Capsid Protein VP1 Research Articles

Aptamer-Based Detection of Foot-and-Mouth Disease Virus Using Single-Stranded DNA Probe.

Foot-and-mouth disease (FMD) is known for its highly contagious properties among cloven-hoofed animals resulting in significant morbidity rates. Incursions of this disease have caused significant losses in affected countries in Southeast Asia and Africa, even within EU countries which resulted in significant financial losses.This study is aimed at addressing existing limitations by creating a diagnostic method using aptamer-based assay. Three DNA aptamers were engineered to target the VP2 region of the FMD viral capsid protein. Since VP2 demonstrates a highly conserved amino acid sequence across serotypes, the specifically designed aptamers can detect different serotypes of the virus. Aptamers were evaluated against VP2 capsid protein, which was synthesized based on sequences from serotypes A, O, and Asia 1 of the FMD virus. After the recombinant VP2 capsid protein was developed, expressed, and refined, it was applied using enzyme-linked aptamer sorbent assay (ELASA) to determine aptamers' binding capability. A similar test was further conducted with purified FMD virus from serotype A and serotype O. The ELASA results displayed a notable sensitivity in identifying the FMDV. Under optimized conditions, the aptamers have LOD as low as 0.11ng/mL with LOQ as low as 0.34ng/mL. The binding strength analyzed using the equilibrium dissociation constant (Kd) showed strong binding affinity at 3.092 ± 0.05nM. Based on these findings, the method shows significant potential with high sensitivity and specificity for FMD virus detection assay.

Human norovirus disturbs intestinal motility and transit time through its capsid proteins.

Human norovirus (HuNoV) accounts for over 700 million cases of gastroenteritis annually. Episodes of HuNoV disease are characterized by vomiting and diarrhea as the two most prominent symptoms. Despite its prevalence, our understanding of the pathophysiological mechanisms triggered upon HuNoV infection is limited, mainly due to a lack of suitable animal models. Our aim was to use the recent HuNoV zebrafish larvae model to study the effect of HuNoV infection on intestinal motility and investigate whether one viral protein could act as an enterotoxin, as seen with rotavirus. We studied whether HuNoV infection affects the contraction frequency of the intestinal bulb and the posterior intestine as well as the transit time. Infection of larvae, following injection of a HuNoV GII.4-containing stool sample in the yolk, resulted in an increased contraction frequency in the intestinal bulb. A comparable effect was observed in serotonin-treated larvae, corresponding to the natural function of serotonin. The higher replication efficacy of HuNoV GII.4 likely explains why they have a more marked effect on gut motility, when compared to other genotypes. Additionally, transit time of fluorescent food was prolonged in HuNoV GII.4 infected larvae, suggesting a loss of coordination in bowel movements upon infection. To identify the proteins responsible for the effect, individual HuNoV non-structural proteins and virus-like particles (VLPs) were injected intraperitoneally (ip). VLPs carrying VP1/VP2, but not those with only VP1, induced increased contraction frequencies in the intestinal bulb in a dose-dependent manner. In conclusion, our findings suggest that the viral capsid and potentially the minor capsid protein VP2 play a crucial role in the aetiology of symptoms associated with HuNoV, potentially acting as a viral enterotoxin. This work contributes to the understanding of the pathophysiological mechanisms in HuNoV-induced disease and further attests zebrafish as a valuable HuNoV disease model.

Conformational Flexibility in Capsids Encoded by the Caliciviridae

Caliciviruses are a diverse group of non-enveloped, positive-sense RNA viruses with a wide range of hosts and transmission routes. Norovirus is the most well-known member of the Caliciviridae; the acute gastroenteritis caused by human norovirus (HuNoV), for example, frequently results in closures of hospital wards and schools during the winter months. One area of calicivirus biology that has gained increasing attention over the past decade is the conformational flexibility exhibited by the protruding (P) domains of the major capsid protein VP1. This was observed in structure analyses of capsids encoded by many species and is often a consequence of environmental cues such as metal ions, changes to pH, or receptor/co-factor engagement. This review summarises the current understanding of P-domain flexibility, discussing the role this region plays in caliciviral infection and immune evasion, and highlighting potential avenues for further investigation.

Construction of a stable 4T1 cell line expressing UL19 by the PiggyBac transposon system

To investigate the mechanism of the major capsid protein VP5 (encoded by the UL19 gene) of oncolytic herpes simplex virus type Ⅱ (oHSV2) in regulating the antitumor function of immune cells, we constructed a mouse breast cancer cell line 4T1-iRFP-VP5-GFP stably expressing VP5 protein, near-infrared fluorescent protein (iRFP), and green fluorescent protein (GFP) by using the PiggyBac transposon system. Flow cytometry and Western blotting were employed to screen the monoclonal cell lines expressing both GFP and VP5 and examine the expression stability of UL19 in the constructed cell line. The results of SYBR Green I real-time PCR and Western blotting showed that the copies of UL19 and the expression level of VP5 protein in the 15th passage of 4T1-iRFP-VP5-GFP cells were significantly higher than those in the 4T1 cells transiently transfected with UL19, demonstrating the stable insertion of UL19 into the 4T1 cell genome. The real-time cell analysis (RTCA) was employed to monitor the proliferation of 4T1-iRFP-VP5-GFP cells, which showed similar proliferation activity to their parental 4T1 cells. Further studies confirmed that NK92 cells exhibited stronger cytotoxicity against 4T1-iRFP-VP5-GFP cells than against 4T1 cells. This study layed a foundation for elucidating the role of VP5 protein in regulating immune cells, including T cells and NK cells, via HLA-E in 4T1 cells to exert the anti-tumor function.

Identification and Characterization of Linear Epitopes of Monoclonal Antibodies Against African Horse Sickness Virus Serotype 1 VP2 Protein.

African horse sickness (AHS) is an acute, fatal, contagious disease of animals of the family Equidae and is caused by infection with the African horse sickness virus (AHSV). Based on the outer capsid protein VP2, AHSV is classified into nine serotypes (AHSV-1 to -9) with little or no serological cross-reactivity between them. In 2020, AHS outbreaks caused by AHSV-1 were reported in Thailand and Malaysia, marking the first occurrences of AHS in Southeast Asia. However, little is known about the antigenic profile of AHSV-1 VP2. In this study, a recombinant VP2 protein was expressed in Escherichia coli and used as an immunogen, and three monoclonal antibodies (mAbs), designated 7D11, 10A9, and 9E7, against AHSV-1 VP2, were generated. These three mAbs were then successfully used in IFA, WB, and ELISA for the detection of AHSV-1 VP2. Two overlapping linear epitopes, 670NEFDFE675 (E670-675) recognized by 9E7 and 670NEFDF674 (E670-674) recognized by 7D11 and 10A9, were identified through truncation of GST-fused VP2. Amino acid sequence alignment shows that the 670NEFDFE675 motif is completely conserved within AHSV-1 but is highly divergent in other AHSV serotypes. Our studies provide an important tool for basic research into AHSV-1 and for the diagnosis of AHSV-1.

Novel virulence determinants in VP1 regulate the assembly of enterovirus-A71.

EV-A71 causes hand, foot, and mouth disease in children. In this study, we discovered three highly conserved residues at positions 75, 78, and 88 of the capsid protein VP1 as the potential virulence determinants of EV-A71, which can influence viral replication by regulating the assembly of EV-A71. Mechanistic studies revealed that VP1-T75A could affect the maturation cleavage of the VP0 precursor, resulting in deficiencies in binding to the receptor SCARB2, viral attachment, internalization, and even uncoating. For the mutants of T78A and G88A, more noninfectious empty particles were produced during viral assembly. The discovery of these novel determinants of EV-A71 virulence will promote the study of the pathogenesis of enteroviruses.

Antigen-Specific T Cell Receptor Discovery for Treating Progressive Multifocal Leukoencephalopathy.

Progressive multifocal leukoencephalopathy (PML) is a frequently fatal disease of the central nervous system caused by JC virus (JCV). Survival is dependent on early diagnosis and ability to re-establish anti-viral T cell immunity. Adoptive transfer of polyomavirus-specific T cells has shown promise; however, there are no readily available HLA-matched anti-viral T cells to facilitate rapid treatment. Identify epitopes of the JCV major capsid protein VP1 that elicit an immune response in the context of human leukocyte antigen allele A*02:01 (HLA-A2) and isolate cognate T cell receptors (TCRs) from healthy donors. Evaluate individual VP1-specific TCRs for their capacity to be expressed in T cells and clear JCV in vitro . PBMCs from HLA-A2+ healthy donors were stimulated with peptide libraries tiled across the JCV VP1 protein. Multiple rounds of stimulation were performed to identify the antigens that induced the largest expansion and CD8 + T cell response (measured as INF γ , TNF α , CD137, and CD69 expression). High-affinity, antigen-specific CD8 + T cells were isolated based on intensity of tetramer binding for downstream single-cell TCR sequencing. Candidate TCRs were selected based on tetramer binding affinity and activation assays. Promising TCRs were introduced into the T cell genome via viral transduction for in vitro validation including peptide-pulsed K562 cells and astrocyte cells, and JCV-infected astrocytes. Four conserved JCV VP1 epitopes (amino acids 100-108, 251-259, 253-262, and 274-283) presented by HLA-A2 were identified. VP1(100-108) consistently elicited the highest level of IFN- γ production from multiple donors and this peptide is in a highly conserved region of VP1. We next identified fourteen high avidity TCRs specific for VP1(100-108). When virally transduced into primary human T cells, seven of these TCRs demonstrated specific binding to VP1(100-108):HLA-A2 tetramers, and four showed increased IFN- γ response when incubated with peptide. Primary CD8 + T cells expressing two of these TCRs cleared both HLA-A2 positive K562 cells and HLA-A2 positive SVG astrocyte cell line presenting exogenously added VP1 peptide at a range of E:T ratios. In addition, both TCR-transduced T cell populations effectively lysed JCV-infected astrocytes. We identified JCV VP1 epitopes that are immunogenic in the context of HLA-A2 MHC-I, including epitopes that have not been previously described. The VP1(100-108) epitope was used to isolate HLA-A2-restricted TCRs. When cloned into primary human CD8 + T cells, these TCRs recognized VP1 (100-108)-presenting targets, and the transduced T cells conferred cytotoxic activity and eliminated K562 and astrocyte cells displaying the VP1(100-108) peptide and not sham peptide, as well as JCV-infected astrocytes. Taken together, these data suggest that JCV VP1-specific TCRs could be appealing therapeutics for HLA-A2+ individuals with PML in whom intrinsic T cell immunity cannot be rescued.

Molecular Analysis of Coxsackievirus B2 Associated With Severe Symptoms of the Central Nervous System.

Coxsackievirus B2 (CVB2) is a member of the enterovirus group known to induce a spectrum of illnesses, from mild to severe. In the summer of 2022, an unusual outbreak of enteroviral central nervous system (CNS) infections occurred that was attributed to CVB2. Cerebrospinal fluid (CSF) samples collected from patients in 2015-2022 were tested for enterovirus via RT-PCR, followed by Sanger sequencing for positive cases. CVB2 samples were further sequenced in the P1 region using NGS. A total of 30 CSF samples were identified as CVB2, with 60% of these cases occurring between June and August 2022. The 2022 CVB2 variants were associated with severe clinical symptoms, including encephalitis (50%) and ataxia (27.8%). Samples from 2015 to 2020 were also included due to the absence of these symptoms. Phylogenetic analysis revealed that CVB2 strains from 2019 to 2020 were also distinct from those obtained in 2022. Amino acid analysis of the capsid proteins VP1, VP2, and VP3 identified three unique substitutions with potential antigenic significance in the 2022 variant: S67A in VP2, and T93A and E274D in VP1. These substitutions were not present in earlier strains or reported in the literature, suggesting they may influence the virus's virulence. The clinical observations from this study highlight new patterns of CVB2 infection in the CNS that had not been previously observed. Additionally, it identifies unique genetic changes in the 2022 CVB2 variant that may account for the increased virulence seen in the 2022 outbreak. However, further analysis is required to validate this assumption.

In Silico Development of a Multi-Epitope Subunit Vaccine against Bluetongue Virus in Ovis aries Using Immunoinformatics.

The bluetongue virus (BTV), transmitted by biting midges, poses a significant threat to livestock globally. This orbivirus induces bluetongue disease, leading to substantial economic losses in the agricultural sector. The current control measures have limitations, necessitating the development of novel, efficient vaccines. In this study, an immunoinformatics approach is employed to design a multi-epitope subunit vaccine for Ovis aries targeting six BTV serotypes. Focusing on the VP2 capsid protein, the vaccine incorporates B-cell, helper-T lymphocytes (HTL), and cytotoxic T-cell lymphocytes (CTL) epitopes. Molecular docking reveals stable interactions with TLR2 and TLR4 receptors, suggesting the stability of the complex, indicating the potential viability of the multi-epitope vaccine. The computational approach offers a rapid and tailored strategy for vaccine development, highlighting potential efficacy and safety against BTV outbreaks. This work contributes to understanding BTV and presents a promising avenue for effective control.

The Feline calicivirus capsid protein VP1 is a client of the molecular chaperone Hsp90.

Feline calicivirus (FCV) icosahedral viral capsids are composed of dozens of structural subunits that rely on cellular chaperones to self-assemble in an orderly fashion. Here, we report that the heat shock protein 90 (Hsp90) inhibition significantly reduced FCV particle production, suggesting a role in the replicative cycle. We found that Hsp90 inhibition was not related to the synthesis or stability of the early proteins that translate from the gRNA nor to the minor capsid protein VP2 but with a reduction in the major capsid protein VP1 levels, both translated late in infection from the subgenomic RNAs. Reduction in VP1 levels was observed despite an augment of the leader of the capsid (LC)-VP1 precursor levels, from which the LC and VP1 proteins are produced after proteolytic processing by NS6/7. The direct interaction of VP1 with Hsp90 was observed in infected cells. These results suggest that upon release from the polyprotein precursor, VP1 becomes a client of Hsp90 and that this interaction is required for an efficient FCV replicative cycle.

The conserved cysteines at position 18, 36, and 49 of Autographa californica multiple nucleopolyhedrovirus VP39 are essential for virus replication.

Autographa californica nucleopolyhedrovirus orf89 (vp39) encodes the major capsid protein VP39. Multiple alignments of protein sequences showed that VP39 has 8 conserved cysteine (Cys) residues. Cysteine residues play an important role in proper function of a protein. To determine the importance of these conserved cysteine residues for virus proliferation, a series of recombinant viruses harboring VP39-Cys mutants were constructed. Viral growth curves and transmission electron microscopy showed that mutation of Cys29, Cys132, Cys169, Cys229, or Cys232 of VP39 to alanine did not affect budded virion production; however, the mutation of Cys18, Cys36, or Cys49 to alanine resulted in interruption of capsid assembly. Co-immunoprecipitation assays showed that mutations of these 8 cysteines individually or simultaneously had no effect on self-association of VP39. Immunofluorescence analysis by confocal microscopy revealed that the subcellular localization of VP39 with mutations in Cys18, Cys36 or Cys49 was exclusively distributed in the cytoplasm of a cell regardless of virus infection or not, while the wild-type VP39 or the VP39 carrying mutations in Cys29, Cys132, Cys169, Cys229, or Cys232 was distributed throughout the cytoplasm and the nucleus. Our results demonstrated that Cys18, Cys36, and Cys49 are essential for the proper localization of VP39, which is a prerequisite for successful nucleocapsid assembly of the virus.

Bivalent norovirus mRNA vaccine elicits cellular and humoral responses protecting human enteroids from GII.4 infection

Nucleoside-modified mRNA-LNP vaccines have revolutionized vaccine development against infectious pathogens due to their ability to elicit potent humoral and cellular immune responses. In this article, we present the results of the first norovirus vaccine candidate employing mRNA-LNP platform technology. The mRNA-LNP bivalent vaccine encoding the major capsid protein VP1 from GI.1 and GII.4 of human norovirus, generated high levels of neutralizing antibodies, robust cellular responses, and effectively protected human enteroids from infection by the most prevalent genotype (GII.4). These results serve as a proof of concept, demonstrating that a modified-nucleoside mRNA-LNP vaccine based on norovirus VP1 sequences can stimulate an immunogenic response in vivo and generates neutralizing antibodies capable of preventing viral infection in models of human gastrointestinal tract infection.

Molecular detection and quantification of canine parvovirus 2 using a fast and sensitive SYBR® green-based quantitative polymerase chain reaction assay in dogs affected with gastroenteritis

Background and Aim: Viral gastroenteritis in canines is primarily caused by the canine parvovirus 2 (CPV-2). Infections by this virus can cause severe consequences in dogs, such as fever, vomiting, diarrhea, septicemia, systemic inflammation, and immunosuppression. Therefore, the mortality rate of persistent infections caused by this virus is significantly high. The capsid protein VP2 genome of canine parvovirus has undergone many changes, resulting in the emergence of different genotypes, including CPV-2a, CPV-2b, and CPV-2c. Diagnostic procedures often lack the necessary specificity for early infection diagnosis. Early detection of the infection enhances the likelihood of canine survival because the canine will receive prompt therapy. Hence, this study aimed to develop a quantitative polymerase chain reaction (qPCR)-based diagnostic technique using SYBR Green for the rapid and accurate detection and quantification of CPV-2. Materials and Methods: The assay was specifically designed to identify a portion of the conserved NS gene using primers that amplify a 125-bp fragment. The qPCR method was executed in the fast mode to expedite the process using Power up SYBR Green Master Mix reagent. A standard curve was constructed using the amplified and purified PCR product of the NS gene. Results: The limit of detection and quantification were determined in the one amplified-DNA copy. The standard curve showed an efficiency of 99.5% and inter- and intra-assay coefficients of variation of 0.387%–0.976% and 0.085%–0.430%, respectively. The assay was specific for the amplification of CPV-2, as no amplification was observed for other viral genomes (canine adenovirus II, canine distemper virus, canine coronavirus, and canine astrovirus) or from the negative controls. Inter- and intra-tests for repeatability showed low test variability around the run time. To validate the present assay, 200 samples of fezzes from canines with gastroenteritis and symptoms associated with enteric infection were tested using the qPCR protocol. From the analyzed samples, 136 were positive for CPV-2 by qPCR assay, of which 110 were before diagnostic positive for the virus by endpoint PCR, showing high sensitivity of the current assay. CPV-2 was detected in dogs over 2 weeks old up to dogs 9 years old, where the highest viral concentration found was 16429595 gene copies in dogs aged 2 weeks. Conclusion: In the present study, a rapid, specific, repeatable, and sensitive assay was developed for the detection and quantification of CPV-2. Furthermore, it was demonstrated that in the population of domestic dogs in Ecuador affected with gastrointestinal disease, the virus is presented in dogs of different ages and not only in young dogs. Keywords: canine parvovirus, gastroenteritis, quantitative polymerase chain reaction, SYBR green.

Impact of VP2 structure on antigenicity: comparison of BTV1 and the highly virulent BTV8 serotype.

Bluetongue virus (BTV) is an agriculturally and economically significant insect-borne virus that causes serious illness and death in sheep and other domestic and wild ruminants in large areas of the world. Numerous BTV serotypes exist, and distant serotypes exhibit unique neutralizing antibody profiles, which target the outermost capsid protein VP2. The predominant serotype-specific nature of the antibody response to VP2 is a barrier to the development of broad-spectrum prophylactic BTV vaccine candidates. Although VP2 is the main serotype determinant of BTV, the structural basis of serotype specificity has not been investigated. In this study, we utilized the recently available atomic structure of VP2 with a modeled tip domain to carry out in silico structural comparisons between distant serotypes BTV1 and BTV8. These analyses identified structural differences in the tip domain, positioned at the apex of VP2, and informed the design of mutant VP2 constructs. Dissection of tip domain antigenicity demonstrated that the region of structural difference between BTV1 and highly virulent BTV8 was a target of BTV neutralizing antibodies and that mutation of this region resulted in a loss of neutralizing antibody recognition. This study has for the first time provided insights into the structural differences, which underpin the serotype-specific neutralizing antibody response to BTV.IMPORTANCEThe immune system can protect against virus infection by producing antibodies, which bind and inhibit the virus from infecting the susceptible host. These antibodies are termed neutralizing antibodies and generally target the viral receptor binding protein, such as the VP2 of bluetongue virus (BTV). This pressure from the immune system can drive mutation of the viral protein resulting in escape from antibody-mediated neutralization and the evolution of serotypes, as is the case for BTV. Understanding the structural differences, which underpin the different BTV serotypes, could help guide the design of a BTV vaccine that targets multiple serotypes. In this study, we have mapped the VP2 structural differences between distant serotypes, to a region targeted by neutralizing antibodies, and have demonstrated for the first time how VP2 structure is the fundamental basis of serotype specificity.

Mouse polyomavirus infection induces lamin reorganisation.

The nuclear lamina is a dense network of intermediate filaments beneath the inner nuclear membrane. Composed of A-type lamins (lamin A/C) and B-type lamins (lamins B1 and B2), the nuclear lamina provides a scaffold for the nuclear envelope and chromatin, thereby maintaining the structural integrity of the nucleus. A-type lamins are also found inside the nucleus where they interact with chromatin and participate in gene regulation. Viruses replicating in the cell nucleus have to overcome the nuclear envelope during the initial phase of infection and during the nuclear egress of viral progeny. Here, we focused on the role of lamins in the replication cycle of a dsDNA virus, mouse polyomavirus. We detected accumulation of the major capsid protein VP1 at the nuclear periphery, defects in nuclear lamina staining and different lamin A/C phosphorylation patterns in the late phase of mouse polyomavirus infection, but the nuclear envelope remained intact. An absence of lamin A/C did not affect the formation of replication complexes but did slow virus propagation. Based on our findings, we propose that the nuclear lamina is a scaffold for replication complex formation and that lamin A/C has a crucial role in the early phases of infection with mouse polyomavirus.

Biological and immunological characterization of major capsid protein VP1 from distinct GII.2 norovirus clusters

Human noroviruses (HuNoVs) are a leading cause of acute viral gastroenteritis worldwide. Infectious outbreaks due to recombinant NoV genotype called GII.P16-GII.2 have been frequently reported since 2016. In this study, we expressed the major capsid protein VP1 from three GII.2 NoV strains using the recombinant baculovirus expression system. The assembly, histo-blood group antigen (HBGA)-binding patterns, and cross-blocking abilities of VP1 proteins were investigated. All the three NoV VP1 proteins successfully assembled into virus-like particles (VLPs). The HBGA-binding assay demonstrated a temporal binding pattern. The latest isolate bound to saliva samples of all blood types. Sequence alignment suggested that the observed gain in HBGA-binding ability was attributed to a limited number of amino acid mutations. Using chimeric VP1 proteins, we demonstrated that synergistic effects resulted in enhanced binding ability. Bile salts increased GII.2 VLP avidity for HBGAs except GII.2-2011/M1. In vitro blockade assay of salivary HBGA-VLP binding demonstrated the presence of cross-blocking effects among different strains. This study provides insight into the evolutionary binding characteristics and cross-blocking effects of GII.2 NoVs to facilitate the development of measures to control this type of viruses.

Out-of-sync evolutionary patterns and mutual interplay of major and minor capsid proteins in norovirus GII.2.

Human noroviruses are the most common cause of viral gastroenteritis, resulting annually in 219 000 deaths and a societal cost of $60 billion, and no antivirals or vaccines are available. The minor capsid protein may play a significant role in the evolution of norovirus. GII.4 is the predominant genotype of norovirus, and its VP2 undergoes epochal co-evolution with the major capsid protein VP1. Since the sudden emergence of norovirus GII.2[P16] in 2016, it has consistently remained a significant epidemic strain in recent years. In the construction of phylogenetic trees, the phylogenetic trees of VP2 closely parallel those of VP1 due to the shared tree topology of both proteins. To investigate the interaction patterns between the major and minor capsid proteins of norovirus GII.2, we chose five representative strains of GII.2 norovirus and investigated their evolutionary patterns using a yeast two-hybrid experiment. Our study shows VP1-VP2 interaction in GII.2, with critical interaction sites at 167-178 and 184-186 in the highly variable region. In the intra-within GII.2, we observed no temporal co-evolution between VP1 and VP2 of GII.2. Notable distinctions were observed in the interaction intensity of VP2 among inter-genotype (P<0.05), highlighting the divergent evolutionary patterns of VP2 within different norovirus genotypes. In summary, the interactions between VP2 and VP1 of GII.2 norovirus exhibit out-of-sync evolutionary patterns. This study offered valuable insights for further understanding and completing the evolutionary mechanism of norovirus.

Coronavirus spike protein fragment-containing chimeric virus-like particles stimulate human dendritic cell maturation

Introduction. Viral capsid proteins can assemble into virus-like particles lacking infectivity and bearing parental virus antigens or artificially introduced antigens from other pathogens. At least some of such particles are highly immunogenic and could serve as a platform for promising vaccines. In this work, we assessed an effect of virus-like particles decorated with a SARS-CoV-2 spike protein fragment on human dendritic cell phenotype and functional properties. Materials and methods. The virus-like particles were assembled using chimeric molecules obtained by fusing genetic sequences encoding a norovirus major capsid protein VP1 fragment and a coronavirus spike protein fragment, including the receptor-binding domain. Dendritic cells were obtained from monocytes in vitro. Results. Incubation of immature dendritic cells with virus-like particles induced their phenotypic and functional maturation. The former was revealed by significantly increased expression of HLA-DR, CD80, CD86 and CD83. Dendritic cell phenotype after incubation with virus-like particles at the maximum concentration of 10 μg/ml did not differ significantly from that of mature dendritic cells in positive control. Along with phenotypic maturation, virus-like particles caused a manifold increase in the production of pro-inflammatory tumor necrosis factor-α, anti-inflammatory interleukin-10, as well as interleukin-6, which can stimulate both antibody synthesis and cellular pro-inflammatory reactions. The pronounced stimulation of dendritic cells by virus-like particles coated with coronavirus antigens evidence about successful particle recognition. Finally, we discuss plausible mechanisms for recognition of such virus-like particles by dendritic cell receptors. Conclusion. It has been shown that chimeric virus-like particles induced phenotypic and functional dendritic cell maturation, which is manifested by markedly elevated expression of functionally important membrane molecules, as well as a manifold rise in production of cytokines with a wide functional range. In our opinion, the data obtained indicate a promise of using virus-like particles based on norovirus proteins to display SARS-CoV-2 antigens.

VP1 of human and murine noroviruses recognizes glycolipid sulfatide via the P domain.

Noroviruses are a prevalent cause of human viral gastroenteritis, yet the precise mechanisms underlying their infection cycle, particularly their interactions with and entry into cells, remain poorly understood. Human norovirus (HuNoV) primarily targets human small intestinal epithelial cells, within which 3-O-sulfogalactosylceramide (sulfatide) ranks among the most abundant glycosphingolipids (GSLs). While sulfatide involvement in the binding and infection mechanism of several viruses has been documented, its interaction with noroviruses remains underexplored. This study investigated whether noroviruses interact with sulfatide. We found that the recombinant viral capsid protein VP1 of HuNoV (genogroups I and II) and murine norovirus (genogroup V) exhibited robust binding to sulfatide compared with other tested GSLs using enzyme-linked immunosorbent assay, thin-layer chromatography binding assay and real-time quantitative reverse transcription polymerase chain reaction binding assay. VP1 also bound 3-O-sulfated lactosylceramide, which shares the 3-O-sulfated galactose moiety with sulfatide. However, both VP1 and its P domain, identified as the sulfatide-binding domain, exhibited limited binding to structural analogues of sulfatide and other sulfated compounds. These findings suggest a specific recognition of the 3-O-sulfated galactose moiety. Notably, we found that sulfatide is a novel binding target for norovirus particles. Overall, our findings reveal a previously unknown norovirus-sulfatide interaction, proposing sulfatide as a potential candidate for norovirus infection receptors.

Surface Display of Duck Hepatitis A Virus Type 1 VP1 Protein on Bacillus subtilis Spores Elicits Specific Systemic and Mucosal Immune Responses on Mice.

Duck viral hepatitis, primarily caused by duck hepatitis A virus type 1 (DHAV-1), poses a significant threat to the global duck industry. Bacillus subtilis is commonly utilized as a safe probiotic in the development of mucosal vaccines. In this study, a recombinant strain of B. subtilis, designated as B. subtilis RV, was constructed to display the DHAV-1 capsid protein VP1 on its spore surface using the outer coat protein B as an anchoring agent. The immunogenicity of this recombinant strain was evaluated in a mouse model through mixed feeding immunization. The results indicated that B. subtilis RV could elicit specific systemic and mucosal immune responses in mice, as evidenced by the high levels of serum IgG, intestinal secretory IgA, and potent virus-neutralizing antibodies produced. Furthermore, the recombinant strain significantly upregulated the expression levels of IL-2, IL-6, IL-10, TNF-α, and IFN-γ in the intestinal mucosa. Thus, the recombinant strain maintained the balance of the Th1/Th2 immune response and demonstrated an excellent mucosal immune adjuvant function. In summary, this study suggests that B. subtilis RV can be a novel alternative for effectively controlling DHAV-1 infection as a vaccine-based feed additive.