A Computational Framework for Influenza Antigenic Cartography

Cai, Zhipeng; Zhang, Tong; Wan, Xiu‐Feng

doi:10.1371/journal.pcbi.1000949

Cited by 130 publications

(168 citation statements)

References 27 publications

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“…. To further address this question, we used antigenic cartography, which provides easily interpretable measures and visualization of multidimensional antigenic relationships and has previously been used to study antigenic differences in influenza virus strains (40,49). This analysis provided further support for the idea that within-host changes in the virus can equal or exceed those differences seen across successive outbreak strains, with the antigenic space between P.D302 and both GII.4-2006b (D ϭ 9.91) and P.D1 (D ϭ 9.15) being greater than the average between the consecutive outbreak strains used in this study (average D ϭ 4.98; range, 2.11 to 12.11), and mirrors the global difference between early GII.4 isolates (1987, 1997, and 2002) and contemporary strains (2006b, 2009, and 2012).…”

Section: Discussionmentioning

confidence: 99%

“…Antigenic cartography. We utilized multidimensional-scaling (MDS) approaches as described and implemented within the AntigenMap 3D software (39,40). The EC 50 blockade titers of various sera against a panel of VLPs were normalized to the maximum blockade titer of each serum, as well as to the maximum overall blockade titer across sera (normalization method 1 in AntigenMap 3D).…”

Section: Methodsmentioning

confidence: 99%

“…Antigenic cartography. In order to further describe and visualize the differences between the antigenic properties of virus strains, we utilized the MDS approach known as antigenic cartography (39,40). Specifically, we used the pipeline described in AntigenMap 3D (39) (Fig.…”

Section: Table 2 Gii4 Mouse and Human Mab Eia Reactivities With Chromentioning

confidence: 99%

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Within-Host Evolution Results in Antigenically Distinct GII.4 Noroviruses

Debbink

Lindesmith

Ferris

et al. 2014

J Virol

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Genogroup II, genotype 4 (GII.4) noroviruses are known to rapidly evolve, with the emergence of a new primary strain every 2 to 4 years as herd immunity to the previously circulating strain is overcome. Because viral genetic diversity is higher in chronic than in acute infection, chronically infected immunocompromised people have been hypothesized to be a potential source for new epidemic GII.4 strains. However, while some capsid protein residues are under positive selection and undergo patterned changes in sequence variation over time, the relationships between genetic variation and antigenic variation remains unknown. Based on previously published GII.4 strains from a chronically infected individual, we synthetically reconstructed virus-like particles (VLPs) representing early and late isolates from a small-bowel transplant patient chronically infected with norovirus, as well as the parental GII.4-2006b strain. We demonstrate that intrahost GII.4 evolution results in the emergence of antigenically distinct strains over time, comparable to the variation noted between the chronologically predominant GII.4 strains GII.4-2006b and GII.4-2009. Our data suggest that in some individuals the evolution that occurs during a chronic norovirus infection overlaps with changing antigenic epitopes that are associated with successive outbreak strains and may select for isolates that are potentially able to escape herd immunity from earlier isolates. IMPORTANCENoroviruses are agents of gastrointestinal illness, infecting an estimated 21 million people per year in the United States alone. In healthy individuals, symptomatic infection typically resolves within 24 to 48 h. However, symptoms may persist for years in immunocompromised individuals, and development of successful treatments for these patients is a continuing challenge. This work is relevant to the design of successful norovirus therapeutics for chronically infected patients; provides support for previous assertions that chronically infected individuals may serve as reservoirs for new, antigenically unique emergent strains; and furthers our understanding of genogroup II, genotype 4 (GII.4) norovirus immune-driven molecular evolution.

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Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

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Within-Host Evolution Results in Antigenically Distinct GII.4 Noroviruses

Debbink

Lindesmith

Ferris

et al. 2014

J Virol

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“…Antigenic maps were constructed using AntigenMap (http://sysbio.cvm.msstate. edu/AntigenMap) (33,34) HI assay results, polyPLA results suggested that subtype H3N2 swine IAVs did not react with the negative-control H1N1 virus and polyclonal antibodies.…”

Section: Resultsmentioning

confidence: 99%

“…The antigenic maps of H3N2 swine IAVs were constructed using AntigenMap (http://sysbio.cvm.msstate.edu/AntigenMap) and data derived from the HI assay or the polyPLA (33,34). The data entry with an HI titer of Ͻ1:10 or a ΔC T of Ͻ3.00 was determined as a low reactor for the data from HI or the polyPLA, respectively.…”

Section: Methodsmentioning

confidence: 99%

Detection of Antigenic Variants of Subtype H3 Swine Influenza A Viruses from Clinical Samples

Martin

Bowman

et al. 2017

J Clin Microbiol

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A large population of genetically and antigenically diverse influenza A viruses (IAVs) are circulating among the swine population, playing an important role in influenza ecology. Swine IAVs not only cause outbreaks among swine but also can be transmitted to humans, causing sporadic infections and even pandemic outbreaks. Antigenic characterizations of swine IAVs are key to understanding the natural history of these viruses in swine and to selecting strains for effective vaccines. However, influenza outbreaks generally spread rapidly among swine, and the conventional methods for antigenic characterization require virus propagation, a timeconsuming process that can significantly reduce the effectiveness of vaccination programs. We developed and validated a rapid, sensitive, and robust method, the polyclonal serum-based proximity ligation assay (polyPLA), to identify antigenic variants of subtype H3N2 swine IAVs. This method utilizes oligonucleotide-conjugated polyclonal antibodies and quantifies antibody-antigen binding affinities by quantitative reverse transcription-PCR (RT-PCR). Results showed the assay can rapidly detect H3N2 IAVs directly from nasal wash or nasal swab samples collected from laboratorychallenged animals or during influenza surveillance at county fairs. In addition, polyPLA can accurately separate the viruses at two contemporary swine IAV antigenic clusters (H3N2 swine IAV-␣ and H3N2 swine IAV-ß) with a sensitivity of 84.9% and a specificity of 100.0%. The polyPLA can be routinely used in surveillance programs to detect antigenic variants of influenza viruses and to select vaccine strains for use in controlling and preventing disease in swine.

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Bayesian nonparametric clustering in phylogenetics: modeling antigenic evolution in influenza

Cybis

Sinsheimer

Bedford

et al. 2017

Statistics in Medicine

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Influenza is responsible for up to 500,000 deaths every year, and antigenic variability represents much of its epidemiological burden. To visualize antigenic differences across many viral strains, antigenic cartography methods use multidimensional scaling on binding assay data to map influenza antigenicity onto a low-dimensional space. Analysis of such assay data ideally leads to natural clustering of influenza strains of similar antigenicity that correlate with sequence evolution. To understand the dynamics of these antigenic groups, we present a framework that jointly models genetic and antigenic evolution by combining multidimensional scaling of binding assay data, Bayesian phylogenetic machinery and nonparametric clustering methods. We propose a phylogenetic Chinese restaurant process that extends the current process to incorporate the phylogenetic dependency structure between strains in the modeling of antigenic clusters. With this method, we are able to use the genetic information to better understand the evolution of antigenicity throughout epidemics, as shown in applications of this model to H1N1 influenza. Copyright © 2017 John Wiley & Sons, Ltd.

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A Computational Framework for Influenza Antigenic Cartography

Cited by 130 publications

References 27 publications

Within-Host Evolution Results in Antigenically Distinct GII.4 Noroviruses

Within-Host Evolution Results in Antigenically Distinct GII.4 Noroviruses

Detection of Antigenic Variants of Subtype H3 Swine Influenza A Viruses from Clinical Samples

Bayesian nonparametric clustering in phylogenetics: modeling antigenic evolution in influenza

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