is an independent funding scheme of the African Academy of Sciences (AAS)'s Alliance for Accelerating Excellence in Science in Africa (AESA) and supported by the New Partnership for Africa's Development Planning and Coordinating Agency (NEPAD Agency) with funding from the Wellcome Trust [107769/Z/10/Z] and the UK government. The study was also part funded by a Wellcome Trust grant [1029745] and the USA CDC grant [GH002133]. N.F.M. is supported by the Swiss National Science Foundation (PZEZP3_191891). This paper is published with the permission of the Director of KEMRI.Author DeclarationsI confirm all relevant ethical guidelines have been followed, and any necessary IRB and/or ethics committee approvals have been obtained.YesThe details of the IRB/oversight body that provided approval or exemption for the research described are given below:The Kenya Medical Research Institute (KEMRI) and KEMRI-Wellcome Trust Research Programme Scientific and Ethics Review Unit (SERU), which is mandated to provide ethical approval for research work conducted in Kenya, provided ethical approval for the studies which collected and archived the samples used in these studies. These were approved under the following Scientific Steering Committee (SSC) approvals: 1. SSC No. 1899, SSC No. 2558 and SSC No. 2692; 2. KEMRI-Wellcome Trust Research Programme SSC No. 1055 and SSC No. 1433.All necessary patient/participant consent has been obtained and the appropriate institutional forms have been archived.YesI understand that all clinical trials and any other prospective interventional studies must be registered with an ICMJE-approved registry, such as Clini alTrials.gov. I confirm that any such study reported in the manuscript has been registered and the trial registration ID is provided (note: if posting a prospective study registered retrospectively, please provide a statement in the trial ID field explaining why the study was not registered in advance).YesI have followed all appropriate research reporting guidelines and uploaded the relevant EQUATOR Network research reporting checklist(s) and other pertinent material as supplementary files, if applicable.YesAll generated sequence data were deposited in the Global Initiative on Sharing All Influenza Data (GISAID). https://github.com/DCollinsOwuor/H1N1pdm09_Kenya_Phylodynamics/tree/main/Data/. |
Integrating genotypes and phenotypes improves long-term forecasts of seasonal influenza A/H3N2 evolution (preprint)
Huddleston J , Barnes JR , Rowe T , Xu X , Kondor R , Wentworth DE , Whittaker L , Ermetal B , Daniels RS , McCauley JW , Fujisaki S , Nakamura K , Kishida N , Watanabe S , Hasegawa H , Barr I , Subbarao K , Neher RA , Bedford T . bioRxiv 2020 2020.06.12.145151 Seasonal influenza virus A/H3N2 is a major cause of death globally. Vaccination remains the most effective preventative. Rapid mutation of hemagglutinin allows viruses to escape adaptive immunity. This antigenic drift necessitates regular vaccine updates. Effective vaccine strains need to represent H3N2 populations circulating one year after strain selection. Experts select strains based on experimental measurements of antigenic drift and predictions made by models from hemagglutinin sequences. We developed a novel influenza forecasting framework that integrates phenotypic measures of antigenic drift and functional constraint with previously published sequence-only fitness estimates. Forecasts informed by phenotypic measures of antigenic drift consistently outperformed previous sequence-only estimates, while sequence-only estimates of functional constraint surpassed more comprehensive experimentally-informed estimates. Importantly, the best models integrated estimates of both functional constraint and either antigenic drift phenotypes or recent population growth.Competing Interest StatementThe authors have declared no competing interest. |
Mitigating Pandemic Risk with Influenza A Virus Field Surveillance at a Swine-Human Interface (preprint)
Rambo-Martin BL , Keller MW , Wilson MM , Nolting JM , Anderson TK , Vincent AL , Bagal UR , Jang Y , Neuhaus EB , Davis CT , Bowman AS , Wentworth DE , Barnes JR . bioRxiv 2019 585588 Working overnight at a large swine exhibition, we identified an influenza A virus (IAV) outbreak in swine, nanopore-sequenced 13 IAV genomes from samples collected, and in real-time, determined that these viruses posed a novel risk to humans due to genetic mismatches between the viruses and current pre-pandemic candidate vaccine viruses (CVV). We developed and used a portable IAV sequencing and analysis platform called Mia (Mobile Influenza Analysis) to complete and characterize full-length consensus genomes approximately 18 hours after unpacking the mobile lab. Swine are important animal IAV reservoirs that have given rise to pandemic viruses via zoonotic transmission. Genomic analyses of IAV in swine are critical to understanding pandemic risk of viruses in this reservoir, and characterization of viruses circulating in exhibition swine enables rapid comparison to current seasonal influenza vaccines and CVVs. The Mia system rapidly identified three genetically distinct swine IAV lineages from three subtypes: A(H1N1), A(H3N2) and A(H1N2). Additional analysis of the HA protein sequences of the A(H1N2) viruses identified >30 amino acid differences between the HA1 portion of the hemagglutinin of these viruses and the most closely related pre-2009 CVV. All virus sequences were emailed to colleagues at CDC who initiated development of a synthetically derived CVV designed to provide an optimal antigenic match with the viruses detected in the exhibition. In subsequent months, this virus caused 13 infections in humans, and was the dominant variant virus in the US detected in 2018. Had this virus caused a severe outbreak or pandemic, our proactive surveillance efforts and CVV derivation would have provided an approximate 8 week time advantage for vaccine manufacturing. This is the first report of the use of field-derived nanopore sequencing data to initiate a real-time, actionable public health countermeasure. |
Detection and discrimination of influenza B Victoria lineage deletion variant viruses by real-time RT-PCR (preprint)
Shu B , Kirby MK , Warnes C , Sessions WM , Davis WG , Liu J , Wilson MM , Wentworth DE , Barnes JR . bioRxiv 2019 818617 Influenza B viruses have two genetically and antigenically distinct lineages, B/Victoria/2/1987-like (VIC) and B/Yamagata/16/1988-like (YAM) viruses, that emerged in the 1980s and co-circulate annually during the influenza season. During the 2016-2017 influenza season, influenza B/VIC lineage variant viruses emerged with two (K162N163) or three (K162N163D164) amino acid (AA) deletions in the hemagglutinin protein. Hemagglutination inhibition assays demonstrate that these deletion variant influenza B/VIC viruses are antigenically distinct from each other and from the progenitor B/VIC virus that lacks the deletion. Therefore, there are currently four antigenically distinct HA proteins expressed by influenza B co-circulating: B/YAM, B/VIC V1A (no deletion), B/VIC V1A.1 (two-AA deletion), and B/VIC V1A.2 and V1A.3 (three-AA deletion). The prevalence of these viruses differs across geographic regions, making it critical to have a sensitive, rapid diagnostic assay(s) that detect and distinguish these Influenza B variant viruses during surveillance. Here, we present a real time RT-PCR assay that targets the influenza B/VIC deletion region in the HA gene and detects and distinguishes the influenza B/VIC V1A, B/VIC V1A.1, B/VIC V1A.2 and B/VIC V1A.3 variant viruses, with no cross-reactivity. This assay can be run as a multiplex reaction, allowing for increased testing efficiency and reduced cost. Coupling this assay with the CDC Human Influenza Virus Real-Time RT-PCR Diagnostic Panel Influenza B Lineage Genotyping Kit results in rapid detection and characterization of circulating influenza B viruses. Having accurate and detailed surveillance information on these distinct Influenza B variant viruses will provide insight into the prevalence and geographic distribution and could aid in vaccine recommendations. |
Direct RNA Sequencing of the Complete Influenza A Virus Genome (preprint)
Keller MW , Rambo-Martin BL , Wilson MM , Ridenour CA , Shepard SS , Stark TJ , Neuhaus EB , Dugan VG , Wentworth DE , Barnes JR . bioRxiv 2018 300384 For the first time, a complete genome of an RNA virus has been sequenced in its original form. Previously, RNA was sequenced by the chemical degradation of radiolabelled RNA, a difficult method that produced only short sequences. Instead, RNA has usually been sequenced indirectly by copying it into cDNA, which is often amplified to dsDNA by PCR and subsequently analyzed using a variety of DNA sequencing methods. We designed an adapter to short highly conserved termini of the influenza virus genome to target the (-) sense RNA into a protein nanopore on the Oxford Nanopore MinION sequencing platform. Utilizing this method and total RNA extracted from the allantoic fluid of infected chicken eggs, we demonstrate successful sequencing of the complete influenza virus genome with 100% nucleotide coverage, 99% consensus identity, and 99% of reads mapped to influenza. By utilizing the same methodology we can redesign the adapter in order to expand the targets to include viral mRNA and (+) sense cRNA, which are essential to the viral life cycle. This has the potential to identify and quantify splice variants and base modifications, which are not practically measurable with current methods. |
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. |
Genetic and potential antigenic evolution of influenza A(H1N1)pdm09 viruses circulating in Kenya during 2009-2018 influenza seasons (preprint)
Owuor DC , de Laurent ZR , Nyawanda BO , Emukule GO , Kondor R , Barnes JR , Nokes DJ , Agoti CN , Chaves SS . medRxiv 2022 13 Background. Influenza viruses undergo rapid evolutionary changes, which requires continuous surveillance to monitor for genetic and potential antigenic changes in circulating viruses that can guide control and prevention decision making. Methods. We sequenced and phylogenetically analyzed A(H1N1)pdm09 virus genome sequences obtained from specimens collected from hospitalized patients of all ages with or without pneumonia between 2009 and 2018 from seven sentinel surveillance sites across Kenya. We compared these sequences with recommended vaccine strains during the study period to infer genetic and potential antigenic changes in circulating viruses and determinants of clinical outcome. Results. We generated and analyzed a total of 383 A(H1N1)pdm09 virus genome sequences. Phylogenetic analyses revealed that multiple genetic groups (clades, subclades, and subgroups) of A(H1N1)pdm09 virus circulated in Kenya over the study period; these evolved away from their vaccine strain, forming clades 7 and 6, subclades 6C, 6B, and 6B.1, and subgroups 6B.1A and 6B.1A1. Several amino acid substitutions among circulating viruses were associated with continued evolution of the viruses, especially in antigenic epitopes and receptor binding sites (RBS) of circulating viruses. Disease severity reduced with increase in age among children aged <5 years. Conclusion. Our study highlights the utility of genomic surveillance to monitor the evolutionary changes of influenza viruses. Routine influenza surveillance with broad geographic representation and whole genome sequencing capacity to inform on the severity of circulating strains could improve selection of influenza strains for inclusion in vaccines. Copyright The copyright holder for this preprint is the author/funder, who has granted medRxiv a license to display the preprint in perpetuity. It is made available under a CC-BY-NC-ND 4.0 International license. |
Identification of a Novel SARS-CoV-2 Delta-Omicron Recombinant Virus in the United States (preprint)
Lacek KA , Rambo-Martin BL , Batra D , Zheng XY , Sakaguchi H , Peacock T , Keller M , Wilson MM , Sheth M , Davis ML , Borroughs M , Gerhart J , Hassell N , Shepard SS , Cook PW , Lee J , Wentworth DE , Barnes JR , Kondor R , Paden CR . bioRxiv 2022 21 Recombination between SARS-CoV-2 virus variants can result in different viral properties (e.g., infectiousness or pathogenicity). In this report, we describe viruses with recombinant genomes containing signature mutations from Delta and Omicron variants. These genomes are the first evidence for a Delta-Omicron hybrid Spike protein in the United States. 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. |
Influenza A virus multicycle replication yields comparable viral population emergence in human respiratory and ocular cell types
Kieran TJ , DaSilva J , Stark TJ , York IA , Pappas C , Barnes JR , Maines TR , Belser JA . Microbiol Spectr 2023 11 (4) e0116623 ![]() While primarily considered a respiratory pathogen, influenza A virus (IAV) is nonetheless capable of spreading to, and replicating in, numerous extrapulmonary tissues in humans. However, within-host assessments of genetic diversity during multicycle replication have been largely limited to respiratory tract tissues and specimens. As selective pressures can vary greatly between anatomical sites, there is a need to examine how measures of viral diversity may vary between influenza viruses exhibiting different tropisms in humans, as well as following influenza virus infection of cells derived from different organ systems. Here, we employed human primary tissue constructs emulative of the human airway or corneal surface, and we infected both with a panel of human- and avian-origin IAV, inclusive of H1 and H3 subtype human viruses and highly pathogenic H5 and H7 subtype viruses, which are associated with both respiratory disease and conjunctivitis following human infection. While both cell types supported productive replication of all viruses, airway-derived tissue constructs elicited greater induction of genes associated with antiviral responses than did corneal-derived constructs. We used next-generation sequencing to examine viral mutations and population diversity, utilizing several metrics. With few exceptions, generally comparable measures of viral diversity and mutational frequency were detected following homologous virus infection of both respiratory-origin and ocular-origin tissue constructs. Expansion of within-host assessments of genetic diversity to include IAV with atypical clinical presentations in humans or in extrapulmonary cell types can provide greater insight into understanding those features most prone to modulation in the context of viral tropism. IMPORTANCE Influenza A virus (IAV) can infect tissues both within and beyond the respiratory tract, leading to extrapulmonary complications, such as conjunctivitis or gastrointestinal disease. Selective pressures governing virus replication and induction of host responses can vary based on the anatomical site of infection, yet studies examining within-host assessments of genetic diversity are typically only conducted in cells derived from the respiratory tract. We examined the contribution of influenza virus tropism on these properties two different ways: by using IAV associated with different tropisms in humans, and by infecting human cell types from two different organ systems susceptible to IAV infection. Despite the diversity of cell types and viruses employed, we observed generally similar measures of viral diversity postinfection across all conditions tested; these findings nonetheless contribute to a greater understanding of the role tissue type contributes to the dynamics of virus evolution within a human host. |
Risk for infection in humans after exposure to birds infected with highly pathogenic avian influenza A(H5N1) virus, United States, 2022
Kniss K , Sumner KM , Tastad KJ , Lewis NM , Jansen L , Julian D , Reh M , Carlson E , Williams R , Koirala S , Buss B , Donahue M , Palm J , Kollmann L , Holzbauer S , Levine MZ , Davis T , Barnes JR , Flannery B , Brammer L , Fry A . Emerg Infect Dis 2023 29 (6) 1215-1219 During February 7─September 3, 2022, a total of 39 US states experienced outbreaks of highly pathogenic avian influenza A(H5N1) virus in birds from commercial poultry farms and backyard flocks. Among persons exposed to infected birds, highly pathogenic avian influenza A(H5) viral RNA was detected in 1 respiratory specimen from 1 person. |
Author Correction: Direct RNA Sequencing of the Coding Complete Influenza A Virus Genome.
Keller MW , Rambo-Martin BL , Wilson MM , Ridenour CA , Shepard SS , Stark TJ , Neuhaus EB , Dugan VG , Wentworth DE , Barnes JR . Sci Rep 2018 8 (1) 15746 ![]() A correction to this article has been published and is linked from the HTML and PDF versions of this paper. The error has been fixed in the paper. |
SARS-CoV-2 spike D614G variant confers enhanced replication and transmissibility (preprint)
Zhou B , Thao TTN , Hoffmann D , Taddeo A , Ebert N , Labroussaa F , Pohlmann A , King J , Portmann J , Halwe NJ , Ulrich L , Trüeb BS , Kelly JN , Fan X , Hoffmann B , Steiner S , Wang L , Thomann L , Lin X , Stalder H , Pozzi B , de Brot S , Jiang N , Cui D , Hossain J , Wilson M , Keller M , Stark TJ , Barnes JR , Dijkman R , Jores J , Benarafa C , Wentworth DE , Thiel V , Beer M . bioRxiv 2020 During the evolution of SARS-CoV-2 in humans a D614G substitution in the spike (S) protein emerged and became the predominant circulating variant (S-614G) of the COVID-19 pandemic (1) . However, whether the increasing prevalence of the S-614G variant represents a fitness advantage that improves replication and/or transmission in humans or is merely due to founder effects remains elusive. Here, we generated isogenic SARS-CoV-2 variants and demonstrate that the S-614G variant has (i) enhanced binding to human ACE2, (ii) increased replication in primary human bronchial and nasal airway epithelial cultures as well as in a novel human ACE2 knock-in mouse model, and (iii) markedly increased replication and transmissibility in hamster and ferret models of SARS-CoV-2 infection. Collectively, our data show that while the S-614G substitution results in subtle increases in binding and replication in vitro , it provides a real competitive advantage in vivo , particularly during the transmission bottle neck, providing an explanation for the global predominance of S-614G variant among the SARS-CoV-2 viruses currently circulating. |
SARS-CoV-2 Delta-Omicron Recombinant Viruses, United States.
Lacek KA , Rambo-Martin BL , Batra D , Zheng XY , Hassell N , Sakaguchi H , Peacock T , Groves N , Keller M , Wilson MM , Sheth M , Davis ML , Borroughs M , Gerhart J , Shepard SS , Cook PW , Lee J , Wentworth DE , Barnes JR , Kondor R , Paden CR . Emerg Infect Dis 2022 28 (7) 1442-1445 ![]() ![]() To detect new and changing SARS-CoV-2 variants, we investigated candidate Delta-Omicron recombinant genomes from Centers for Disease Control and Prevention national genomic surveillance. Laboratory and bioinformatic investigations identified and validated 9 genetically related SARS-CoV-2 viruses with a hybrid Delta-Omicron spike protein. |
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. |
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