Trivalent Combination Vaccine Induces Broad Heterologous Immune Responses to Norovirus and Rotavirus in Mice

Rotavirus (RV) and norovirus (NoV) are the two major causes of viral gastroenteritis (GE) in children worldwide. We have developed an injectable vaccine design to prevent infection or GE induced with these enteric viruses. The trivalent combination vaccine consists of NoV capsid (VP1) derived virus-like particles (VLPs) of GI-3 and GII-4 representing the two major NoV genogroups and tubular RV recombinant VP6 (rVP6), the most conserved and abundant RV protein. Each component was produced in insect cells by a recombinant baculovirus expression system and combined in vitro. The vaccine components were administered intramuscularly to BALB/c mice either separately or in the trivalent combination. High levels of NoV and RV type specific serum IgGs with high avidity (>50%) as well as intestinal IgGs were detected in the immunized mice. Cross-reactive IgG antibodies were also elicited against heterologous NoV VLPs not used for immunization (GII-4 NO, GII-12 and GI-1 VLPs) and to different RVs from cell cultures. NoV-specific serum antibodies blocked binding of homologous and heterologous VLPs to the putative receptors, histo-blood group antigens, suggesting broad NoV neutralizing activity of the sera. Mucosal antibodies of mice immunized with the trivalent combination vaccine inhibited RV infection in vitro. In addition, cross-reactive T cell immune responses to NoV and RV-specific antigens were detected. All the responses were sustained for up to six months. No mutual inhibition of the components in the trivalent vaccine combination was observed. In conclusion, the NoV GI and GII VLPs combination induced broader cross-reactive and potentially neutralizing immune responses than either of the VLPs alone. Therefore, trivalent vaccine might induce protective immune responses to the vast majority of circulating NoV and RV genotypes.     

Immune responses to the major capsid protein during parvovirus infection of rats

Rat virus (RV) is a common parvovirus of laboratory rodents which can disrupt rat-based research. Prenatal or perinatal infection can be pathogenic or lead to persistent infection, whereas infection of adult rats is typically self-limiting. Effects on the host immune system have been documented during RV infection, but little is known about immune responses necessary for viral clearance. Our studies were conducted to identify humoral and cellular responses to the predominant capsid protein, VP2, during experimental infection of adult rats. We observed VP2-specific proliferation, gamma interferon production, and an immunoglobulin G2a humoral response that is maintained for at least 35 days following RV infection. These results strongly suggest the induction of virus-specific Th1-mediated immunity.     

Misdirected antibody responses against an N-terminal epitope on human rhinovirus VP1 as explanation for recurrent RV infections

Rhinoviruses (RVs) are the primary cause of upper respiratory tract infections, generally known as the common cold. Moreover, RV infections can trigger severe exacerbations of asthma and chronic obstructive pulmonary disease (COPD). We expressed the 4 major RV capsid proteins, VP1-VP4, in Escherichia coli and used these proteins as well as recombinant and synthetic VP1 fragments to study and map antibody responses in RV-infected humans. VP1, which on infection binds to ICAM 1, was identified as a major target for the memory immune response, residing in the IgG1 subclass and IgA class. Interestingly, this response was mainly directed against an N-terminal 20 mer peptide in VP1, P1a, which becomes exposed on intact RV only when it docks to its receptor ICAM 1. Molecular modeling using the 3-dimensional RV capsid structures revealed that P1a was localized inside the capsid and outside the areas involved in receptor binding or RV neutralization. Our results suggest misdirection of antibody responses against a nonprotective epitope as a mechanism how RV escapes immunity and causes recurrent infections. Based on these findings, it may be possible to design vaccines against RV infections and RV-induced respiratory diseases.     

DNA vaccination against foot-and-mouth disease via electroporation: study of molecular approaches for enhancing VP1 antigenicity

BACKGROUND: Foot-and-mouth disease virus (FMDV) affects susceptible livestock animals and causes disastrous economic impact. Immunization with plasmid expressing VP1 that contains the major antigenic epitope(s) of FMDV as cytoplasmic protein (cVP1) failed to elicit full protection against FMDV challenge. MATERIALS AND METHODS: In this study, mice were immunized via electroporation with four cDNA expression vectors that were constructed to express VP1 of FMDV, as cytoplasmic (cVP1), secreted (sVP1), membrane-anchored (mVP1) or capsid precursor protein (P1), respectively, to evaluate whether expression of VP1 in specific subcellular compartment(s) would result in better immune responses. RESULTS: Electroporation enhanced immune responses to vectors expressing cVP1 or P1 and expedited the immune responses to vectors expressing sVP1 or mVP1. Immunization of mice via electroporation with mVP1 cDNA was better than sVP1 or cVP1 cDNA in eliciting neutralizing antibodies and viral clearance protection. Vaccination with P1 cDNA, nonetheless, yielded the best immune responses and protection among all four cDNAs that we tested. CONCLUSIONS: These results suggest that the antigenicity of a VP1 DNA vaccine can be significantly enhanced by altering the cellular localization of the VP1 antigen. Electroporation is a useful tool for enhancing the immune responses of vectors expressing VP1 or P1. By mimicking FMDV more closely than that of transgenic VP1 and eliciting immune responses favorably toward Th2, transgenic P1 may induce more neutralizing antibodies and better protection against FMDV challenge.     

Natural immunity to rotavirus infection in children

Annual deaths in infants and young children due to rotavirus (RV) infection are around 100,000 in India and about 600,000 globally. Development of a vaccine for this disease is a high priority. The protective mechanisms for RV diarrhea in human are not fully understood, but it is known that children develop natural immunity against RV. Early exposure to RV results in most severe episode of diarrhea and subsequent infections are milder or asymptomatic. Of the immune responses measured during natural infection, RV-specific antibodies have been well documented, whereas data on cellular immunity in humans are sparse. It is generally thought that two outer capsid proteins VP4 and VP7 play a critical role in protective immunity by stimulating production of neutralizing antibodies. While serotype- specific protection mediated by antibodies directed against the outer capsid proteins may be a mechanism of protection, such a correlate for protection has been difficult to demonstrate in humans during clinical trials. Increasing evidences suggest that viral proteins that lack a capacity of eliciting neutralizing antibody response also induce protective immunity. Limited efforts have focused on the role of non-structural proteins in protective immunity. This review describes current understanding of antibody responses in children with focus on responses specific to viral antigens with their possible role in protective immunity. We have also briefly reviewed the responses elicited to non-antibody effectors during RV infection in human subjects.     

The VP6 protein of rotavirus interacts with a large fraction of human naive B cells via surface immunoglobulins

Immunity to human group A rotavirus (RV), a major cause of viral gastroenteritis in infants, involves B lymphocytes that provide RV-specific antibodies. Additionally, some arguments suggest that naive B cells could be implicated in the first steps of the immune response against RV. The aim of our study was to analyze the interaction of VP6 and VP7 RV capsid proteins with human B cells depending on the immune status of the individual, i.e., naive or RV experienced. For this purpose, a two-color virus-like particle flow cytometry assay was devised to evaluate the blood B-lymphocyte reactivity to VP6 and VP7 proteins from healthy RV-exposed adults, recently infected infants, and neonates at birth. Both VP6 and VP7 interactions with B cells were mediated by surface immunoglobulins and probably by their Fab portions. VP7-reactive B lymphocytes were mainly detected from RV-experienced patients and almost exclusively in the CD27-positive memory cell fraction. Conversely, VP6-reactive B lymphocytes were detected at similar and high frequencies in adult, infant, and neonate samples. In adult samples, VP6 reacted with about 2% of the CD27-negative (CD27(neg)) naive B cells. These results demonstrated that the VP6 RV protein interacted with a large fraction of naive B lymphocytes from both adults and neonates. We propose that naive B cell-VP6 interaction might influence the strength and quality of the acquired immune response and should be considered for elaborating RV vaccine strategies.     

Antigenic sequences of poliovirus recognized by T cells: serotype-specific epitopes on VP1 and VP3 and cross-reactive epitopes on VP4 defined by using CD4+ T-cell clones.

A panel of poliovirus-specific murine CD4+ T-cell clones has been established from both BALB/c (H-2d) and CBA (H-2k) mice immunized with Sabin vaccine strains of poliovirus serotype 1, 2, or 3. T-cell clones were found to be either serotype specific or cross-reactive between two or all three serotypes. Specificity analysis against purified poliovirus proteins demonstrated that T-cell clones recognized determinants on the surface capsid proteins VP1, VP2, and VP3 and the internal capsid protein VP4. Panels of overlapping synthetic peptides were used to identify eight distinct T-cell epitopes. One type 3-specific T-cell clone recognized an epitope within amino acids 257 and 264 of VP1. Three T-cell epitopes corresponding to residues 14 to 28, 189 to 203, and 196 to 210 were identified on VP3 of poliovirus type 2. The remaining four T-cell epitopes were mapped to an immunodominant region of VP4, encompassed within residues 6 and 35 and recognized by both H-2d and H-2k mice. The epitopes on VP4 were conserved between serotypes, and this may account for the predominantly cross-reactive poliovirus-specific T-cell response observed with polyclonal T-cell populations. In contrast, T-cell clones that recognize epitopes on VP1 or VP3 were largely serotype specific; single or multiple amino acid substitutions were found to be critical for T-cell recognition.     

Cross-reactive neutralization epitopes on VP3 of human rotavirus: analysis with monoclonal antibodies and antigenic variants.

We analyzed cross-reactive neutralization epitopes on protein VP3 of human rotavirus (HRV) by the use of neutralizing monoclonal antibodies (N-MAbs), which showed a variety of interserotypic reactivity patterns when examined in a neutralization test and an enzyme-linked immunosorbent assay against 15 HRV and 2 animal RV strains. Serological study with the six cross-reactive N-MAbs revealed antigenic variations in some HRV strains within the same serotype as well as a marked antigenic difference between serotype 2 strains and serotype 1, 3, and 4 strains. Epitope analysis of the antigenic variants resistant to the six individual cross-reactive N-MAbs suggested the existence of at least three distinct cross-reactive neutralization epitopes on VP3 of HRV.     

A Novel Mucosal Vaccine Against Foot-and-Mouth Disease Virus Induces Protection in Mice and Swine

Epitopes of a foot-and-mouth disease virus (FMDV) capsid protein VP1 complex and a chimera of 6×His-tagged cholera toxin B subunit (hCTB) were expressed in Hansenula polymorpha and used together as a mucosal vaccine. Antibody and cytokine responses to VP1–hCTB vaccine and protection against FMDV were evaluated by ELISA and a virus challenge test in mice, respectively. VP1–hCTB directly enhanced the expression of interleukin-5 (IL-5) both in serum and supernatants of cultured spleen cells. After challenging suckling mice with 10⁵ FMDV (=50% lethal dosage per mouse) a greater protection was seen after intraperitoneal and intranasal vaccinations than after oral vaccination. In swine immunized with VP1–hCTB, immune responses were achieved after three administrations, and the vaccine protected swine (80%) when challenged with 10^6.5 FMDV (=50% infectious dosage per swine). These results demonstrated the possibility of using CTB as a mucosal adjuvant to elicit protective immune responses against FMDV. Houhui Song, Zhiliang Wang and Dongxia Zheng contributed equally to this work.     

Class II-restricted T cell responses in Theiler's murine encephalomyelitis virus-induced demyelinating disease. IV. Identification of an immunodominant T cell determinant on the N-terminal end of the VP2 capsid protein in susceptible SJL/J mice.

Theiler's murine encephalomyelitis virus (TMEV)-induced demyelinating disease serves as a relevant animal model of human multiple sclerosis. Myelin damage induced by TMEV infection appears to be immune mediated. Disease susceptibility correlates best with the temporal development of chronic, high levels of TMEV-specific, MHC class II-restricted delayed-type hypersensitivity (DTH) responses. We have proposed a model wherein these responses result in CNS demyelination via a macrophage-mediated terminal nonspecific bystander response. As virus-specific DTH responses appear to be intimately involved in the pathogenicity of CNS demyelination, it is critical to determine the specificity of these responses so that effector T cells specific for potential pathogenic epitopes can be targeted to serve as the focus of specific immunoregulatory processes. In the current study, the capsid protein specificity of the TMEV-susceptible SJL/J and TMEV-resistant C57BL/6 mouse strains was examined. DTH and Tprlf responses in both infected and immunized SJL/J mice were found to be predominantly directed toward the VP2 capsid protein, specifically to an epitope(s) contained within the N-terminal 150 amino acids of VP2. This same epitope was also found to be dominant in priming SJL/J mice for responses to challenge with intact virions. In contrast, the T cell-mediated responses of TMEV-resistant C57BL/6 mice did not show preferential reactivity towards VP2, because all three major capsid proteins (VP1, VP2, and VP3) elicited responses with essentially equal potency. The relationship of the restricted VP2 T cell epitope to predicted neutralizing antibody sites on the VP2 protein is discussed as is the potential use of this epitope for prevention and/or treatment of TMEV-induced demyelinating disease via the induction of epitope-specific tolerance.     

长春地区轮状病毒流行株VP7基因的遗传变异

A组轮状病毒是引起婴幼儿秋冬季病毒性腹泻的主要病原.目前没有有效的治疗药物,应用安全而有效的疫苗是控制重症腹泻的首要措施.对当地A组轮状病毒流行株的主要中和抗原VP7的编码基因进行遗传变异分析,可以为疫苗的应用和开发提供有益的指导.利用ELISA方法对长春地区1999～2005年的腹泻患儿标本检测A组轮状病毒,RT-PCR方法对阳性标本进行G血清分型,发现长春地区2001年以后流行的轮状病毒以G3型血清为主.选取1999～2005年的G3型轮状病毒标本31份,对其VP7基因进行扩增、克隆、测序,经过计算机分析比对,31株G3型轮状病毒VP7基因核苷酸序列没有显著差异.同一流行季节的毒株具有较相似的遗传变异特征.在2003年轮状病毒流行季节内,有6株G3型分离株的VP7基因在碱基1 038位置上出现一个碱基缺失.毒株发生在A、B、C三个高变区的碱基突变,位点相同或者位置临近.2002年以后毒株的基因突变增加,非高变区的碱基变异增加,这可能有助于维持G3型轮状病毒成为流行株.有规律的变异多发生在高变区,但是非高变区的非连续性变异的增加值得引起注意.     

表达轮状病毒G2和G3型vp7基因重组腺病毒的免疫效果

为探索以非复制型腺病毒为表达载体的多价轮状病毒(Rotavirus,RV)基因工程疫苗的可行性,在前期工作的基础上,对表达我国G2和G3型RV流行毒株vp7基因的重组腺病毒的免疫效果进行了研究。分别用表达G2和G3型vp7基因的重组腺病毒rvAdG2VP7、rvAdG3VP7经滴鼻和灌胃两种途径免疫Balb/c小鼠,对免疫后小鼠的血清抗体、黏膜抗体和相关的细胞因子水平进行了检测和比较。结果表明,用表达G2和G3型vp7基因的重组腺病毒经滴鼻和灌胃两种途径免疫小鼠后,均可诱导机体产生较强的RV特异性免疫反应,包括体液免疫、细胞免疫和黏膜免疫,并能产生中和抗体。但免疫反应以Th2类为主,Th1类反应也占有相当的比例。本研究为新型RV基因工程疫苗的深入研究奠定了基础。     

2018–2020年人轮状病毒锦州地方株VP4及VP7基因特征

【背景】人A组轮状病毒(Rotavirus Group A,RVA)是婴幼儿胃肠炎的主要病原体及发展中国家婴幼儿死亡的重要原因,目前无特效药物治疗,疫苗预防是唯一可行的预防感染方法。外衣壳蛋白VP7和VP4是疫苗设计的主要靶点,针对该基因加强RVA地方株分子流行病学监测十分必要。【目的】对锦州地方流行RVA株VP7和VP4基因进行型别鉴定和序列特征分析。【方法】收集锦州地区2018-2020年RVA感染腹泻患儿的粪便标本,提取病毒RNA,通过RT-PCR扩增VP7、VP4基因片段并测序,得到7株RVA VP7和VP4序列。使用在线基因分型工具Rota C V2.0对测序结果进行分型分析。应用BLAST、DNAStar、MEGA X、Bio Edit等生物软件与临床流行株及疫苗株进行系统发育分析及氨基酸序列比对分析。【结果】分型结果表明7株锦州地方株均为G9P[8]型,系统发育分析证实其VP7和VP4基因分别属于G9-Ⅵ和P[8]-3谱系,核苷酸序列相似性分别为99.32%-100%与99.41%-100%。JZ株VP7与疫苗株Rotavac和Rotasiil相比,在抗原表位区7-1a、7-1b、7-2中分别存在4个和3个氨基酸替换。JZ株VP4与疫苗株Rotarix和Rota Teq VP4氨基酸序列相比,发现7个和4个氨基酸替换,位于抗原表位区8-1和8-3。【结论】2018-2020年在辽宁锦州地区检测到7株G9P[8]型RVA株,VP7和VP4序列相似性高于99%,G9P[8]型可能是辽宁省锦州地区2018-2020年婴幼儿轮状病毒腹泻的主要流行基因型之一。与同基因型疫苗株比较,位于JZ株VP7和VP4抗原表位区的氨基酸位点差异对于野毒株免疫逃逸机制的研究具有意义。     

How do antigenically varying pathogens avoid cross-reactive responses to invariant antigens?

Pathogens such as trypanosomes and malaria use antigenic variation to evade immune responses and prolong the duration of infections. As pathogens typically express more than one antigen, even relatively rare conserved antigens might be expected to trigger cross-reactive immune responses capable of clearing the infection. We use simple mathematical models that explicitly consider the dynamic interplay between the replicating pathogen, immune responses to different antigens and immune exhaustion to explore how pathogens can escape the responses to both variable and invariant (conserved) antigens. Our results suggest two hypotheses. In the first, limited quantities of invariant antigens on each pathogen may lead to saturation in killing by cross-reactive responses. In the second, antigenic variation of the dominant antigens prolongs the duration of infection sufficiently to allow for exhaustion of the cross-reactive responses to subdominant, invariant epitopes prior to their being able to control the infection. These hypotheses make distinct predictions: the former predicts that cross-reactive responses will always be ineffective while the latter predicts that appropriately timed treatment could, by preventing exhaustion, lead to the generation of long-lasting protective cross-reactive immunity and thus act similarly to a vaccine.     

Expression and characterization of virus-like particles containing rubella virus structural proteins.

Rubella virus (RV) virions contain two envelope glycoproteins (E1 and E2) and a capsid protein (C). Noninfectious RV-like particles (VLPs) containing three structural proteins were expressed in a BHK cell line (BHK-24S) by using an inducible promoter. These VLPs were found to resemble RV virons in terms of their size, their morphology, and some biological activities. In immunoblotting studies, VLPs were found to bind similarly to native RV virions with 10 of a panel of 12 RV-specific murine monoclonal antibodies. Immunization of mice with VLPs induced specific antibody responses against RV structural proteins as well as virus-neutralizing and hemagglutination-inhibiting antibodies. After immunization of mice with VLPs, in vitro challenge of isolated lymphocytes with inactivated RV and individual RV structural proteins stimulated proliferation. Our data suggest the possibility of using VLPs as immunogens for serodiagnostic assays and RV vaccines.     

Generation of recombinant rotavirus with an antigenic mosaic of cross-reactive neutralization epitopes on VP4

Recombinant rotavirus (RV) with cDNA-derived chimeric VP4 was generated using recently developed reverse genetics for RV. The rescued virus, KU//rVP4(SA11)-II(DS-1), contains SA11 (simian RV strain, G3P[2])-based VP4, in which a cross-reactive neutralization epitope (amino acids 381 to 401) on VP5* is replaced by the corresponding sequence of a different P-type DS-1 (human RV strain, G2P[4]). Serological analyses with a panel of anti-VP4- and -VP7-neutralizing monoclonal antibodies revealed that the rescued virus carries a novel antigenic mosaic of cross-reactive neutralization epitopes on its VP4 surface. This is the first report of the generation of a recombinant RV with artificial amino acid substitutions.     

Immunogenicity and virus-like particle formation of rotavirus capsid proteins produced in transgenic plants

The human pathogen, group A rotavirus, is the most prevalent cause of acute infantile and pediatric gastroenteritis worldwide, especially in developing countries. There is an urgent demand for safer, more effective and cheaper vaccines against rotavirus infection. Plant-derived antigens may provide an exclusive way to produce economical subunit vaccines. Virus-like particles, constituting viral capsid proteins without viral nucleic acids, are considered a far safer candidate compared with live attenuated viral vaccines. In this study, the rotavirus capsid proteins VP2, VP6 and VP7 were co-expressed in transgenic tobacco plants, and their expression levels, formation of rotavirus-like particles (RV VLPs) and immunogenicity were extensively studied. Quantitative real-time RT-PCR and Western blot analysis revealed that the expression level of vp6 was the highest while vp7 was expressed at the lowest levels. The RV VLPs were purified from transgenic tobacco plants and analyzed by electron microscopy and Western blot. Results indicated that the plant-derived VP2, VP6 and VP7 proteins self-assembled into 2/6 or 2/6/7 RV VLPs with a diameter of 60–80 nm. When orally delivered into mice with cholera toxin as an adjuvant, the total soluble protein extracted from transgenic tobacco plants induced rotavirus-specific antibodies comparable with those of attenuated rotavirus vaccines, while VP 2/6/7 induced higher serum IgG and fecal IgA titers compared with VP 2/6.     

Protection of rhesus monkeys against infection with minimally pathogenic simian-human immunodeficiency virus: correlations with neutralizing antibodies and cytotoxic T cells

We studied the capacity of active immunization of rhesus monkeys with HIV-1 envelope protein (Env) to induce primary virus cross-reactive neutralizing antibodies to prevent infection following intravenous challenge with simian-human immunodeficiency virus (SHIV). Monkeys were immunized with the human immunodeficiency type 1 (HIV-1) strain R2 Env. Initially, the Env was expressed in vivo by an alphavirus replicon particle system, and then it was administered as soluble oligomeric gp140. Concurrently, groups of monkeys received expression vectors that encoded either simian immunodeficiency virus (SIV) gag/pol genes or no SIV genes in vivo to test the additional protective benefit of concurrent induction of virus-specific cell-mediated immune (CMI) responses. Groups of control monkeys received either the gag/pol regimen or sham immunizations. The antibodies induced by the Env immunization regimen neutralized diverse primary HIV-1 strains. Similarly, potent CMI responses were induced by the gag/pol regimen, as measured by gamma interferon enzyme-linked immunospot assays. Differences in the responses among groups of monkeys strongly suggested that there was interference between the Env and gag/pol immunization regimens. Complete protection of some of the monkeys against infection after intravenous challenge with the partially pathogenic SHIV(DH12R (Clone 7)) was associated independently with both neutralizing antibody and CMI responses. Protection was associated with SHIV(DH12 (Clone 7)) serum neutralizing antibody titers of > or =1:80 or with cellular immune responses corresponding to >2,000 spot forming cells per 10(6) peripheral blood mononuclear cells. Immunization was also associated with a reduction in the magnitude and duration of virus load. Induction of cross-reactive, primary HIV-1-neutralizing antibodies is feasible and, when potent, may result in complete protection against infection with a heterologous challenge virus strain.     

Recombinant VP1 protein expressed in Pichia pastoris induces protective immune responses against EV71 in mice

Human enterovirus 71 (EV71) is one of the major causative agents of hand, foot and mouth disease and is also associated with serious neurological diseases in children. Currently, there are no effective antiviral drugs or vaccines against EV71 infection. VP1, one of the major immunogenic capsid proteins of EV71, is widely considered to be the candidate antigen for an EV71 vaccine. In this study, VP1 of EV71 was expressed as a secretory protein with an N-terminal histidine tag in the methylotrophic yeast Pichia pastoris, and purified by Ni–NTA affinity chromatography. Immunogenicity and vaccine efficacy of the recombinant VP1 were assessed in mouse models. The results showed that the recombinant VP1 could efficiently induce anti-VP1 antibodies in BALB/c mice, which were able to neutralize EV71 viruses in an in vitro neutralization assay. Passive protection of neonatal mice further confirmed the prophylactic efficacy of the antisera from VP1 vaccinated mice. Furthermore, VP1 vaccination induced strong lymphoproliferative and Th1 cytokine responses. Taken together, our study demonstrated that the yeast-expressed VP1 protein retained good immunogenicity and was a potent EV71 vaccine candidate.