New research on phagocytosis and SARS-CoV-2's spike protein

The coronavirus disease 2019 (COVID-19), which is caused by the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), has caused over 4.9 million deaths worldwide, as well as a significant impact on societal health throughout the world. During the early stages of the COVID-19 pandemic, both monoclonal antibodies and convalescence plasma were used to treat patients.

Study: Opsonization by non-neutralizing antibodies can confer protection to SARS-CoV-2 despite Spike-dependent modulation of phagocytosis. Image Credit: StudioMoleKuul / Shutterstock.com

This news article was a review of a preliminary scientific report that had not undergone peer-review at the time of publication. Since its initial publication, the scientific report has now been peer reviewed and accepted for publication in a Scientific Journal. Links to the preliminary and peer-reviewed reports are available in the Sources section at the bottom of this article. View Sources

Background

Two monoclonal antibody cocktails, of which included both casirivimab and imdevim, as well as bamlanivimab and etesevim, were found to target the SARS-CoV-2 spike protein. As a result of their success during Phase III clinical trials, these two antibody treatments quickly received emergency use authorization (EUA) by the United States Food and Drug Administration (FDA).

Further, the trials indicated that the use of these antibody cocktails led to a reduction in symptoms, hospitalization, and mortality that was associated with early-stage COVID-19. However, the antibiotic cocktails did not show any benefit in case of severe COVID-19 infections.

The aforementioned therapeutic antibodies have been categorized as neutralizing antibodies. Neutralizing antibodies comprise only a fraction of the total antibodies that are generated by B-cells against the SARS-CoV-2 spike protein.

Comparatively, non-neutralizing antibodies comprise a majority of the humoral response against a pathogen. These antibodies are also known to have other immunological functions such as complement-dependent immune activation and viral phagocytosis. By carrying out either virus or cellular phagocytosis, phagocytic cells help to reduce the viral load.

In the case of certain viral infections such as Respiratory Syncytial Virus (RSV), SARS-CoV-2, and Dengue, the level of neutralizing antibodies is found to be insufficient. This allows non-neutralizing antibodies to mediate entry of the virions into the host immune cells resulting in an Antibody-Dependent-Enhancement (ADE). This further results in increased infection, along with worsened patient outcomes. To date, no study has shown evidence of ADE in the case of COVID-19 infections.

A new study published in the preprint server bioRxiv* showed evidence that convalescent patient plasma and monoclonal anti-spike antibodies were able to induce phagocytosis at high antibody concentrations. This study also demonstrated that neutralization potential did not have any effect on the activation and inhibition of phagocytosis. This study also utilized an experimental animal infection model to determine the role of non-neutralizing antibodies in providing protection against SARS-CoV-2.

About the study

The current study began with in vitro transfection of HEK293 cells with plasmids for expression of the spike protein, as well as antibodies. SARS-CoV-2 anti-spike antibodies were selected with the help of phage display technology.

Convalescent patient plasma reduces Spike-monocyte interaction. a Biotinylated Spike protein was conjugated to fluorescent (APC) streptavidin microspheres and was opsonized with three convalescent patient plasma concentrations (1%, 0.1%, and 0.01%). The beads were then mixed with THP-1 cells at a ratio of 2:1, and the association was measured using flow cytometry. Cells that had signal in the APC channel were considered positive. The gating strategy is shown in the top right. b The same samples of THP-1 cells and beads from (a) were fixed with methanol and stained with a fluorescent (FITC) Fab anti-human Fab secondary antibody. The samples were analyzed for human antibody (opsonin) binding to the Spike-beads using flow cytometry. The gating strategy is shown in the top right. The data presented are from three independent experiments. Error bars represent the SD. Statistical significance was assessed using two-way ANOVA with Dunnett’s multiple comparison correction. * denotes p 0.05, ** for p 0.01, *** for p 0.001 and **** for p 0.0001).

Blood samples were also collected from 20 patients with mild, moderate, or severe COVID-19. These blood samples were used for the isolation of B-cells. Spike proteins were incubated with the B-cells followed by bulk cell sorting, genome sequencing, and antibody reactivity screening.

Generation of Spike-reactive human monoclonal antibodies. a Human monoclonal antibodies were generated from convalescent donor B cells through single-cell sequencing technology. 96 antibodies derived from Spike-reactive human B cells were produced in HEK293F cells. b Cell culture supernatants containing the antibodies were assayed by ELISA for reactivity against immobilized Spike protein. Serum from a COVID19 patient was used as a positive control. The data represent three replicate ELISAs where reproducibly reactive antibodies are indicated with their names above the heatmap. c Antibodies which were Spike-reactive in (b) were assayed for reactivity to Spike immobilized on beads. Fluorescent (APC) Streptavidin beads coated with biotinylated Spike protein were incubated with HEK293F-produced antibodies at a concentration of 1 µg/ml. The beads were then stained with a fluorescent (FITC) secondary anti-Fab antibody. The beads were analyzed by flow cytometry. Antibodies that shifted the beads into the FITC-positive gate were deemed reactive.

Following this, three different assays were carried out including spike-THP-1 association assays, Pseudotyped virus neutralization assays, and Bead-based neutralization assay. Immunoglobulin G (IgG)-antigen interaction was determined followed by determination of epitope location by enzyme-linked immunosorbent assay (ELISA).

Surface plasmon resonance studies were carried out for the assessment of IgG specificity. Finally, antibodies were cross-linked to the spike proteins followed by peptide analysis using liquid chromatography-tandem mass spectrometry (LC-MS/MS).

The in vivo experiments involved the use of transgenic mice that carried the humane angiotensin-converting enzyme 2 (ACE2) gene and were inoculated with SARS-CoV-2. The mice were divided into six groups, with seven mice in each group.

Both neutralizing and non-neutralizing antibodies were administered intraperitoneally in one single dose. The infection was allowed to proceed for seven days, following which the mice were euthanized.

Study findings

The results indicated that at a high plasma concentration, there was a reduction in the binding of TPH1 monocytes and the spike protein. This reduction was found to be independent of the age, gender, and disease severity of the patient. Experiments with monoclonal antibodies detected ten spike-reactive antibodies, out of which nine were found to bind to spike beads as detected by flow cytometry.

The results of the epitope analysis indicated that antibodies could bind the spike protein but they did not compete with the binding site of human ACE2. These antibodies included Ab11, 57, 59, 66, 77, 81, 94.

Ab94 could bind to both the receptor-binding domain (RBD) and N-terminal domain (NTD). Ab59 was a neutralizing antibody, while the others were non-neutralizing antibodies. Overall, Ab59 was found to be most effective in SARS-CoV-2 neutralization.

The results also indicated that the spike-specific monoclonal antibodies that were obtained from COVID-19 patients had a dose-dependent effect on the spike-THP-1 cell interactions. This effect was independent of the spike-ACE2 neutralization capability of the monoclonal antibodies.

Although the results indicated that the monoclonal antibodies were effective in the mediation of phagocytosis, a threshold that led to a reduction in interaction efficiency was identified.

Determination of the antibodies’ function in a physiological context took place with the help of mice models. The results from the in vivo study indicated that too high doses of neutralizing antibodies were not beneficial for treatment. Additionally, non-neutralizing antibodies were also found to provide protection against SARS-CoV-2.

Therefore, the current study represents a concentration-dependent modulation of phagocytosis that was brought about by anti-spike antibodies. It may also help to indicate the unclear clinical benefit of COVID-19 treatment with monoclonal antibodies.

This news article was a review of a preliminary scientific report that had not undergone peer-review at the time of publication. Since its initial publication, the scientific report has now been peer reviewed and accepted for publication in a Scientific Journal. Links to the preliminary and peer-reviewed reports are available in the Sources section at the bottom of this article. View Sources

Journal references:

Article Revisions

  • May 1 2023 - The preprint preliminary research paper that this article was based upon was accepted for publication in a peer-reviewed Scientific Journal. This article was edited accordingly to include a link to the final peer-reviewed paper, now shown in the sources section.
Suchandrima Bhowmik

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Suchandrima Bhowmik

Suchandrima has a Bachelor of Science (B.Sc.) degree in Microbiology and a Master of Science (M.Sc.) degree in Microbiology from the University of Calcutta, India. The study of health and diseases was always very important to her. In addition to Microbiology, she also gained extensive knowledge in Biochemistry, Immunology, Medical Microbiology, Metabolism, and Biotechnology as part of her master's degree.

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  1. Wendy Wilson Wendy Wilson People's Republic of China says:

    With the expert in the microbial genome engineering and metabolic pathway analysis. Base strains producing natural compounds can be constructed by transplanting or adopting heterologous or homologous production pathways.

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