ABSTRACT
Since their emergence in late 2021, SARS-CoV-2 Omicron replaced earlier variants of concern and marked a new phase in the SARS-CoV-2 pandemic. Until the end of 2023, Omicron lineages continue to circulate and continue to evolve, with new lineages causing infection waves throughout 2022 and 2023. In the population, this leads to a complex immunological exposure background, characterized by immunity derived through vaccination, in the 5th year of the pandemic in the majority of individuals followed by at least one or even multiple infections or only natural infection in individuals that did not receive a vaccine. In this study, we use eight authentic SARS-CoV-2 isolates (ancestral lineage B.1 and the seven Omicron lineages BA.1, BA.2, BA.5.1, BQ.1, XBB.1.5, EG.5.1 and JN.1.1) in a live virus neutralization assay to study immune escape in 97 human sera or plasma of different immunological backgrounds (vaccination, hybrid immunity due to one or two natural infections and natural infection without vaccination in children and adults). We showed a gradually increasing immune escape after vaccination and hybrid immunity in from B.1 to BA.1/BA.2 to BA.5.1 to BQ.1 to XBB.1.5 to EG.5.1, but remarkably, no more enhanced immune escape of JN.1.1 compared to EG.5.1, with the latter two showing almost identical neutralization titers in individuals with hybrid immunity due to one or more infections. In vaccinated but never infected individuals, neutralization was markedly reduced or completely lost for XBB.1.5., EG.5.1 and JN.1.1, while in those with hybrid immunity, titers were reduced but almost all sera still showed some degree of neutralization. After a single infection without vaccination, reduced or complete loss of neutralization occurred for BQ.1, XBB.1.5, EG.5.1 and JN.1.1 compared to BA.1/BA.2. Furthermore, we observed that, although absolute titers differed between groups, the pattern of immune escape between the variants remains comparable across groups, with strongest loss of neutralization for BQ.1, XBB.1.5, EG.5.1 and JN.1.1 was observed across the different immunological backgrounds. Our results show gradually increasing antibody escape of evolving Omicron lineages over the last two years of Omicron circulation until variant EG.5.1, but not anymore for the currently dominant lineages JN.1.1, suggesting other mechanisms than immune escape to be behind the rapid global emergence of JN.1.
ABSTRACT
Mucosal antibodies play a key role in the protection against SARS-CoV-2 infection in the upper respiratory tract, and potentially in limiting virus replication and therefore onward transmission. While systemic immunity to SARS-CoV-2 is well understood, little is known about the antibodies present on the nasal mucosal surfaces. In this study, we evaluated SARS-CoV-2 mucosal antibodies in response to infection, vaccination, or a combination of both. Paired nasal fluid and serum samples were collected from 136 individuals, which include convalescent, vaccinated, or breakthrough infections. We detected a high correlation between IgG responses in serum and nasal fluids, which were higher in both compartments in vaccinated compared to convalescent participants. Contrary, nasal and systemic SARS-CoV-2 IgA responses were weakly correlated, indicating a compartmentalization between the local and systemic IgA responses. SARS-CoV-2 secretory component IgA (s-IgA) antibodies, present exclusively on mucosal surfaces, were detected in the nasal fluid only in a minority of vaccinated subjects and were significantly higher in previously infected individuals. s-IgA binding antibodies showed significant correlation with neutralizing activity of nasal fluids against SARS-CoV-2 ancestral B.1 and Omicron-BA.5 variant, indicating that s-IgA is the crucial contributor to neutralization in the nasal mucosa. Neutralization against both SARS-CoV-2 strains was higher in the mucosa of subjects with previous SARS-CoV-2 infections compared to vaccinated participants. In summary, we demonstrate that currently available vaccines elicit strong systemic antibody responses, but SARS-CoV-2 infection generates more potent binding and neutralizing mucosal antibodies. Our results support the importance to develop SARS-CoV-2 vaccines that elicit mucosal antibodies.
Subject(s)
COVID-19 , Breakthrough Pain , Severe Acute Respiratory SyndromeABSTRACT
Background: We evaluate the diagnostic performance of dried blood microsampling combined with a high-throughput microfluidic nano-immunoassay (NIA) for the identification of anti-SARS-CoV-2 Spike IgG seropositivity. Methods: We conducted a serological study among 192 individuals with documented prior SARS-CoV- 2 infection and 44 SARS-CoV-2 negative individuals. Participants with prior SARS-CoV-2 infection had a long interval of 11 months since their qRT-PCR positive test. Serum was obtained after venipuncture and tested with an automated electrochemiluminescence anti-SARS-CoV-2 S total Ig reference assay, a commercial ELISA anti-S1 IgG assay, and the index test NIA. 109 participants from the positive co- hort and 44 participants from the negative cohort also participated in capillary blood collection using three microsampling devices: Mitra, repurposed glucose test strips, and HemaXis. Samples were dried, shipped by regular mail, extracted, and measured with NIA. Findings: Using serum samples, we achieve a clinical sensitivity of 98.33% and specificity of 97.62% on NIA, affirming the high performance of NIA in participants 11 months post infection. Combining microsampling with NIA, we obtain a clinical sensitivity of 95.05% using Mitra, 61.11% using glucose test strips, 83.16% using HemaXis, and 91.49% for HemaXis after automated extraction, without any drop in specificity. Interpretation: High sensitivity and specificity was demonstrated when testing micro-volume capillary dried blood samples using NIA, which is expected to facilitate its use in large-scale studies using home- based sampling or samples collected in the field. Funding: Swiss National Science Foundation NRP 78 Covid-19 grant 198412 and Private Foundation of the Geneva University Hospital.
Subject(s)
Severe Acute Respiratory Syndrome , COVID-19ABSTRACT
Viral load (VL) is one determinant of secondary transmission of SARS-CoV-2. Emergence of variants of concerns (VOC) Alpha and Delta was ascribed, at least partly, to higher VL. Furthermore, with parts of the population vaccinated, knowledge on VL in vaccine-breakthrough infections is crucial. As RNA VL is only a weak proxy for infectiousness, studies on infectious virus presence by cell culture isolation are of importance. We assessed nasopharyngeal swabs of COVID-19 patients for quantitative infectious viral titres (IVT) by focus-forming assay and compared to overall virus isolation success and RNA genome copies. We assessed IVTs during the first 5 symptomatic days in a total of 440 patients: unvaccinated individuals infected with pre-VOC SARS-CoV-2 (n= 118) or Delta (n= 127) and vaccine-breakthrough infections with Delta (n= 133) or Omicron (n=62). Correlation between RNA copy number and IVT was low for all groups. No correlation between IVTs and age or sex was seen. We observed higher RNA genome copies in pre-VOC SARS-CoV-2 compared to Delta, but significantly higher IVTs in Delta infected individuals. Vaccinated Delta infected individuals had significantly lower RNA genome copies and IVTs compared to unvaccinated subjects and cleared virus faster. In addition, vaccinated individuals with Omicron infection had lower IVTs in comparison to Delta breakthrough infections. Quantitative IVTs can give detailed insights into virus shedding kinetics. Vaccination was associated with lower infectious titres and faster clearance for Delta, showing that vaccination would also lower transmission risk. Omicron vaccine-breakthrough infections did not show elevated IVTs compared to Delta, suggesting that other mechanisms than increased VL contribute to the high infectiousness of Omicron.
Subject(s)
COVID-19ABSTRACT
Background Viral load (VL) is one determinant of secondary transmission of SARS-CoV-2. Emergence of variants of concerns (VOC) Alpha and Delta was ascribed, at least partly, to higher VL. Furthermore, with parts of the population vaccinated, knowledge on VL in vaccine-breakthrough infections is crucial. As RNA VL is only a weak proxy for infectiousness, studies on infectious virus presence by cell culture isolation are of importance. Methods We assessed nasopharyngeal swabs of COVID-19 patients for quantitative infectious viral titres (IVT) by focus-forming assay and compared to overall virus isolation success and RNA genome copies. We assessed IVTs during the first 5 symptomatic days in a total of 384 patients: unvaccinated individuals infected with pre-VOC SARS-CoV-2 (n= 118) or Delta (n= 127) and vaccine breakthrough infections with Delta (n= 121) or Omicron (n=18). Findings Correlation between RNA copy number and IVT was low for all groups. No correlation between IVTs and age or sex was seen. We observed higher RNA genome copies in pre-VOC SARS-CoV-2 compared to Delta, but significantly higher IVTs in Delta infected individuals. Vaccinated Delta infected individuals had significantly lower RNA genome copies and IVTs compared to unvaccinated subjects and cleared virus faster. In addition, vaccinated individuals with Omicron infection had comparable IVTs to Delta breakthrough infections. Interpretation Quantitative IVTs can give detailed insights into virus shedding kinetics. Vaccination was associated with lower infectious titres and faster clearance for Delta, showing that vaccination would also lower transmission risk. Omicron vaccine-breakthrough infections did not show elevated IVTs compared to Delta, suggesting that other mechanisms than increase VL contribute to the high infectiousness of Omicron. Funding This work was supported by the Swiss National Science Foundation 196644, 196383, NRP (National Research Program) 78 Covid-19 Grant 198412, the Fondation Ancrage Bienfaisance du Groupe Pictet and the Fondation Privée des Hôpitaux Universitaires de Genève.
Subject(s)
COVID-19ABSTRACT
Emerging SARS-CoV-2 variants of concern/interest (VOC/VOI) raise questions about effectiveness of neutralizing antibodies derived from infection or vaccination. As the population immunity to SARS-CoV-2 has become more complex due to prior infection and/or vaccination, understanding the antigenic relationship between variants is needed. Here, we have assessed in total 104 blood specimens from convalescent individuals after infection with early-pandemic SARS-CoV-2 (pre-VOC) or with Alpha, Beta, Gamma or Delta, post-vaccination after double-dose mRNA-vaccination and break through infections due to Delta or Omicron. Neutralization against seven authentic SARS-CoV-2 isolates (B.1, Alpha, Beta, Gamma, Delta, Zeta, Omicron) was assessed by plaque-reduction neutralization assay. We found highest neutralization titers against the homologous (previously infecting) variant, with lower neutralization efficiency against heterologous variants. Significant loss of neutralization for Omicron was observed but to a varying degree depending on previously infecting variant (23.0-fold in Beta-convalescence up to 56.1-fold in Alpha-convalescence), suggesting that infection-derived immunity varies, but independent of the infecting variant is only poorly protective against Omicron. Of note, Zeta VOI showed also pronounced escape from neutralization of up to 28.2-fold in Alpha convalescent samples. Antigenic mapping reveals both Zeta and Omicron as separate antigenic clusters. Double dose vaccination showed robust neutralization for Alpha, Beta, Gamma, Delta and Zeta, with fold-change reduction of only 2.8 (for Alpha) up to 6.9 (for Beta). Escape from neutralization for Zeta was largely restored in vaccinated individuals, while Omicron still showed a loss of neutralization of 85.7-fold compared to pre-VOC SARS-CoV-2. Combined immunity from infection followed by vaccination or vaccine breakthrough infection showed highest titers and most robust neutralization for heterologous variants. Breakthrough infection with Delta showed only 12.5-fold reduced neutralization for Omicron, while breakthrough infection with Omicron showed only a 1.5-fold loss for Delta, suggests that infection with antigenically different variants can boost immunity for antigens closer to the vaccine strain. Antigenic cartography showed also a tendency towards broader neutralizing capacity for heterologous variants. We conclude that the complexity of background immunity needs to be taken into account when assessing new VOCs. Development towards separate serotypes such as Zeta was already observed before Omicron emergence, thus other factors than just immune escape must contribute to Omicrons rapid dominance. However, combined infection/vaccination immunity could ultimately lead to broad neutralizing capacity also against non-homologous variants.