Universal influenza virus vaccines: what can we learn from the human immune response following exposure to H7 subtype viruses?

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Frontiers of Medicine

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Front. Med.

2017, Vol. 11

Issue (4) : 471-479 https://doi.org/10.1007/s11684-017-0602-z

REVIEW

Universal influenza virus vaccines: what can we learn from the human immune response following exposure to H7 subtype viruses?

Daniel Stadlbauer^1,², Raffael Nachbagauer¹, Philip Meade^1,³, Florian Krammer¹(

)

¹. Department of Microbiology, Icahn School of Medicine at Mount Sinai, New York, NY 10024, USA
². Department of Biotechnology, University of Natural Resources and Life Sciences, 1190, Vienna, Austria
³. Graduate School of Biomedical Sciences, Icahn School of Medicine at Mount Sinai, New York, NY 10024, USA

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Abstract

Several universal influenza virus vaccine candidates based on eliciting antibodies against the hemagglutinin stalk domain are in development. Typically, these vaccines induce responses that target group 1 or group 2 hemagglutinins with little to no cross-group reactivity and protection. Similarly, the majority of human anti-stalk monoclonal antibodies that have been isolated are directed against group 1 or group 2 hemagglutinins with very few that bind to hemagglutinins of both groups. Here we review what is known about the human humoral immune response to vaccination and infection with H7 subtype influenza viruses on a polyclonal and monoclonal level. It seems that unlike vaccination with H5 hemagglutinin, which induces antibody responses mostly restricted to the group 1 stalk domain, H7 exposure induces both group 2 and cross-group antibody responses. A better understanding of this phenomenon and the underlying mechanisms might help to develop future universal influenza virus vaccine candidates.

Keywords universal influenza virus vaccine hemagglutinin stalk H7N9

Corresponding Author(s): Florian Krammer

Just Accepted Date: 30 October 2017 Online First Date: 21 November 2017 Issue Date: 04 December 2017

Cite this article:

Daniel Stadlbauer,Raffael Nachbagauer,Philip Meade, et al. Universal influenza virus vaccines: what can we learn from the human immune response following exposure to H7 subtype viruses?[J]. Front. Med., 2017, 11(4): 471-479.

URL:

https://academic.hep.com.cn/fmd/EN/10.1007/s11684-017-0602-z
https://academic.hep.com.cn/fmd/EN/Y2017/V11/I4/471

Fig.1 Structure of influenza A virus hemagglutinin and phylogenetic tree of influenza A and B hemagglutinins. (A) An HA timer with the membrane distal globular head domain visualized in dark red and the membrane proximal stalk domain shown in blue. Cysteines 52 and 277 (H3 numbering), which are the demarcation line between head and stalk, are shown in yellow. The figure is based on PDB # 1TI8 [27]. (B) Phylogenetic tree of influenza A and B hemagglutinins based on amino acid sequence. Influenza A HAs are separated into groups 1 and 2 based on their sequence. HA clades and subtypes are annotated. H1 and H5 (group 1) and H3 and H7 (group 2) are marked by stars. The scale bar represents % amino acid difference. The sequences were assembled in Clustal Omega and visualized in FigTree.

Fig.2 Reactivity of human sera of different age groups to diverse influenza virus HAs. (A) Human serum samples from three different age cohorts were tested by ELISA against recombinant HA proteins including all influenza A subtypes. The birth ranges for each cohort are indicated in green for 18−20 year olds (n = 30), 33−44 year olds (n = 30) and 49−64 year olds (n = 30). The blue bars indicate circulating group 1 viruses and the red bars indicate circulating group 2 viruses. Serum samples were collected in 2014. (B–D) The ELISA endpoint titers are shown on the y-axis. Each point indicates the geometric mean titer of 30 individuals. The error bars show the 95% confidence intervals. Blue circles show group 1 HAs and red triangles show group 2 HAs. The x-axis indicates the difference of the analyzed HAs to both H1 (A/New Caledonia/20/99; NC99) and H3 (A/Philippines/2/1982; Phil82). The percent similarities for each strain were calculated and the percent difference to Phil82 was subtracted from the percent difference to NC99 for each HA. This resulted in an alignment that shows HAs more closely related to H1, but more distantly related to H3 on the left side and vice versa. HAs that are distantly related to both H1 and H3 are shown toward in the middle of the graph. (B) Sera from 18 to 20 year olds. (C) Sera from 33 to 44 year olds. (D) Sera from 49 to 64 year olds. Figures are adapted from Ref. [28].

Fig.3 The immune response of human individuals with pre-existing H1 and H3 immunity to H5 vaccination or H7 exposure. Hemagglutinins (H1, H3, H5, H7) are shown as monomers (based on PDB # 1TI8) for simplicity. (A) Low levels of pre-existing anti-stalk immunity to H1 (pink head domain, orange stalk domain, group 1 HA) and to H3 (brown head, green stalk, group 2) exists in the human population. Typically anti-group 1 HA stalk antibody (yellow) levels are higher than anti-group 2 HA stalk antibody (green) levels. The baseline level of cross-group stalk antibodies (yellow and green) is unclear and likely very low. Antibodies binding to the globular head domain are not shown. (B) Vaccination with H5 HA (purple head, orange stalk) leads to a strong increase of mostly group 1 reactive stalk antibodies (biased toward the VH1-69 germline) and very few cross-group stalk antibodies. (C) Exposure to H7 HA (blue head, green stalk) induces fewer anti-stalk antibodies overall but a relatively larger proportion of cross-group reactive stalk antibodies (focused toward VH1-18, VH6-1 and other germlines).

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