The protective nasal boosting of a triple-RBD subunit vaccine against SARS-CoV-2 following inactivated virus vaccination

Dear Editor,Though COVID-19 vaccines have been developed and clinically deployed rapidly,new variants of concern(VOCs)are still emerging frequently and escalating around the world.More breakthrough infections occurred even vaccination rates are high.For possible ending of the pandemic,curbing infection and stopping transmission are priority.

Nasal vaccination of triple-RBD scaffold protein with flagellin elicits long-term protection against SARS-CoV-2 variants including JN.1

Developing a mucosal vaccine against SARS-CoV-2 is critical for combatting the epidemic.Here,we investigated long-term immune responses and protection against SARS-CoV-2 for the intranasal vaccination of a triple receptor-binding domain(RBD)scaffold protein(3R-NC)adjuvanted with a flagellin protein(KFD)(3R-NC+KFDi.n).In mice,the vaccination elicited RBD-specific broad-neutralizing antibody responses in both serum and mucosal sites sustained at high level over a year.This long-lasting humoral immunity was correlated with the presence of long-lived RBD-specific IgG-and IgA-producing plasma cells,alongside the Th17 and Tfh17-biased T-cell responses driven by the KFD adjuvant.Based upon these preclinical findings,an open labeled clinical trial was conducted in individuals who had been primed with the inactivated SARS-CoV-2(IAV)vaccine.With a favorable safety profile,the 3R-NC+KFDi.n boost elicited enduring broad-neutralizing IgG in plasma and IgA in salivary secretions.To meet the challenge of frequently emerged variants,we further designed an updated triple-RBD scaffold protein with mutated RBD combinations,which can induce adaptable antibody responses to neutralize the newly emerging variants,including JN.1.Our findings highlight the potential of the KFD-adjuvanted triple-RBD scaffold protein is a promising prototype for the development of a mucosal vaccine against SARS-CoV-2 infection.

A triple-RBD-based mucosal vaccine provides broad protectionagainst SARS-CoV-2 variants of concern

The rapid mutation and spread of SARS-CoV-2 variants urge the development of effective mucosal vaccines to provide broadspectrum protection against the initial infection and thereby curb the transmission potential.Here,we designed a chimeric tripleRBD immunogen,3Ro-NC,harboring one Delta RBD and two Omicron RBDs within a novel protein scaffold.3Ro-NC elicits potent and broad RBD-specific neutralizing immunity against SARS-CoV-2 variants of concern.Notably,intranasal immunization with 3RoNC plus the mucosal adjuvant KFD(3Ro-NC+KFDi.n)elicits coordinated mucosal IgA and higher neutralizing antibody specificity(closer antigenic distance)against the Omicron variant.In Omicron-challenged human ACE2 transgenic mice,3Ro-NC+KFDi.n immunization significantly reduces the tissue pathology in the lung and lowers the viral RNA copy numbers in both the lung(85.7-fold)and the nasal turbinate(13.6-fold).Nasal virologic control is highly correlated with RBD-specific secretory IgA antibodies.Our data show that 3Ro-NC plus KFD is a promising mucosal vaccine candidate for protection against SARS-CoV-2 Omicron infection,pathology and transmission potential.

Mucosal epithelial cells: the initial sentinels and responders controlling and regulating immune responses to viral infections

In the context of host defense,immune protection is mostly provided by hematopoietic immune cells,including neutrophils,macrophages,T cells,B cells,etc.However,in recent decades,emerging evidence has identified many additional diverse roles of nonhematopoietic cells in mammalian immunity,although most of these studied focused on a single-cell type.In July 2020,Krausgruber et al.in the laboratory of Christoph Bock published the paper“Structural cells are key regulators of organ-specific immune responses”in Nature.The authors used multiomics and systematically investigated the regulation of immune-associated genes in three major types of structural cells(epithelial cells,endothelial cells,and fibroblasts)in 12 different organs in mice.

A single nonsynonymous mutation on ZIKV E protein-coding sequences leads to markedly increased neurovirulence in vivo

Zika virus(ZIKV)can infect a wide range of tissues including the developmental brain of human fetus.Whether specific viral genetic variants are linked to neuropathology is incompletely understood.To address this,we have intracranially serially passaged a clinical ZIKV isolate(SW01)in neonatal mice and discovered variants that exhibit markedly increased virulence and neurotropism.Deep sequencing analysis combining with molecular virology studies revealed that a single 67D(Aspartic acid)to N(Asparagine)substitution on E protein is sufficient to confer the increased virulence and neurotropism in vivo.Notably,virus clones with D67N mutation had higher viral production and caused more severe cytopathic effect(CPE)in human neural astrocytes U251 cells in vitro,indicating its potential neurological toxicity to human brain.These findings revealed that a single mutation D67N on ZIKV envelope may lead to severe neuro lesion that may help to explain the neurovirulence of ZIKV and suggest monitoring the occurrence of this mutation during nature infection may be important.