Computational Identification of Antigenicity-Associated Sites in the Hemagglutinin Protein of A/H1N1 Seasonal Influenza Virus

Ren, Xiaowei; Li, Yuefeng; Liu, Xiaoning; Shen, Xiping; Gao, Wenlong; Li, Juansheng

doi:10.1371/journal.pone.0126742

Cited by 23 publications

(28 citation statements)

References 30 publications

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“…However, to expand this result to other strains circulating in other geographical areas, cross‐neutralization results from different strains are required. Whereas Reference Laboratories for Avian influenza virus are focused on assessing and storing data related to virus neutralization from different strains measured by inhibition of hemagglutination (Ren et al, ), which facilitates the antigenic map reconstructions, this kind of information is unfortunately unavailable for CSFV. Therefore, the creation of a Reference Database containing virus cross‐neutralization results from different strains of CSFV facilitating the evaluation of the antigenic evolution for this viral agent will be a valuable aim to accomplish.…”

Section: Discussionmentioning

confidence: 99%

Positive selection pressure on E2 protein of classical swine fever virus drives variations in virulence, pathogenesis and antigenicity: Implication for epidemiological surveillance in endemic areas

Coronado

Rios

Frı́as

et al. 2019

Transbound Emerg Dis

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Classical swine fever (CSF), caused by CSF virus (CSFV), is considered one of the most important infectious diseases with devasting consequences for the pig industry. Recent reports describe the emergence of new CSFV strains resulting from the action of positive selection pressure, due mainly to the bottleneck effect generated by ineffective vaccination. Even though a decrease in the genetic diversity of the positively selected CSFV strains has been observed by several research groups, there is little information about the effect of this selective force on the virulence degree, antigenicity and pathogenicity of this type of strains. Hence, the aim of the current study was to determine the effect of the positive selection pressure on these three parameters of CSFV strains, emerged as result of the bottleneck effects induced by improper vaccination in a CSF‐endemic area. Moreover, the effect of the positively selected strains on the epidemiological surveillance system was assessed. By the combination of in vitro, in vivo and immunoinformatic approaches, we revealed that the action of the positive selection pressure induces a decrease in virulence and alteration in pathogenicity and antigenicity. However, we also noted that the evolutionary process of CSFV, especially in segregated microenvironments, could contribute to the gain‐fitness event, restoring the highly virulent pattern of the circulating strains. Besides, we denoted that the presence of low virulent strains selected by bottleneck effect after inefficient vaccination can lead to a relevant challenge for the epidemiological surveillance of CSF, contributing to under‐reports of the disease, favouring the perpetuation of the virus in the field. In this study, B‐cell and CTL epitopes on the E2 3D‐structure model were also identified. Thus, the current study provides novel and significant insights into variation in virulence, pathogenesis and antigenicity experienced by CSFV strains after the positive selection pressure effect.

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Section: Discussionmentioning

confidence: 99%

Positive selection pressure on E2 protein of classical swine fever virus drives variations in virulence, pathogenesis and antigenicity: Implication for epidemiological surveillance in endemic areas

Coronado

Rios

Frı́as

et al. 2019

Transbound Emerg Dis

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“…Groups of H1 antigenic sites were taken from Huang et al (53) and Ren et al (54), and H3 antigenic sites were taken from Smith et al (41), Steinbrück and McHardy (40), Koel et al (17), and Neher et al (39). The single group of N2 epitopic sites was taken from refs.…”

Section: Methodsmentioning

confidence: 99%

Allele-specific nonstationarity in evolution of influenza A virus surface proteins

Popova

Safina

Ptushenko

et al. 2019

Proc. Natl. Acad. Sci. U.S.A.

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Influenza A virus (IAV) is a major public health problem and a pandemic threat. Its evolution is largely driven by diversifying positive selection so that relative fitness of different amino acid variants changes with time due to changes in herd immunity or genomic context, and novel amino acid variants attain fitness advantage. Here, we hypothesize that diversifying selection also has another manifestation: the fitness associated with a particular amino acid variant should decline with time since its origin, as the herd immunity adapts to it. By tracing the evolution of antigenic sites at IAV surface proteins, we show that an amino acid variant becomes progressively more likely to become replaced by another variant with time since its origin—a phenomenon we call “senescence.” Senescence is particularly pronounced at experimentally validated antigenic sites, implying that it is largely driven by host immunity. By contrast, at internal sites, existing variants become more favorable with time, probably due to arising contingent mutations at other epistatically interacting sites. Our findings reveal a previously undescribed facet of adaptive evolution and suggest approaches for prediction of evolutionary dynamics of pathogens.

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“…Although antigenic distances between vaccine strains have been measured experimentally [ 7 – 9 ], these studies use only a small fraction of the viruses that have been isolated and do not include the many genetically unique strains that circulate annually. Typically, measurement of the antigenic relatedness between viruses involves production of convalescent ferret antiserum and use of functional antibody binding assays, such as the hemagglutination inhibition (HAI) assay.…”

Section: Introductionmentioning

confidence: 99%

Antigenic cartography of H1N1 influenza viruses using sequence-based antigenic distance calculation

et al. 2018

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BackgroundThe ease at which influenza virus sequence data can be used to estimate antigenic relationships between strains and the existence of databases containing sequence data for hundreds of thousands influenza strains make sequence-based antigenic distance estimates an attractive approach to researchers. Antigenic mismatch between circulating strains and vaccine strains results in significantly decreased vaccine effectiveness. Furthermore, antigenic relatedness between the vaccine strain and the strains an individual was originally primed with can affect the cross-reactivity of the antibody response. Thus, understanding the antigenic relationships between influenza viruses that have circulated is important to both vaccinologists and immunologists.ResultsHere we develop a method of mapping antigenic relationships between influenza virus stains using a sequence-based antigenic distance approach (SBM). We used a modified version of the p-all-epitope sequence-based antigenic distance calculation, which determines the antigenic relatedness between strains using influenza hemagglutinin (HA) genetic coding sequence data and provide experimental validation of the p-all-epitope calculation. We calculated the antigenic distance between 4838 H1N1 viruses isolated from infected humans between 1918 and 2016. We demonstrate, for the first time, that sequence-based antigenic distances of H1N1 Influenza viruses can be accurately represented in 2-dimenstional antigenic cartography using classic multidimensional scaling. Additionally, the model correctly predicted decreases in cross-reactive antibody levels with 87% accuracy and was highly reproducible with even when small numbers of sequences were used.ConclusionThis work provides a highly accurate and precise bioinformatics tool that can be used to assess immune risk as well as design optimized vaccination strategies. SBM accurately estimated the antigenic relationship between strains using HA sequence data. Antigenic maps of H1N1 virus strains reveal that strains cluster antigenically similar to what has been reported for H3N2 viruses. Furthermore, we demonstrated that genetic variation differs across antigenic sites and discuss the implications.Electronic supplementary materialThe online version of this article (10.1186/s12859-018-2042-4) contains supplementary material, which is available to authorized users.

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Computational Identification of Antigenicity-Associated Sites in the Hemagglutinin Protein of A/H1N1 Seasonal Influenza Virus

Cited by 23 publications

References 30 publications

Positive selection pressure on E2 protein of classical swine fever virus drives variations in virulence, pathogenesis and antigenicity: Implication for epidemiological surveillance in endemic areas

Positive selection pressure on E2 protein of classical swine fever virus drives variations in virulence, pathogenesis and antigenicity: Implication for epidemiological surveillance in endemic areas

Allele-specific nonstationarity in evolution of influenza A virus surface proteins

Antigenic cartography of H1N1 influenza viruses using sequence-based antigenic distance calculation

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