NAction! How Can Neuraminidase-Based Immunity Contribute to Better Influenza Virus Vaccines?

Krammer, Florian; Fouchier, Ron A. M.; Eichelberger, Maryna C.; Webby, Richard J.; Shaw-Saliba, Kathryn; Wan, Hongquan; Wilson, Patrick C.; Compans, Richard W.; Skountzou, Ioanna; Monto, Arnold S.

doi:10.1128/mbio.02332-17

Cited by 234 publications

(234 citation statements)

References 100 publications

(143 reference statements)

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“…Examples of these alternative immune correlates include the serum virus neutralization antibody titer, 18,19 which often, but not always, aligns with the serum HI antibody titer. In addition, serum neuraminidase inhibition (NI) antibody titers have been identified as independent correlates of protection in field studies by Monto et al and Couch et al 9,10,20 Furthermore, this is supported by recent data from an H1N1 human challenge model. 21 Of note, anti-HA stalk antibodies can interfere with H6NX-based NI assays which have to be taken into account in their interpretation.…”

Section: E Xis Ting and Novel Correl Ate S Of Protec Ti Onmentioning

confidence: 84%

Meeting report and review: Immunological assays and correlates of protection for next‐generation influenza vaccines

Krammer

Weir

Engelhardt

et al. 2019

Influenza Resp Viruses

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Background This report summarizes the discussions and conclusions from the “Immunological Assays and Correlates of Protection for Next‐Generation Influenza Vaccines” meeting which took place in Siena, Italy, from March 31, 2019, to April 2, 2019. Conclusions Furthermore, we review current correlates of protection against influenza virus infection and disease and their usefulness for the development of next generation broadly protective and universal influenza virus vaccines.

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Section: E Xis Ting and Novel Correl Ate S Of Protec Ti Onmentioning

confidence: 84%

Meeting report and review: Immunological assays and correlates of protection for next‐generation influenza vaccines

Krammer

Weir

Engelhardt

et al. 2019

Influenza Resp Viruses

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“…Monoclonal antibodies (mAbs) administered either prophylactically or therapeutically have been proposed as a strategy to provide immediate immunity and augment existing vaccines and drugs in combatting seasonal and pandemic influenza infection. Broadly neutralizing antibodies against conserved epitopes of the haemagglutinin (HA) stem and head, and antibodies against the neuraminidase (NA) are candidates for human treatment 1, 2 . Both prophylactic and therapeutic administration of these antibodies have been shown to be effective in the mouse and ferret 3–10 .…”

mentioning

confidence: 99%

Establishment of a pig influenza challenge model for evaluation of monoclonal antibody delivery platforms

McNee

Smith

Holzer

et al. 2020

Preprint

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31Monoclonal antibodies are a possible adjunct to vaccination and drugs in treatment of 32 influenza virus infection. However questions remain whether small animal models 33 accurately predict efficacy in humans. We have established the pig, a large natural 34 host animal for influenza, with many physiological similarities to humans, as a robust 35 model for testing monoclonal antibodies. We show that a strongly neutralizing 36 monoclonal antibody (2-12C) against the hemagglutinin head administered 37prophylactically at 15 mg/kg reduced viral load and lung pathology after pandemic 38 H1N1 influenza challenge. A lower dose of 1 mg/kg of 2-12C or a DNA plasmid 39 encoded version of 2-12C, reduced pathology and viral load in the lungs, but not viral 40 shedding in nasal swabs. We propose that the pig influenza model will be useful for 41 testing candidate monoclonal antibodies and emerging delivery platforms prior to 42 human trials. 43 therapeutic administration to reduce viral load after infection has been established. 94We went on to evaluate the potential of an in vivo produced 2-12C using synthetic 95 dMAb technology in support of the translation of this technology to humans as an 96 immunoprophylactic. 97 98 Results: 99Establishment of a prophylactic pig influenza challenge model with recombinant 100 2-12C mAb. To establish a positive control protective mAb and delivery method in the 101 pig influenza model we tested the strongly neutralizing human IgG1 anti-head 2-12C 102 mAb 31 in a prophylactic experiment. We administered 15 mg/kg of 2-12C intravenously 103 and the control groups received an isotype matched IgG1 mAb or the diluent. Twenty-104 four hours later the pigs were challenged with pandemic swine H1N1 isolate, 105 A/swine/England/1353/2009 (pH1N1) and 4 days later culled to assess viral load and 106 pathology (Fig. 1a). 2-12C significantly decreased viral load in nasals swabs on each 107 day over the course of infection, although the decrease was less on days 2 and 3 than 108 days 1 and 4 (Fig. 1b). The total viral load in nasal swabs over the 4 days in animals 109 treated with 2-12C was also significantly less as determined by the area under the 110 curve (AUC) compared to diluent and isotype controls (p=0.0267 and p=0.021). Viral 111 load in the 2-12C group was significantly reduced in the BAL and no virus was detected 112 in the lungs at 4 days post infection (DPI). Overall 2-12C had a clear effect on viral 113 load in nasal swabs, BAL and lung. 114The isotype and diluent control groups showed the most severe gross 115 pathology and histopathology scores (Fig. 2a). The red tan areas of pulmonary 116 consolidation were present mainly in the cranial and middle lung lobes of animals from 117 the isotype and diluent groups, but no lesions were found in the 2-12C group (Fig. 2b). 118 6 Similarly, necrotizing bronchiolitis and bronchial and alveolar exudation, and mild 119 thickening of the alveolar septa was shown in the animals from both control groups. 120

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“…Neuraminidase inhibitory antibodies have previously been shown to inhibit virus replication by inhibiting enzymatic activity of the protein or by inducing a cellular immune response through antibody dependent cellular cytotoxicity (ADCC) [12, 20, 30, 33] or a combination of both. With two recombinant viruses only differing in the 245 NA glycosylation sequence, we sought to understand how this glycan would impact the ability of 229-1G03 and 235-1C02 to neutralize virus infectivity.…”

Section: Resultsmentioning

confidence: 99%

“…In recent years the NA protein has had renewed interest as a relatively conserved protein that’s an attractive vaccine target[12, 22, 41]. In some respects, the NA protein is an excellent candidate for a universal vaccine.…”

Section: Discussionmentioning

confidence: 99%

“…Antibody response to NA are not induced effectively in all age groups by current influenza vaccines because the amount of NA is not standardized in vaccine preparations and the NA protein conformation is more sensitive to the current vaccine production methods than the HA protein[12, 20, 43, 44]. While other methods for inducing NA immunity are being developed, our data show that two amino acid changes in N2 NA can lead to escape from antibodies that bind to one of the most universal antigenic sites of the protein.…”

Section: Discussionmentioning

confidence: 99%

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Neuraminidase antigenic drift of Influenza A virus H3N2 clade 3c.2a viruses alters virus replication, enzymatic activity and inhibitory antibody binding

Powell

Pekosz

2020

Preprint

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27 In the 2014-2015 influenza season a novel neuraminidase (NA) genotype emerged in 28 the Johns Hopkins Center of Excellence for Influenza Research and Surveillance (JH 29 CEIRS) surveillance network as well as globally. This novel genotype encoded a 30 glycosylation site at position 245-247 in the NA protein from clade 3c.2a H3N2 viruses.31 In the years following the 2014-2015 season, this novel NA glycosylation genotype 32 quickly dominated the human H3N2 population of viruses. To assess the effect this 33 novel glycosylation has on virus fitness and antibody binding, recombinant viruses with 34 (NA Gly+) or without (NA Gly-) the novel NA glycosylation were created. Viruses with 35 the 245 NA Gly+ genotype grew to a significantly lower infectious virus titer on primary, 36 differentiated human nasal epithelial cells (hNEC) compared to viruses with the 245 NA 37 Gly-genotype, but growth was similar on immortalized cells. The 245 NA Gly+ blocked 38 human and rabbit monoclonal antibodies that target the enzymatic site from binding to 39 their epitope. Additionally, viruses with the 245 NA Gly+ genotype had significantly 40 lower enzymatic activity compared to viruses with the 245 NA Gly-genotype. Human 41 monoclonal antibodies that target residues near the 245 NA glycosylation were less 42 effective at inhibiting NA enzymatic activity and virus replication of viruses encoding an 43 NA Gly+ protein compared to ones encoding NA Gly-protein. Additionally, a 44 recombinant H6N2 virus with the 245 NA Gly+ protein was more resistant to enzymatic 45 inhibition from convalescent serum from H3N2-infected humans compared to viruses 46 with the 245 NA Gly-genotype. Finally, the 245 NA Gly+ protected from NA antibody 47 mediated virus neutralization. These results suggest that while the 245 NA Gly+ 48 decreases virus replication in hNECs and decreases enzymatic activity, the 49 glycosylation blocks the binding of monoclonal and human serum NA specific antibodies 50 that would otherwise inhibit enzymatic activity and virus replication. Influenza virus infects millions of people worldwide and leads to thousands of deaths 74 and millions in economic loss each year. During the 2014/2015 season circulating 75 human H3N2 viruses acquired a novel mutation in the neuraminidase (NA) protein. This 76 mutation has since fixed in human H3N2 viruses. This mutation at position 245 through 77 247 in the amino acid sequence of NA encoded an N-linked glycosylation. Here, we 78 studied how this N-linked glycosylation impacts virus fitness and protein function. We 79 found that this N-linked glycosylation on the NA protein decreased viral replication 80 fitness on human nasal epithelial cells (hNEC) but not immortalized Madin-Darby 81 Canine Kidney (MDCK) cells. We also determined this glycosylation decreases NA 82 enzymatic activity, enzyme kinetics and affinity for substrate. Furthermore, we show that 83 this N-linked glycosylation at position 245 blocks some NA specific inhibitory antibodies 84 from binding to the protein, inhibiting enzyma...

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NAction! How Can Neuraminidase-Based Immunity Contribute to Better Influenza Virus Vaccines?

Cited by 234 publications

References 100 publications

Meeting report and review: Immunological assays and correlates of protection for next‐generation influenza vaccines

Meeting report and review: Immunological assays and correlates of protection for next‐generation influenza vaccines

Establishment of a pig influenza challenge model for evaluation of monoclonal antibody delivery platforms

Neuraminidase antigenic drift of Influenza A virus H3N2 clade 3c.2a viruses alters virus replication, enzymatic activity and inhibitory antibody binding

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