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Antigenic drift and immunity gap explain reduction in protective responses against influenza A(H1N1)pdm09 and A(H3N2) viruses during the COVID-19 pandemic: a cross-sectional study of human sera collected in 2019, 2021, 2022, and 2023
Virology Journal volume 21, Article number: 57 (2024)
Abstract
Background
Non-pharmaceutical interventions implemented during the COVID-19 pandemic resulted in a marked reduction in influenza infections globally. The absence of influenza has raised concerns of waning immunity, and potentially more severe influenza seasons after the pandemic.
Methods
To evaluate immunity towards influenza post-COVID-19 pandemic we have assessed influenza A epidemics in Norway from October 2016 to June 2023 and measured antibodies against circulating strains of influenza A(H1N1)pdm09 and A(H3N2) in different age groups by hemagglutination inhibition (HAI) assays in a total of 3364 serum samples collected in 2019, 2021, 2022 and 2023.
Results
Influenza epidemics in Norway from October 2016 until June 2023 were predominately influenza As, with a mixture of A(H1N1)pdm09 and A(H3N2) subtype predominance. We did not observe higher numbers of infections during the influenza epidemics following the COVID-19 pandemic than in pre-COVID-19 seasons. Frequencies of protective HAI titers against A(H1N1)pdm09 and A(H3N2) viruses were reduced in sera collected in 2021 and 2022, compared to sera collected in 2019. The reduction could, however, largely be explained by antigenic drift of new virus strains, as protective HAI titers remained stable against the same strain from one season to the next. However, we observed the development of an immunity gap in the youngest children during the pandemic which resulted in a prominent reduction in HAI titers against A(H1N1)pdm09 in 2021 and 2022. The immunity gap was partially closed in sera collected in 2023 following the A(H1N1)pdm09-dominated influenza seasons of 2022/2023. During the 2022/2023 epidemic, drift variants of A(H1N1)pdm09 belonging to the 5a.2a.1 clade emerged, and pre-season HAI titers were significantly lower against this clade compared to the ancestral 5a.2 clade.
Conclusion
The observed reduction in protective antibodies against A(H1N1)pdm09 and A(H3N2) viruses post COVID-19 is best explained by antigenic drift of emerging viruses, and not waning of antibody responses in the general population. However, the absence of influenza during the pandemic resulted in an immunity gap in the youngest children. While this immunity gap was partially closed following the 2022/2023 influenza season, children with elevated risk of severe infection should be prioritized for vaccination.
Background
Non-pharmaceutical interventions (NPI) introduced in 2020 to limit the spread of SARS-CoV-2 drastically reduced the global spread of respiratory viruses and terminated the 2019/2020 influenza season early in Norway [1]. In Norway, NPIs consisted of temporary closing of schools, remote education, recommendation to work from home, social distancing and closing/restricting access to restaurants/bars and indoor sport and cultural events [2]. There were hardly any confirmed cases of influenza virus infections from April/May 2020 until December 2021, after which there was a resurgence in influenza infections that peaked around week 14 2022. The prolonged absence of influenza has raised concerns of whether waning immunity would result in more extensive influenza epidemics as respiratory viruses have returned following the removal of NPIs. Indeed, several countries, including Norway, have observed out-of-season resurgence of respiratory viruses such as Respiratory Syncytial virus with the relaxation of NPIs [3,4,5,6], while influenza infections returned in many countries towards the end of 2021 [7, 8]. However, it is not clear how the resurgence in respiratory viruses correlate with potential changes in population immunity over the pandemic.
The level of protective immunity against influenza viruses in the population is a result of vaccinations and previous infections (reviewed in [9]). However, the nature of the immune response induced by infection or vaccination can vary extensively. Natural influenza infection can induce long lasting immune response consisting of humoral and cellular immunity against several viral antigens. For instance, during the influenza A(H1N1)pdm09 pandemic in 2009 it was observed that older individuals were better protected against infection, most likely due to previous exposure to antigenically similar A(H1N1) strains more than 50 years prior [10, 11]. Indeed, HAI assay performed on sera collected prior to the 2009 pandemic observed the highest seropositivity towards A(H1N1)pdm09 virus in the > 80 years age group [12], and B cells specific for the 1918 A(H1N1) virus have been isolated in elderly donors nearly 90 years after the pandemic [13]. In contrast, vaccination is thought to induce a more short-lived and strain-specific antibody response, predominantly directed against the hemagglutinin (HA) surface antigen [9]. As a consequence, there are reports of intra-seasonal waning of vaccine induced protection [14, 15], and laboratory studies indicating that antibody levels are significantly reduced within 6 months [16]. However, antibody levels are still elevated after 6 months compared to pre-vaccination samples [17], and vaccination remains the best option for reducing the number of deaths and hospitalizations from seasonal influenza.
While immune responses may provide protection from infection, they also exerts evolutionary pressure on the virus to mutate in order to evade existing immunity – a process referred to as antigenic drift. Consequently, the emergence of strains with a new antigenic profile may render a larger part of the population susceptible to infection and disease. To evaluate immunity against influenza in Norway, the National Influenza Centre (NIC Norway) at the Norwegian Institute of Public Health (NIPH) conducts an annual collection of residual sera from laboratories across the country from a geographical and age-representative selection of the population [18, 19]. The serum samples are collected in August each year and analyzed by HAI assays for protective antibodies against influenza viruses that have circulated in previous seasons or are expected to circulate in the coming season. HAI assays have long been established as a correlate of protection in humans [20, 21], and it is generally established that an HAI titer of 1:40 or more will reduce the risk of influenza A infection by 50% (reviewed in [22]). Here we present a summary of influenza A infections from October 2016 to May 2023, and HAI titers against A(H1N1)pdm09 and A(H3N2) strains in sera collected in 2019, 2021, 2022, and 2023.
Methods
Collection of serum samples
Anonymized residual sera were collected in August/September in 2019, 2021, 2022 and 2023 from medical laboratories across Norway as previously described [12, 23]. In total, 3364 sera were selected for analysis by HAI. Sera were collected to be representative of the Norwegian population in terms of geography and age distribution. The mean age of the collected sera were 34 years and 56.1% were from females. Characteristics of the collected sera for each year are presented in Table 1. Due to an increased workload related to the COVID-19 pandemic, serum samples from 2020 were not analyzed for antibodies against influenza.
Quantitating influenza infections and vaccine coverage
Influenza detections from all microbiology laboratories in Norway were until 2020 reported directly to the NIC on a weekly basis, and after this in real-time via the Norwegian microbiology laboratory database (MSIS laboratory database). The aggregated number of influenza infections from October 2016 until May 2023 were obtained by combining data from the two registries. Since 2009, more laboratories test for A(H1N1)pdm09 than for A(H3N2), hence a larger portion of the patient samples will get a positive subtyping result for H1 than for H3. Used raw, the national subtyping data will underestimate the number of A(H3N2) infections and overestimate A(H1N1)pdm09. To correct for this bias, the proportion of subtype A(H1N1)pdm09 to A(H3N2) infections were calculated based only on samples that were tested against both subtypes, and the proportions projected onto the total number of laboratory confirmed influenza A infections.
To determine the number of confirmed influenza A infections per 100.000 by age group, the population number within each age group were obtained from Statistics Norway for Q1 2022 and Q1 2023 [24]. Influenza A infections data were obtained from the MSIS database on 4. October 2023 for the period week 1 – 26 2022 (predominantly A(H3N2)) and week 40 2022 – week 22 2023 (predominantly A(H1N1)pdm09).
Vaccine coverage for the different age groups used in the manuscript were obtained from the Norwegian Immunization Registry SYSVAK.
A(H1N1)pdm09 and A(H3N2) PCR
Various PCR methods were used for influenza A and A(H1N1)pdm09 virus testing in the primary testing laboratories, while the majority of A(H3N2) subtyping were performed at the NIC. In the NIC, identification of A(H1N1)pdm09 was done using a protocol developed by the Robert Koch Institut, Germany [25], whereas A(H3N2) subtyping was done using a PCR developed by the Influenza Division, Centers for Disease Control and Prevention, Atlanta, GA, USA (https://www.cdc.gov/ncird/flu.html). In addition, influenza A and A(H1N1)pdm09 virus testing were verified in the NIC by PCR and a subset of samples selected for whole-genome sequencing of full-length viral RNA segment amplicons by Oxford Nanopore technology (nanopore baroding with PCR amplifications adopted from Zhou. et al. [26]).
Generating phylogenetic trees of A(H1N1)pdm09 and A(H3N2) viruses
Phylogenetic trees were generated using the software Molecular Evolutionary Genetics Analysis (MEGA) version 11 [27]. For the A(H1N1)pdm09 and A(H3N2) HA gene phylogenetic trees in Additional file 1: Fig. S2, evolutionary history was inferred using the Neighbor-Joining method [28], with evolutionary distance calculated the Maximum Composite Likelihood method[29]. For the A(H1N1)pdm09 tree A/Christchurch/16/2010 was applied as root, while A/Texas/50/2012 was applied as root in the A(H3N2) tree. All the HA gene sequences of A(H1N1)pdm09 and A(H3N2) strains in Additional file 1: Fig. S2 were obtained from the GISAID EpiFlu database [30] with the accession numbers; EPI_ISL_79721 (A/Christchurch/16/2010), EPI_ISL_199532 (A/Michigan/45/2015), EPI_ISL_306335 (A/Brisbane/02/2018), EPI_ISL_332059 (A/Darwin/6/2018), EPI_ISL_377080 (A/Guangdong-Maonan/SWL1536/2019), EPI_ISL_401903 (A/Victoria/2570/2019), EPI_ISL_6424984 (A/Sydney/5/2021), EPI_ISL_122006 (A/Texas/50/2012), EPI_ISL_292575 (A/Kansas/14/2017), EPI_ISL_285898 (A/Singapore/INFIMH-16–0019/2016), EPI_ISL_710475 (A/Cambodia/e0826360/2020), EPI_ISL EPI_ISL_2233240 (A/Darwin/9/2021).
The phylogenetic analysis of Norwegian A(H1N1)pdm09 viruses sequenced during the 2022/2023 season was performed in BioNumerics version 8.0 by generating a Maximum parsimony tree of HA sequences, including reference strains and vaccine strains for the southern and northern hemisphere.
Propagation of influenza virus
With the exception of A/Norway/25089/2022 (H1N1)pdm09 which was propagated in MDCK cells, the influenza viruses for the HAI assay were egg isolates kindly provided by the Worldwide Influenza Centre at the Francis Crick Institute, UK, and propagated in the allantoic cavity of embryonated hen’s eggs following the WHO GISRS Manual for the laboratory diagnosis and virological surveillance of influenza [31].
Hemagglutination inhibition assay (HAI)
Serum antibody titers were determined using an HAI assay, as previously described [32]. In short, aliquots of the collected sera were treated with receptor destroying enzyme (RDE) over night (ON) at 37°C, followed by inactivation by incubating for 30 min at 56°C. Next, the sera were serially diluted two-fold in 96-well plates starting at dilution 1:10 in PBS pH 7.2, resulting in a final volume of 25 μl pr well. Viral antigen in the form of different strains of influenza virus was subsequently added to the wells at a concentration 6–8 hemagglutinating units (HAU) pr 25 μl. Diluted sera and influenza virus were incubated for 1h at room temperature, before addition of turkey red blood cells (RBC) as indicator cells at a concentration of 0.25% in PBS with BSA. The HAI titer was determined as the serum dilution factor that produced complete inhibition in the assay. An HAI titer of 40 or higher against a particular influenza virus strain is associated with reduced risk for infection [20, 21]. For calculations of geometric mean titers, sera with titers < 10 were assigned an HAI titer of 5. Sera collected in 2019 were tested against the A(H1N1)pdm09 strains A/Michigan/45/2015 and A/Brisbane/2/2018, while sera collected in 2021, 2022 and 2023 were tested against A/Victoria/2570/2019. In addition, sera from 2019 were tested against A(H3N2) strains A/Singapore/19/2016 and A/Kansas/14/2017, sera from 2021 were tested against A/Cambodia/e0826360/2020 and A/Darwin/9/2021 and sera from 2022 and 2023 were tested against A/Darwin/9/2021.
Statistics
HAI titers in Fig. 3 and Fig. 4 were plotted as reverse cumulative plots [33], while HAI titers in Fig. 5 were plotted as geometric mean with 95% confidence interval. Significant difference in HAI titers between two groups were calculated using a Mann–Whitney test or a Wilcoxon matched-pairs signed rank test using GraphPad Prism 9.
Results
To assess the influenza epidemics in Norway before and after the COVID-19 pandemic, the number of confirmed influenza A and B cases were plotted from October 2016 until June 2023 (Fig. 1A). While the 2016/2017 and 2018/2019 seasons were dominated by influenza A, the 2017/2018 season had an overweight of influenza B cases. The 2019/2020 influenza season was mild and had an even mix of influenza A and B detections. The 2019/2020 season progressed largely as normal, with a start in October/November 2019 and a peak February 2020, although the number of infections quickly declined in March 2020 with the introduction of contact-reducing measures to limit the spread of SARS-CoV-2 (Fig. 1A)[1]. During the 2020/2021 season NIPH only registered 11 confirmed influenza A infections and 11 influenza B cases with many of them being imported, and influenza viruses were largely absent from April 2020 until December 2021. After low levels of influenza infections during winter 2021/2022 there was a late influenza epidemic that started in March 2022, after all non-pharmaceutical interventions against COVID-19 had ended in February 2022. The influenza A epidemic of the 2022/2023 season started relatively early and peaked around Christmas 2022, followed by a smaller increase in influenza B infections in February to April 2023. Despite the absence of influenza viruses for almost two years, the two influenza epidemics that have occurred after start of the COVID-19 pandemic have not resulted in a higher number of confirmed infections compared to the influenza seasons before the pandemic.
Influenza A subtype distribution indicates that the 2016/2017 and 2021/2022 seasons were dominated by the influenza A(H3N2) subtype, while the 2018/2019 and 2022/2023 seasons had a higher number of A(H1N1)pdm09 subtype infections (Fig. 1B). The 2019/2020 season was more mixed between A(H1N1)pdm09 and A(H3N2) infections, while the 2017/2018 season consisted predominantly of B/Yamagata infections in addition to A(H3N2) infections (Fig. 1A-B, Additional file 1: Figure S1). Indeed, since the A(H1N1)pdm09 pandemic in 2009/2010, influenza A viruses have predominated in most seasons, with only the 2010/2011 and 2017/2018 seasons being influenza B dominated (Additional file 1: Figure S1).
Protective immunity against influenza A viruses
To assess the level of immunity towards influenza before and after the COVID-19 pandemic, we compared HAI titers in serum samples collected in 2019, 2021, 2022 and 2023. Serum samples were collected to be representative of the Norwegian population in terms of geography and age distribution (Table 1) and were analyzed by HAI assays against influenza strains that were circulating, or were expected to circulate the following influenza season, and that were part of previous or current seasonal influenza vaccines (Fig. 2A-B). Given the dominance of influenza A from fall 2016 until spring 2023 we focused on immunity towards A(H1N1)pdm09 and A(H3N2)(Fig. 2).
Sera was considered protective if HAI titers were ≥ 40, and the percentage of protective sera plotted for each influenza strain (Fig. 2A). For sera collected in 2019, 63.7% of all serum samples had protective HAI titers against A/Michigan/45/2015 (H1N1pdm09, Clade 6B.1). There was a reduction to 53.9% protective titers against A/Brisbane/2/2018 of the Clade 6B.1A1 in the same sera (Additional file 1: Figure S2A)[34]. There was a more pronounced reduction in protective HAI titers to 27.3% in sera from 2021, which were tested against A/Victoria/2570/2019. However, this reduction may also relate to further antigenic drift of the A/Victoria/2570/2019 strain which belongs to the 6B.1A.5a.2 clade (Additional file 1: Figure S2A)[35]. In sera collected in 2022 there was an increase in the percentage of protective HAI titers to 35.4% against A/Victoria/2570/2019, even though there was very little circulation of A(H1N1)pdm09 virus during the 2021/2022 season. A/Victoria/2570/2019 was, however, included in the seasonal influenza vaccine that was administered in the fall/winter of 2021 and in the fall/winter of 2022 (Fig. 2A)[36]. Following the A(H1N1)pdm09 dominated 2022/2023 influenza season we observed a further increase in the percentage of protective HAI-titers against A/Victoria/2570/2019 to 52.2% in sera collected in 2023.
For influenza A(H3N2), 52.9% of the sera collected in 2019 had protective HAI titers against A/Singapore/19/2016, while only 12.3% had protective HAI titers against A/Kansas/14/2017 (Fig. 2B). These two strains belong to different clades, 3C.2a1 and 3C.3 respectively, which explains the large difference in protective HAI titers (Additional file 1: Figure S2B). In sera collected in 2021, 52.4% had protective titers against A/Cambodia/e0826360/2020 which belongs to a continuation of the 3C.2a1 clade, this indicates that protective HAI titers against this clade have remained quite stable over the pandemic. In contrast, only 22.6% of serum samples from 2021 had protective HAI titers against A/Darwin/9/2021 of the 3C.2a1b.2a.2 clade (Additional file 1: Figure S2B). Protective titers against A/Darwin/9/2021 remained stable at 21.9% of sera collected in 2022, while increasing to 32.9% of collected sera in 2023 (Fig. 2B). In contrast to the A/Victoria/2570/2019(H1N1) strain, the A/Darwin/9/2021(H3N2) strain was first included in the northern hemisphere seasonal vaccine for 2022/2023, which may have contributed to the increase in protective responses from 2022 to 2023.
HAI responses in different age groups
When breaking the HAI data into age groups we observed that in the 25–59 years and 60 + years groups, the percentage of sera with protective HAI tiers against A(H1N1)pdm09 was reduced in sera from 2021, compared to sera from 2019. Similarly to the percentages observed for all serum samples, there was an increase in sera with protective titers from 2021 to 2022, which was further increased in 2023. (Fig. 2). In the 0–4 years age group there was a marked reduction in the percentage of protective HAI titers against A(H1N1)pdm09 from 33.6% against A/Brisbane/2/2018 in 2019 to 8.3% against A/Victoria/2570/2019 in 2021. There was a further reduction to 4.4% against A/Victoria/2570/2019 in 2022, likely reflecting the fact that most children born after the 2018/2019 influenza season were immunologically naïve to A(H1N1)pdm09 viruses. Following the A(H1N1)pdm09 dominated influenza season of winter 2022/2023, there was an increase in protective titers to 16.2% against A/Victoria/2570/2019. For the 5–14 years and 15–24 years age groups the percentage of protective sera was comparable or higher than those observed for the combined age groups.
To better evaluate the changes in HAI titers from one season to the next we generated reverse cumulative plots for different age groups for sera collected in 2021 and 2022 seasons which were tested against the same A(H1N1)pdm09 and A(H3N2) strains (Figs. 3A and 4A). Reverse cumulative plots display all the HAI data and makes it possible to identify changes in antibody levels that are not apparent when just evaluating the percentage of sera with titer titers ≥ 40. For the 0–4 years age group, HAI titers were significantly lower against A/Victoria/2570/2019 in 2022 compared to 2021 (Fig. 3A). The data indicate that most children aged 4 or younger did not have any immunity against A(H1N1)pdm09 in August 2022, constituting an immunity gap which may have contributed to the high number of confirmed influenza A infections during the 2022/23 season (Fig. 3B). Similarly, we observed a significant reduction in HAI titers against A/Darwin/9/2021 (H3N2) in the youngest age group, despite the percentage of sera with protective titers being quite stable from 2021 to 2022 (Figs. 2B and 4A).
HAI titers against A/Victoria/2570/2019(H1N1)pdm09 were stable in the 5–14 years and 15–24 years age groups, suggesting limited antibody waning from one season to the next (Fig. 3A). There was a slight increase in HAI titers against A/Darwin/9/2021(H3N2) in the 15–24 years age group in sera from 2022, which may reflect the higher number of infections reported in this age group during spring 2022 (Fig. 4A-B).
In the older age groups, there was a significant increase in HAI titer against A/Victoria/2570/2019(H1N1)pdm09 from 2021 to 2022 likely reflecting the inclusion of this strain in the seasonal influenza vaccine administered in fall 2021. For the 2021/2022 season, vaccine coverage in the + 60 years age group were estimated to be at least 55%, while the coverage in the 25–59 years group were at least 17.4% (Fig. 3C). To ensure that HAI data were comparable when collected and analyzed over two consecutive seasons, a set of 119 sera from one microbiological laboratory collected in 2021 were also analyzed together with the samples collected in 2022. No significant difference was seen in HAI assays performed in 2021 and 2022 for the reference samples against A/Victoria/2570/2019 or A/Darwin/9/2021 (Figs. 3D and 4C).
Lower HAI titers against A(H1N1)pdm09 clade 6B.1A.5a.2a.1 in 2022
The 2022/2023 influenza season predominantly consisted of infections with A(H1N1)pdm09 viruses, although there was increasing numbers of influenza B infection during late winter/spring of 2023. There was cocirculation of A(H1N1)pdm09 viruses belonging to the 6B.1A.5a.2a clade (which include A/Victoria/2570/2019), and the 6B.1A.5a.2a.1 clade including A/Norway/25089/2022 (Fig. 5A). To assess immunity towards the novel A/Norway/25089/2022 strain, we selected 75 serum samples collected in 2022 with HAI titer ≥ 160 against A/Victoria/2570/2019 and tested them in HAI assays against A/Norway/25089/2022 (Fig. 5B). We observed significantly lower HAI titers against the 6B.1A.5a.2a.1 clade with geometric mean titer declining from 187 against A/Victoria/2570/2019 to 50 against A/Norway/25089/2022 (Fig. 5B).
When dividing serum samples into age groups, the reduction in HAI titers against A/Norway/25089/2022 were more prominent in the 25–59 years and 60 + years age groups (Fig. 5B). The reduction in HAI titer in the younger age group did not reach significance. Due to a limited number of serum samples, the 5–14 and 15–24 age groups were combined. None of the serum samples in the 0–4 years age group had HAI titers ≥ 160 against A/Victoria/2570/2019 and thus were not included in the comparison. The marked reduction in HAI titers against A/Norway/25089/2022 in the oldest age group supports the decision of WHO to update the influenza vaccine strain recommendation for 2023/2024 for the northern hemisphere to include a virus of the 6B.1A.5a.2a.1 clade [36].
Discussion
The long absence of influenza virus during the COVID-19 pandemic have raised concerns about waning immunity and more severe epidemics following the removal of non-pharmaceutical interventions. Indeed, the term “immunity debt” has been used to describe a situation where the lowered immunity in the general population would need to be “repaid” through either infections or vaccinations [37]. However, our results indicate that the immunity against influenza has remained relatively stable in most age groups over the pandemic, and that the two influenza A epidemics of spring 2022 and winter 2022/2023 have been comparable in magnitude to previous seasonal epidemics.
For children in the 0–4 years age group, we observed a pronounced drop in the percentage of sera with protective levels of antibodies against A(H1N1)pdm09 from 2019 until 2022, suggesting that the absence of influenza during the COVID-19 pandemic has generated an immunity gap in this age group which, more than the other groups, is characterized by replacement with many immunologically naïve individuals every year. It should be noted that sera collected in 2019 may have had above-average levels of protective antibodies due to being collected following the extensive A(H1N1)pdm09 epidemic of 2018/2019. In contrast, sera collected in 2022 were predominantly from children who were born after the 2018/2019 influenza season and therefore were antigenically naïve to A(H1N1)pdm09 viruses. Corresponding to the lack of pre-season immunity, we observed a high incidence of influenza A infections in the 0–4 years group during the A(H1N1)pdm09-dominated 2022/2023 winter season. It is possible that testing regimes may have differed between age groups, resulting in a higher number of tests and more confirmed infections in the youngest children. This is, however, contradicted by the fact that a similar elevated incidence in the youngest was not seen for influenza A infections during the A(H3N2) epidemic in spring 2022. The percentage of sera with protective titers against A/Victoria/2570/2019 rose almost fourfold in 2023 following the A(H1N1)pdm09-dominated 2022/2023 season, suggesting that the immunity gap was at least partially closed. Protective levels of antibodies against A(H3N2) were more similar in sera collected in 2019 and 2022, potentially influenced by the late A(H3N2) epidemic in spring of 2022. Nevertheless, disease burden in the youngest children should be carefully monitored over the coming influenza seasons, as they may still be at increased risk of infection and disease from influenza A and B viruses.
For the age groups above 4 years, that have probably had previous exposure to A(H1N1)pdm09 viruses, we observed a more moderate change in protective antibodies from 2019 to 2022. When evaluating sera collected in 2021 and 2022 against the A/Victoria/2570/2019(H1N1)pdm09 strain, HAI titers remained surprisingly stable from one season to the next. Our observations are in accordance with studies in health care workers receiving an AS03-adjuvanted H1N1pdm09 vaccine in 2009 where elevated antibody levels remained for 60 months without additional booster vaccinations or known influenza infection [38]. While the duration of the protective antibody responses following the H1N1pdm09 vaccine may be influenced by the AS03 adjuvant [39], the results indicate that HAI titers after immunization can remain stable when tested against the same strain over time [38]. Similar results were also observed for HAI titers against A/Darwin/9/2021 (H3N2) which remained stable in sera from all age groups from 2021 to 2022. Conceivably, since the sera are collected in late summer, an initial drop in individual post-exposure peak titres down to a more persistent steady-state titre may have already occurred.
In the oldest age groups, we observed an increase in HAI titer against A/Victoria/2570/2019 (H1N1pdm09) from 2021 to 2022, probably reflecting the inclusion of this strain in the seasonal influenza vaccine for the 2021/2022 season which saw very little actual A(H1N1)pdm09 circulation. In Norway, annual influenza vaccination is recommended for people in risk groups, including all above 65 years, which may explain why vaccination rates and the increase in HAI titers are highest in the 60 + age group. However, HAI titers also increased in the 25–59 years group even lthough vaccination coverage was only 17.4% in the general population. Since the residual sera is predominantly collected from microbiological laboratories associated with hospitals, there is a chance that we have a higher frequency of sera from people in various risk groups and consequently higher vaccination coverage than the general population. Previous studies have indicated that HAI titers in the elderly largely return to baseline within 12 months after vaccination [16]. In contrast, our observations indicate that HAI titers may remain significantly elevated after 12 months as the residual sera were collected during the same time period each year. Since the samples are irreversibly anonymized upon collection, we cannot exclude that there are inherent differences between sera collected in 2021 and 2022. However, HAI titers remained the stabile against A/Darwin/9/2021 (H3N2) from 2021 to 2022, and then increased from 2022 to 2023 when the strain was included in the seasonal influenza vaccine for 2022/2023, supporting the idea that vaccine uptake may have improved HAI titers in the older age group.
The stable HAI titers against A/Victoria/2570/2019 and A/Darwin/9/2021 from 2021 to 2022 indicate limited waning between seasons. Consequently, it is highly likely that the reduction in percentage of sera with HAI titers ≥ 40 against contemporaneous strains from 2019 to 2021 is related to antigenic drift due to immune evasive mutations in the HA. Consistent with this conclusion, previous studies have observed reduced effectiveness of the influenza vaccine for the 2019/2020 season (containing A/Brisbane/2/2018, clade 6B.1A.1) against A(H1N1)pdm09 viruses of the 6B.1A.5A clade with additional mutations K130N, N156K, L161I and V250A (as found in A/Victoria/2570/2019) [40]. Similarly, serum samples collected in 2022 with high HAI titers against A/Victoria/2570/2019 displayed a significant reduction in titers against A/Norway/25089/2022, indicating further antigenic drifting of the 6B.1A.5a.2a.1 clade which circulated during the 2022/2023 influenza season. The difference in titers was least for the 5–24-year-olds. This may reflect that the antibody repertoire in younger people is more directed against recent strains than in older people, while less “monospecific” than in the very young who generally have experienced only one strain of the subtype, if any.
Our study of protective immune responses against subtype A(H1N1)pdm09 and A(H3N2) viruses was performed using HAI assays which measures antibodies that block binding of influenza HA to sialic acids on red blood cells. While the assay is recognized as a correlate of protection against influenza infection, it does not measure all protective antibodies that may be induced following infection or vaccination. Antibodies directed against the stem or other epitopes on HA apart from the sialic binding site may neutralize the virus or target infected cells for cellular immune responses and thus contribute to protection [22], but would likely not be measured in our assays. This is also the case for antibodies against neuraminidase (NA) which may protect against infection [41], and has been established as a correlate of protection against influenza [42, 43]. Consequently, the HAI results are likely an underestimate of the protective responses in the population, especially in the age groups that have been exposed to influenza infections over several seasons.
Conclusion
Analysis of serum samples collected in 2019, 2021, 2022 and 2023 indicate that antibody levels against seasonal influenza A viruses in the Norwegian population have remained relatively stable over the course of the COVID-19 pandemic. The observed reduction in protective antibodies against A(H1N1)pdm09 and A(H3N2) viruses are likely associated with viral antigenic drift. However, due to the absence of influenza viruses for almost two years, an immunity gap developed in the youngest children who were mostly naïve to influenza virus infection by summer 2022. Even though many of these children must be expected to have experienced their first influenza virus infection during the 2022/2023 influenza season, this age group may still have a higher susceptibility to influenza infection in the coming years. Increased focus on vaccination of children with elevated risk of severe infection should therefore be prioritized.
Availability of data and materials
Anonymized data and viral samples can be shared in accordance with the data sharing policy of NIPH.
Change history
18 March 2024
A Correction to this paper has been published: https://doi.org/10.1186/s12985-024-02341-x
Abbreviations
- HAI:
-
Hemagglutination inhibition
- HA:
-
Hemagglutinin
- MSIS:
-
Norwegian surveillance system for communicable diseases
- NA:
-
Neuraminidase
- NIC Norway:
-
National influenza centre
- NIPH:
-
Norwegian institute of public health
- RBC:
-
Red blood cells
- REK:
-
Regional ethics committee
References
Emborg HD, Carnahan A, Bragstad K, Trebbien R, Brytting M, Hungnes O, et al. Abrupt termination of the 2019/20 influenza season following preventive measures against COVID-19 in Denmark, Norway and Sweden. Euro Surveill. 2021;26(22):2001160.
Saunes IS, Vrangbaek K, Byrkjeflot H, Jervelund SS, Birk HO, Tynkkynen LK, et al. Nordic responses to Covid-19: governance and policy measures in the early phases of the pandemic. Health Policy. 2022;126(5):418–26.
Folkehelseinstituttet, Risiko ved covid-19-epidemien, influensa og RSV-infeksjon i Norge. (2022)
Agha R, Avner JR. Delayed seasonal RSV surge observed during the COVID-19 pandemic. Pediatrics. 2021;148(3):e2021052089.
Weinberger Opek M, Yeshayahu Y, Glatman-Freedman A, Kaufman Z, Sorek N, Brosh-Nissimov T. Delayed respiratory syncytial virus epidemic in children after relaxation of COVID-19 physical distancing measures, Ashdod, Israel, 2021. Euro Surveill. 2021;26(29):2100706.
Foley DA, Yeoh DK, Minney-Smith CA, Martin AC, Mace AO, Sikazwe CT, et al. The interseasonal resurgence of respiratory syncytial virus in Australian children following the reduction of coronavirus disease 2019-related public health measures. Clin Infect Dis. 2021;73(9):e2829–30.
Chen B, Zhu Z, Li Q, He D. Resurgence of different influenza types in China and the US in 2021. Math Biosci Eng. 2023;20(4):6327–33.
Sominina A, Danilenko D, Komissarov A, Karpova L, Pisareva M, Fadeev A, et al. Resurgence of influenza circulation in the russian federation during the delta and omicron COVID-19 era. Viruses. 2022;14(9):1909.
Krammer F. The human antibody response to influenza A virus infection and vaccination. Nat Rev Immunol. 2019;19(6):383–97.
Fisman DN, Savage R, Gubbay J, Achonu C, Akwar H, Farrell DJ, et al. Older age and a reduced likelihood of 2009 H1N1 virus infection. N Engl J Med. 2009;361(20):2000–1.
Hancock K, Veguilla V, Lu X, Zhong W, Butler EN, Sun H, et al. Cross-reactive antibody responses to the 2009 pandemic H1N1 influenza virus. N Engl J Med. 2009;361(20):1945–52.
Waalen K, Kilander A, Dudman SG, Krogh GH, Aune T, Hungnes O. High prevalence of antibodies to the 2009 pandemic influenza A(H1N1) virus in the Norwegian population following a major epidemic and a large vaccination campaign in autumn 2009. Euro Surveill. 2010;15(31):19633.
Yu X, Tsibane T, McGraw PA, House FS, Keefer CJ, Hicar MD, et al. Neutralizing antibodies derived from the B cells of 1918 influenza pandemic survivors. Nature. 2008;455(7212):532–6.
Ray GT, Lewis N, Klein NP, Daley MF, Wang SV, Kulldorff M, et al. Intraseason waning of influenza vaccine effectiveness. Clin Infect Dis. 2019;68(10):1623–30.
Ferdinands JM, Fry AM, Reynolds S, Petrie J, Flannery B, Jackson ML, et al. Intraseason waning of influenza vaccine protection: evidence from the US influenza vaccine effectiveness network, 2011–12 through 2014–15. Clin Infect Dis. 2017;64(5):544–50.
Young B, Zhao X, Cook AR, Parry CM, Wilder-Smith A, Mc IC. Do antibody responses to the influenza vaccine persist year-round in the elderly?+ A systematic review and meta-analysis. Vaccine. 2017;35(2):212–21.
Mordant FL, Price OH, Rudraraju R, Slavin MA, Marshall C, Worth LJ, et al. Antibody titres elicited by the 2018 seasonal inactivated influenza vaccine decline by 3 months post-vaccination but persist for at least 6 months. Influenza Other Respir Viruses. 2023;17(1): e13072.
Haaheim LR. Surveillance of the antibody status to current influenza strains in the Norwegian population. 1: Method of serum sampling and evaluation of the A/USSR/77 (H1N1) impact in various age groups in 1978. NIPH Ann. 1979;2(2):45–54.
Haaheim LR. Surveillance of the antibody status to current influenza strains in the Norwegian population. 2: antibodies to the A/USSR/90/77 (H1N1) virus in various age groups after the second epidemic wave. NIPH Ann. 1980;3(1):49–56.
Hobson D, Curry RL, Beare AS, Ward-Gardner A. The role of serum haemagglutination-inhibiting antibody in protection against challenge infection with influenza A2 and B viruses. J Hyg (Lond). 1972;70(4):767–77.
Potter CW, Oxford JS. Determinants of immunity to influenza infection in man. Br Med Bull. 1979;35(1):69–75.
Cox RJ. Correlates of protection to influenza virus, where do we go from here? Hum Vaccin Immunother. 2013;9(2):405–8.
Tunheim G, Ro GOI, Chopra A, Aase A, Kran AB, Vaage JT, et al., Prevalence of antibodies against SARS-CoV-2 in the Norwegian population, August 2021. Influenza Other Respir Viruses, (2022)
Population count. 2023, Statistics Norway: www.ssb.no
Schulze M, Nitsche A, Schweiger B, Biere B. Diagnostic approach for the differentiation of the pandemic influenza A(H1N1)v virus from recent human influenza viruses by real-time PCR. PLoS ONE. 2010;5(4): e9966.
Zhou B, Donnelly ME, Scholes DT, St George K, Hatta M, Kawaoka Y, et al. Single-reaction genomic amplification accelerates sequencing and vaccine production for classical and Swine origin human influenza a viruses. J Virol. 2009;83(19):10309–13.
Tamura K, Stecher G, Kumar S. MEGA11: molecular evolutionary genetics analysis version 11. Mol Biol Evol. 2021;38(7):3022–7.
Saitou N, Nei M. The neighbor-joining method: a new method for reconstructing phylogenetic trees. Mol Biol Evol. 1987;4(4):406–25.
Tamura K, Nei M, Kumar S. Prospects for inferring very large phylogenies by using the neighbor-joining method. Proc Natl Acad Sci U S A. 2004;101(30):11030–5.
Shu Y, McCauley J. GISAID: global initiative on sharing all influenza data - from vision to reality. Euro Surveill. 2017;22(13):30494.
World Health O and Network WHOGIS, Manual for the laboratory diagnosis and virological surveillance of influenza. 2011, Geneva: World Health Organization. 139 p
Waalen K, Kilander A, Dudman SG, Ramos-Ocao R, Hungnes O. Age-dependent prevalence of antibodies cross-reactive to the influenza A(H3N2) variant virus in sera collected in Norway in 2011. Euro Surveill. 2012;17(19):20170.
Reed GF, Meade BD, Steinhoff MC. The reverse cumulative distribution plot: a graphic method for exploratory analysis of antibody data. Pediatrics. 1995;96(3 Pt 2):600–3.
John McCauley RD, Yi Pu Lin, Ruth Harvey, Monica Galiano, Zheng Xiang, Lynne Whittaker, Chandrika Halai, Karen Cross, Aine Rattigan, Burcu Ermetal, Alice Lilley, Mian Dai, Michael Bennett, Saira Hussain, Report prepared for the WHO annual consultation on the composition of influenza vaccines for the Southern Hemisphere 2020. 2019, Worldwide Influenza Centre, The Francis Crick Institute.
Nicola Lewis RD, Ruth Harvey, Monica Galiano, Zheng Xiang, Lynne Whittaker, Christine Carr, Burcu Ermetal, Karen Cross, Karen Cross, Alice Lilley, Michael Bennett, Chandrika Halai, Chandrika Halai, Lorin Adams, Report prepared for the WHO annual consultation on the composition of influenza vaccines for the Northern Hemisphere 2023–2024. 2023, Worldwide Influenza Centre, The Francis Crick Institute
Recommended composition of influenza virus vaccines for use in the 2023–2024 northern hemisphere influenza season. 2023: www.who.int
Cohen R, Ashman M, Taha MK, Varon E, Angoulvant F, Levy C, et al. Pediatric infectious disease group (GPIP) position paper on the immune debt of the COVID-19 pandemic in childhood, how can we fill the immunity gap? Infect Dis Now. 2021;51(5):418–23.
Trieu MC, Jul-Larsen A, Saevik M, Madsen A, Nostbakken JK, Zhou F, et al. Antibody responses to influenza A/H1N1pdm09 virus after pandemic and seasonal influenza vaccination in healthcare workers: a 5-year follow-up study. Clin Infect Dis. 2019;68(3):382–92.
Galson JD, Truck J, Kelly DF, van der Most R. Investigating the effect of AS03 adjuvant on the plasma cell repertoire following pH1N1 influenza vaccination. Sci Rep. 2016;6:37229.
Tenforde MW, Kondor RJG, Chung JR, Zimmerman RK, Nowalk MP, Jackson ML, et al. Effect of antigenic drift on influenza vaccine effectiveness in the United States-2019-2020. Clin Infect Dis. 2021;73(11):e4244–50.
Werninghaus IC, Hinke DM, Fossum E, Bogen B and Braathen R, Neuraminidase delivered as an APC-targeted DNA vaccine induces protective antibodies against influenza. Mol Ther, 2023.
Couch RB, Atmar RL, Franco LM, Quarles JM, Wells J, Arden N, et al. Antibody correlates and predictors of immunity to naturally occurring influenza in humans and the importance of antibody to the neuraminidase. J Infect Dis. 2013;207(6):974–81.
Monto AS, Petrie JG, Cross RT, Johnson E, Liu M, Zhong W, et al. Antibody to influenza virus neuraminidase: an independent correlate of protection. J Infect Dis. 2015;212(8):1191–9.
Acknowledgements
We are deeply grateful to all the contributing Norwegian diagnostic laboratories for their invaluable support by providing the serum samples used in the present study. We also thank these laboratories for continuously providing surveillance data on influenza virus detections, until 2020 directly to the NIC and subsequently via the MSIS Laboratory Database, whose team we also gratefully acknowledge. In addition, we thank the SYSVAK team for providing data on vaccine uptake. We would furthermore like to thank Marianne Morken, Marie Paulsen Madsen, Elisabeth Lea Vikse, Malene Strøm Dieseth, Rasmus Kopperud Riis, Anne Marie Lund, Valentina Johansen and Maja Fjellstad Knutsen for excellent technical assistance, Ignacio Garcia Llorente and Rasmus Kopperud Riis for sequence analysis of the virus isolates and our other highly skilled colleagues in the Department of Virology and beyond who contributed to make the study possible. The egg and cell-grown virus strains used as antigens were kindly provided by the WHO Worldwide Influenza Center at the Francis Crick Institute, United Kingdom, under direction of Professor Nicola Lewis.
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Open access funding provided by Norwegian Institute of Public Health (FHI)
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EF, AR, TA and KMR extracted and analyzed results. EF, KB and OH conceptualized and supervised the study. EF wrote first draft while all authors reviewed and edited the final manuscript.
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Collection and analysis of residual sera was performed after approval from the Regional Ethics Committee (REC south-east)(ref. 2009/1322).
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. Figure S1: Percentage distribution of influenza A and B subtypes from seasons 2008/09 through 2022/23, and Figure S2: Phylogeny of A(H1N1)pdm09 and A(H3N2) strain tested by HAI.
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Fossum, E., Rohringer, A., Aune, T. et al. Antigenic drift and immunity gap explain reduction in protective responses against influenza A(H1N1)pdm09 and A(H3N2) viruses during the COVID-19 pandemic: a cross-sectional study of human sera collected in 2019, 2021, 2022, and 2023. Virol J 21, 57 (2024). https://doi.org/10.1186/s12985-024-02326-w
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DOI: https://doi.org/10.1186/s12985-024-02326-w