The BNT162b2 mRNA SARS-CoV-2 vaccine induces transient afucosylated IgG1 in naive but not in antigen-experienced vaccinees.

BACKGROUND: Afucosylated IgG1 responses have only been found against membrane-embedded epitopes, including anti-S in SARS-CoV-2 infections. These responses, intrinsically protective through enhanced FcγRIIIa binding, can also trigger exacerbated pro-inflammatory responses in severe COVID-19. We investigated if the BNT162b2 SARS-CoV-2 mRNA also induced afucosylated IgG responses. METHODS: Blood from vaccinees during the first vaccination wave was collected. Liquid chromatography-Mass spectrometry (LC-MS) was used to study anti-S IgG1 Fc glycoprofiles. Responsiveness of alveolar-like macrophages to produce proinflammatory cytokines in presence of sera and antigen was tested. Antigen-specific B cells were characterized and glycosyltransferase levels were investigated by Fluorescence-Activated Cell Sorting (FACS). FINDINGS: Initial transient afucosylated anti-S IgG1 responses were found in naive vaccinees, but not in antigen-experienced ones. All vaccinees had increased galactosylated and sialylated anti-S IgG1. Both naive and antigen-experienced vaccinees showed relatively low macrophage activation potential, as expected, due to the low antibody levels for naive individuals with afucosylated IgG1, and low afucosylation levels for antigen-experienced individuals with high levels of anti-S. Afucosylation levels correlated with FUT8 expression in antigen-specific plasma cells in naive individuals. Interestingly, low fucosylation of anti-S IgG1 upon seroconversion correlated with high anti-S IgG levels after the second dose. INTERPRETATION: Here, we show that BNT162b2 mRNA vaccination induces transient afucosylated anti-S IgG1 responses in naive individuals. This observation warrants further studies to elucidate the clinical context in which potent afucosylated responses would be preferred. FUNDING: LSBR1721, 1908; ZonMW10430012010021, 09150161910033, 10430012010008; DFG398859914, 400912066, 390884018; PMI; DOI4-Nr. 3; H2020-MSCA-ITN 721815.

Afucosylated IgG responses in humans - structural clues to the regulation of humoral immunity.

Healthy immune responses require efficient protection without excessive inflammation. Recent discoveries on the degree of fucosylation of a human N-linked glycan at a conserved site in the immunoglobulin IgG-Fc domain might add an additional regulatory layer to adaptive humoral immunity. Specifically, afucosylation of IgG-Fc enhances the interaction of IgG with FcγRIII and thereby its activity. Although plasma IgG is generally fucosylated, afucosylated IgG is raised in responses to enveloped viruses and Plasmodium falciparum proteins expressed on infected erythrocytes, as well as during alloimmune responses. Moreover, while afucosylation can exacerbate some infectious diseases (e.g., COVID-19), it also correlates with traits of protective immunity against malaria and HIV-1. Herein we discuss the implications of IgG afucosylation for health and disease, as well as for vaccination.

Immunoassay for quantification of antigen-specific IgG fucosylation.

BACKGROUND: Immunoglobulin G (IgG) antibodies serve a crucial immuno-protective function mediated by IgG Fc receptors (FcγR). Absence of fucose on the highly conserved N-linked glycan in the IgG Fc domain strongly enhances IgG binding and activation of myeloid and natural killer (NK) cell FcγRs. Although afucosylated IgG can provide increased protection (malaria and HIV), it also boosts immunopathologies in alloimmune diseases, COVID-19 and dengue fever. Quantifying IgG fucosylation currently requires sophisticated methods such as liquid chromatography-mass spectrometry (LC-MS) and extensive analytical skills reserved to highly specialized laboratories. METHODS: Here, we introduce the Fucose-sensitive Enzyme-linked immunosorbent assay (ELISA) for Antigen-Specific IgG (FEASI), an immunoassay capable of simultaneously quantitating and qualitatively determining IgG responses. FEASI is a two-tier immunoassay; the first assay is used to quantify antigen-specific IgG (IgG ELISA), while the second gives FcγRIIIa binding-dependent readout which is highly sensitive to both the IgG quantity and the IgG Fc fucosylation (FcγR-IgG ELISA). FINDINGS: IgG Fc fucosylation levels, independently determined by LC-MS and FEASI, in COVID-19 responses to the spike (S) antigen, correlated very strongly by simple linear regression (R2=0.93, p < 0.0001). The FEASI method was then used to quantify IgG levels and fucosylation in COVID-19 convalescent plasma which was independently validated by LC-MS. INTERPRETATION: FEASI can be reliably implemented to measure relative and absolute IgG Fc fucosylation and quantify binding of antigen-specific IgG to FcγR in a high-throughput manner accessible to all diagnostic and research laboratories. FUNDING: This work was funded by the Stichting Sanquin Bloedvoorziening (PPOC 19-08 and SQI00041) and ZonMW 10430 01 201 0021.

IgG GLYCOSYLATION PREDICTS COVID-19 DISEASE SEVERITY and VACCINE ANTIBODY RESPONSE

Background: Although vaccination efforts have been deployed worldwide over the past 10 months, there are still gaps in our understanding surrounding the immune response to SARS-CoV-2 infection and vaccination, including changes to the antibody repertoire. One way of tracking the immune response over time is through measuring IgG Fc glycosylation, which provides insight into the inflammatory state of an infected individual, antibody effector function, antibody half-life, and more. Therefore we set out to interrogate bulk IgG changes in glycosylation in both natural infection and vaccinated cohorts in order to determine potential insight into protection from severe disease and responsiveness to vaccination. Methods: We evaluated 98 plasma samples from COVID-19 patients with either mild or severe COVID-19. Symptomatic patients were characterized as mild or severe based on hospital admission. We also evaluated plasma from 228 vaccinated individuals (Pfizer-BioNTech). Bulk IgG glycosylation analysis was measured through a quadrupole orbitrap mass spectrometry. Neutralization potential was assessed through a spike pseudotyped neutralization assay. Spike antibody levels were measured using a Luminex assay and ELISA. Results: We found that inflammatory glycans (fucosylated agalactosylated, G0F) on bulk IgG were elevated in hospitalized COVID-19 patients and increased over time in this population when compared to mild infection. Mild patients had an anti-inflammatory glycosylation pattern (afucosylated galactosylated, G2) which increased over time. Siaylation levels were elevated in mild individuals, increased over time, and correlated with increased RBD antibody levels. Interestingly, when we assessed COVID-19 vaccinated individuals with low Spike antibody levels and low neutralization, they had the same glycosylation pattern (G0F) as that of hospitalized COVID-19 patients. Additionally, a small longitudinal vaccinated cohort (out to 8 months) revealed a decrease in G0F associated with peak IgG concentrations and neutralization (Fig 1). Conclusion: Inflammatory glycan signatures, such as an elevation in G0F glycans, can be used as prognostic tools, not only to predict the severity of COVID-19 disease, but also to predict patient responsiveness to COVID-19 vaccines. This is the first report identifying a shift in glycan signature to be associated with COVID-19 disease severity and vaccine responsiveness, which can guide future studies into SARS-CoV-2 protective immunity and vaccine development.