Whole-Genome Analysis of Human Influenza A Virus Reveals Multiple Persistent Lineages and Reassortment among Recent H3N2 Viruses

Holmes, Edward C.; Ghedin, Elodie; Miller, Naomi; Taylor, Jill; Bào, Yīmíng; George, Kirsten St.; Grenfell, Bryan T.; Salzberg, Steven L.; Fraser, Claire M.; Lipman, David J.; Taubenberger, Jeffery K.

doi:10.1371/journal.pbio.0030300

Cited by 349 publications

(412 citation statements)

References 57 publications

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“…Recent studies of the population genetics of influenza based on the whole genome show that influenza is considerably more polymorphic than previously thought in particular in its internal structures and that reassortment may generate at least some of the novel viral variants (Holmes et al, 2005). These findings question our interpretation of the relatedness among strains as solely characterized by amino-acid differences in the HA-gene but not the relatednesses themselves as they may be seen as a schematic representation of the observed cross-reactivity.…”

Section: Discussionmentioning

confidence: 92%

“…Specific strains appear to be well suited for the low-transmission period (Gog et al, 2003) and in addition genetic and antigenic variation is always present at least at the global and regional scales (Plotkin et al, 2002;Holmes et al, 2005). Still within a single epidemic, variation appears to be 6 limited (Schweiger et al, 2002;Shih et al, 2005).…”

Section: Derivation Of Basic Modelmentioning

confidence: 99%

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Shaping the phylogenetic tree of influenza by cross-immunity

Andreasen

Sasaki

2006

Theoretical Population Biology

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Section: Discussionmentioning

confidence: 92%

Section: Derivation Of Basic Modelmentioning

confidence: 99%

Shaping the phylogenetic tree of influenza by cross-immunity

Andreasen

Sasaki

2006

Theoretical Population Biology

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“…Genome segmentation complements the high mutation rate of IAV by facilitating reassortment, which can maximize positive intergenic epistasis (2)(3)(4)(5) and allow selective elimination of segments with deleterious mutations (6,7). Although reassortment is the most obvious and best-characterized benefit of segmentation, there are likely additional evolutionary advantages.…”

mentioning

confidence: 99%

Influenza A virus nucleoprotein selectively decreases neuraminidase gene-segment packaging while enhancing viral fitness and transmissibility

Brooke

Ince

Wei

et al. 2014

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

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The influenza A virus (IAV) genome is divided into eight distinct RNA segments believed to be copackaged into virions with nearly perfect efficiency. Here, we describe a mutation in IAV nucleoprotein (NP) that enhances replication and transmission in guinea pigs while selectively reducing neuraminidase (NA) gene segment packaging into virions. We show that incomplete IAV particles lacking gene segments contribute to the propagation of the viral population through multiplicity reactivation under conditions of widespread coinfection, which we demonstrate commonly occurs in the upper respiratory tract of guinea pigs. NP also dramatically altered the functional balance of the viral glycoproteins on particles by selectively decreasing NA expression. Our findings reveal novel functions for NP in selective control of IAV gene packaging and balancing glycoprotein expression and suggest a role for incomplete gene packaging during host adaptation and transmission.influenza virus | genome segmentation | genome packaging | nucleoprotein | host adaptation S easonal influenza A virus (IAV) remains a major public health threat, causing tens of thousands of deaths each year in the United States alone (1). Morbidity and mortality rates can increase dramatically when a zoonotic strain adapts to circulate in humans, triggering a pandemic. The continuing toll exerted by IAV stems from its remarkable adaptability, which enables it to move between widely divergent host species and also evade herd immunity within each species. Defining the specific mechanisms that mediate IAV adaptation is essential to improving anti-IAV vaccines, therapeutics, and pandemic surveillance.The IAV genome consists of eight negative-sense RNA segments, each of which is required for productive infection. Genome segmentation complements the high mutation rate of IAV by facilitating reassortment, which can maximize positive intergenic epistasis (2-5) and allow selective elimination of segments with deleterious mutations (6, 7). Although reassortment is the most obvious and best-characterized benefit of segmentation, there are likely additional evolutionary advantages.Genome segmentation imposes the substantial constraint of maintaining a gene-packaging mechanism to produce fully infectious virions (8). For IAV, it is widely believed that a single copy of each segment is packaged into progeny virions with nearly perfect efficiency, resulting in an equimolar ratio of the segments at the population level (9-12). Confounding this model, we recently demonstrated that most IAV virions fail to express one or more gene products (13). This finding raises the possibility that in some circumstances incomplete influenza gene packaging is evolutionarily neutral and possibly even advantageous (14).The viral glycoproteins HA and neuraminidase (NA) are encoded by separate genome segments. HA attaches IAV to terminal sialic acid residues on the host cell surface, enabling viral entry. By hydrolyzing sialic acids, NA detaches budding virions and neutralizes HA-inhibiting glyco...

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“…The fragmented nature of the genome allows the exchange of gene segments when two or more influenza viruses coinfect the same cell, in a process named "genetic reassortment" (4). Genetic reassortment is a major feature of influenza evolution and cross-species transmission and also is important for the generation of antigenically novel isolates by introducing novel HA segments in compatible genetic backgrounds (5)(6)(7). Future pandemic viruses most likely will carry different HA genes to which human populations are immunologically naive.…”

mentioning

confidence: 99%

Critical role of segment-specific packaging signals in genetic reassortment of influenza A viruses

Essere

Yver

Gavazzi

et al. 2013

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

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The fragmented nature of the influenza A genome allows the exchange of gene segments when two or more influenza viruses infect the same cell, but little is known about the rules underlying this process. Here, we studied genetic reassortment between the A/Moscow/10/99 (H3N2, MO) virus originally isolated from human and the avian A/Finch/England/2051/91 (H5N2, EN) virus and found that this process is strongly biased. Importantly, the avian HA segment never entered the MO genetic background alone but always was accompanied by the avian PA and M fragments. Introduction of the 5′ and 3′ packaging sequences of HA MO into an otherwise HA EN backbone allowed efficient incorporation of the chimerical viral RNA (vRNA) into the MO genetic background. Furthermore, forcing the incorporation of the avian M segment or introducing five silent mutations into the human M segment was sufficient to drive coincorporation of the avian HA segment into the MO genetic background. These silent mutations also strongly affected the genotype of reassortant viruses. Taken together, our results indicate that packaging signals are crucial for genetic reassortment and that suboptimal compatibility between the vRNA packaging signals, which are detected only when vRNAs compete for packaging, limit this process.hemagglutinin | RNA packaging

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Whole-Genome Analysis of Human Influenza A Virus Reveals Multiple Persistent Lineages and Reassortment among Recent H3N2 Viruses

Cited by 349 publications

References 57 publications

Shaping the phylogenetic tree of influenza by cross-immunity

Shaping the phylogenetic tree of influenza by cross-immunity

Influenza A virus nucleoprotein selectively decreases neuraminidase gene-segment packaging while enhancing viral fitness and transmissibility

Critical role of segment-specific packaging signals in genetic reassortment of influenza A viruses

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