Immunogenicity of Vibrio cholerae outer membrane vesicles secreted at various environmental conditions.

Cholera is caused by toxigenic Vibrio cholerae. It is a significant health problem and an important cause of mortality of children in developing countries. Annually, about 5-7 million people are being infected worldwide, leading to death of 100,000 to 120,000. Immunization using the currently available cholera vaccines has been recommended by World Health Organization (WHO) in areas where cholera is endemic or at risk of outbreaks. Gram-negative bacteria secrete outer membrane vesicles (OMVs) that play important roles in virulence and host-pathogen interaction. The content of protein and lipid in OMVs are affected by purification methods and bacterial growth condition. OMVs released from V. cholerae are an appropriate candidate for vaccine development. The protection conferred by a new vaccine candidate prepared using different methods and in two different growth conditions with nanoparticles in an experimental model of cholera in mice was investigated. OMVs were encapsulated in chitosan-tripolyphosphate (TPP) nanoparticles prepared by an ionic gelation method and coated with Eudragit as an enteric polymer. OMVs loaded into nanoparticles (NP-OMVs) were homogeneous and spherical in shape, with a size of 417nm. BALB/c mice (male, 20-24g) were immunized via intraperitoneal (10µg) or oral route (50µg) with free or encapsulated OMVs. Seventy-eight days after first administration, serum of mice was infected with infection dose of V. cholerae (≥107 CFU). The new vaccine was able to protect fully against infection when it was administered via mucosa. By intraperitoneal route, the unpolymerized OMVs increased the protection against these bacteria.

Achievements and challenges for the use of killed oral cholera vaccines in the global stockpile era.

Cholera remains an important but neglected public health threat, affecting the health of the poorest populations and imposing substantial costs on public health systems. Cholera can be eliminated where access to clean water, sanitation, and satisfactory hygiene practices are sustained, but major improvements in infrastructure continue to be a distant goal. New developments and trends of cholera disease burden, the creation of affordable oral cholera vaccines (OCVs) for use in developing countries, as well as recent evidence of vaccination impact has created an increased demand for cholera vaccines. The global OCV stockpile was established in 2013 and with support from Gavi, has assisted in achieving rapid access to vaccine in emergencies. Recent WHO prequalification of a second affordable OCV supports the stockpile goals of increased availability and distribution to affected populations. It serves as an essential step toward an integrated cholera control and prevention strategy in emergency and endemic settings.

Rapid and scalable plant-based production of a cholera toxin B subunit variant to aid in mass vaccination against cholera outbreaks.

INTRODUCTION: Cholera toxin B subunit (CTB) is a component of an internationally licensed oral cholera vaccine. The protein induces neutralizing antibodies against the holotoxin, the virulence factor responsible for severe diarrhea. A field clinical trial has suggested that the addition of CTB to killed whole-cell bacteria provides superior short-term protection to whole-cell-only vaccines; however, challenges in CTB biomanufacturing (i.e., cost and scale) hamper its implementation to mass vaccination in developing countries. To provide a potential solution to this issue, we developed a rapid, robust, and scalable CTB production system in plants. METHODOLOGY/PRINCIPAL FINDINGS: In a preliminary study of expressing original CTB in transgenic Nicotiana benthamiana, the protein was N-glycosylated with plant-specific glycans. Thus, an aglycosylated CTB variant (pCTB) was created and overexpressed via a plant virus vector. Upon additional transgene engineering for retention in the endoplasmic reticulum and optimization of a secretory signal, the yield of pCTB was dramatically improved, reaching >1 g per kg of fresh leaf material. The protein was efficiently purified by simple two-step chromatography. The GM1-ganglioside binding capacity and conformational stability of pCTB were virtually identical to the bacteria-derived original B subunit, as demonstrated in competitive enzyme-linked immunosorbent assay, surface plasmon resonance, and fluorescence-based thermal shift assay. Mammalian cell surface-binding was corroborated by immunofluorescence and flow cytometry. pCTB exhibited strong oral immunogenicity in mice, inducing significant levels of CTB-specific intestinal antibodies that persisted over 6 months. Moreover, these antibodies effectively neutralized the cholera holotoxin in vitro. CONCLUSIONS/SIGNIFICANCE: Taken together, these results demonstrated that pCTB has robust producibility in Nicotiana plants and retains most, if not all, of major biological activities of the original protein. This rapid and easily scalable system may enable the implementation of pCTB to mass vaccination against outbreaks, thereby providing better protection of high-risk populations in developing countries.

[Selection of attenuated Vibrio cholerae strains to obtain oral attenuated candidate vaccines against cholera]. / Selección de cepas atenuadas de Vibrio cholerae para la obtención de candidatos vacunales atenuados orales contra el cólera.

A methodology was developed for the selection of genetically modified strains of Vibrio cholerae 01 and 0139 aimed at obtaining oral attenuated candidate vaccines against cholera. The modified strains underwent microbiological characterization, bacterial susceptibility and different biological tests (mean lethal dose, colonizing capacity, adherence in mice, ligated intestine and intraduodenal inoculation in rabbits as virulence and potency tests. The strains 81, 638, 638T and 1333 were evaluated in clinical trials to determine their reactogenicity and immunogenicity. All the strains were sensitive to tetracycline and doxoclycine. They showed their attenuation and immunogenicity in animal models. The strains 638 and 1333 proved to be immunogenic and non reactogenic in volunteers.

Construction and evaluation of a safe, live, oral Vibrio cholerae vaccine candidate, IEM108.

IEM101, a Vibrio cholerae O1 El Tor Ogawa strain naturally deficient in CTXPhi, was previously selected as a live cholera vaccine candidate. To make a better and safer vaccine that can induce protective immunity against both the bacteria and cholera toxin (CT), a new vaccine candidate, IEM108, was constructed by introducing a ctxB gene and an El Tor-derived rstR gene into IEM101. The ctxB gene codes for the protective antigen CTB subunit, and the rstR gene mediates phage immunity. The stable expression of the two genes was managed by a chromosome-plasmid lethal balanced system based on the housekeeping gene thyA. Immunization studies indicate that IEM108 generates good immune responses against both the bacteria and CT. After a single-dose intraintestinal vaccination with 10(9) CFU of IEM108, both anti-CTB immunoglobulin G and vibriocidal antibodies were detected in the immunized-rabbit sera. However, only vibriocidal antibodies are detected in rabbits immunized with IEM101. In addition, IEM108 but not IEM101 conferred full protection against the challenges of four wild-type toxigenic strains of V. cholerae O1 and 4 micro g of CT protein in a rabbit model. By introducing the rstR gene, the frequency of conjugative transfer of a recombinant El Tor-derived RS2 suicidal plasmid to IEM108 was decreased 100-fold compared to that for IEM101. This indicated that the El Tor-derived rstR cloned in IEM108 was fully functional and could effectively inhibit the El Tor-derived CTXPhi from infecting IEM108. Our results demonstrate that IEM108 is an efficient and safe live oral cholera vaccine candidate that induces antibacterial and antitoxic immunity and CTXPhi phage immunity.

Preparation and preclinical evaluation of experimental group B streptococcus type III polysaccharide-cholera toxin B subunit conjugate vaccine for intranasal immunization.

Streptococcus group B (GBS) is usually carried asymptomatically in the vaginal tract of women and can be transferred to the newborn during parturition. Serum antibodies to the capsular polysaccharide (CPS) can prevent invasive diseases, whereas immunity acting at the mucosal surface may be more important to inhibit the mucosal colonization of GBS and thus the risk of infection for the newborn. We prepared different GBS type III CPS-protein conjugate vaccines and evaluated their systemic and mucosal immunogenicity in mice. GBS type III CPS was conjugated to tetanus toxoid (TT) or recombinant cholera toxin B subunit (rCTB) either directly or to rCTB indirectly via TT. The conjugation was performed by different methods: (1) CPS was coupled to TT with 1-ethyl-3 (3-dimethylaminopropyl)-carbodiimide (EDAC), using adipic acid dihydrazide (ADH) as a spacer; (2) CPS was conjugated with rCTB using reductive amination; or, (3) N-succinimidyl 3-(2-pyridyldithio) propionate (SPDP) was used to bind rCTB to the TT of the CPS-TT conjugate. Mice were immunized with these conjugates or purified CPS by subcutaneous (s.c.) and intranasal (i. n.) routes. Antibodies to GBS III in serum, lungs and vagina were measured with ELISA. All of the CPS-protein conjugates were superior to unconjugated CPS in eliciting CPS-specific immune responses in serum and mucosal tissue extracts. The conjugates, when administrated s.c., induced only IgG responses in serum, lung and vagina, while i.n. vaccination also elicited IgA responses in the lungs and vagina. The CPS-TT conjugate administrated i.n. induced a strong serum IgG, but only a weak mucosal IgA response, while the CPS-rCTB conjugate elicited high IgG as well as IgA antibodies in the lungs after i.n. immunization. GBS III CPS-TT conjugated with rCTB produced a strong systemic and local anti-CPSIII response after i.n. administration. Co-administration of CT as adjuvant enhanced the anti-CPS systemic and mucosal immune responses further after i.n. administration with the CPS conjugates. These findings indicate that: (i) i.n. immunization with GBS CPS-protein conjugates was more effective than s.c immunization for stimulating serum as well as mucosal immune responses; (ii) rCTB as a carrier protein for GBS III CPS could markedly improve the mucosal immune response; and (iii) the experimental GBS type III CPS conjugates containing rCTB should be investigated as mucosal vaccine to prevent GBS infection in humans.

Pathogenic and vaccine significance of toxin-coregulated pili of Vibrio cholerae E1 Tor.

Vibrio cholerae O1 strains are classified into one of two biotypes, classical and E1 Tor, the latter being primarily responsible for cholera cases worldwide since 1961. Recent studies in our laboratory have focused upon the pathogenic and vaccine significance of the toxin-coregulated pili (TCP) produced by strains of E1 Tor biotype. Mutants in which the tcpA gene (encoding the pilin subunit protein) has been inactivated are dramatically attenuated in the infant mouse cholera model, showing markedly reduced colonisation potential in mixed-infection competition experiments. Significantly, in the vaccine context, antibodies to TCP are sufficient to prevent experimental infection, although our data suggest that this protective effect might be limited to strains of homologous biotype. Since we have shown that tcpA sequences are conserved within a biotype but differ between biotypes, this latter observation suggests that the biotype-restricted pilin epitopes might have greater vaccine significance. Similar studies indicate that TCP also play a critical role in colonisation by strains of the recently-recognised O139 serogroup, which is thought to have evolved from an O1 E1 Tor strain. In contrast to the effect of introducing mutations in the tcpA gene, strains carrying inactivated mshA genes (encoding the subunit of the mannose-sensitive haemagglutinin pilus) show unaltered in vivo behaviour. Consistent with this finding is our inability to demonstrate any protective effect associated with antibodies to MSHA. Ongoing approaches to vaccine development are variously aimed at improving the immunogenicity of the current inactivated whole-cell vaccine, or assessing the field efficacy of a promising live attenuated strain. The possible implications of our findings are discussed in relation to both of these options.

Vibrio cholerae CVD103-HgR live oral attenuated vaccine: construction, safety, immunogenicity, excretion and non-target effects.

In many controlled studies, CVD103-HgR has been shown to be safe and immunogenic and to offer a significant degree of protection against experimental cholera after a single dose. Its minimal excretion and limited ability to compete and survive in various ecosystems indicate that this strain presents little risk to the environment. Furthermore, the potential of CVD103-HgR to regain virulence by acquisition of the CT A or LT A gene is extremely remote even under optimal conditions. Therefore, CVD103-HgR possesses those traits desired in a live oral attenuated vaccine produced by recombinant DNA technology.

Why do we not yet have a suitable vaccine against cholera?

The available options, past and present, of cholera vaccines have been summarized above. It is saddening but clear that, more than a century after the introduction of the first cholera vaccine, we still do not have available a suitable vaccine against cholera. The currently raging and expanding new epidemic of cholera in the Western hemisphere dramatically illustrates anew the need, although a new illustration is not necessary if one but considers the innumerable, but unnecessary, victims of cholera of the past which could have been prevented had a suitable vaccine been available earlier. Indeed, it should also be clear from this review that a suitable vaccine against cholera still eludes us and will for an additional period of time. Cholera, a disease of humans only, can be controlled by prevention of human to human transmission, i.e., by universal availability of appropriate sewage disposal and clean water--an expensive solution, but one which will also reduce the toll of the other diseases transmitted by the fecal-oral route. Short of this, we should not be diverted by less than a highly effective, and economical vaccine. The "bottleneck" resides in the difficulty of getting from the laboratory to the field: the essential, and most efficient, intermediate step being the testing of candidate vaccines in volunteers--laboratory animal models do not suffice. Cholera is now, especially under controlled conditions, a perfectly treatable disease. Additional volunteer centers, and studies in volunteers, are essential to the solution of the cholera problem in the near future.(ABSTRACT TRUNCATED AT 250 WORDS)

Production of Vibrio cholerae ghosts (VCG) by expression of a cloned phage lysis gene: potential for vaccine development.

The protein E-specific lysis mechanism of the Escherichia coli-specific bacteriophage PhiX174 was employed to produce Vibrio cholerae ghosts (VCG). VCG consist of both rounded and collapsed cells that have lost their cytoplasmic contents through an E-specific hole in the cell envelope. These ghosts are proposed as non-living material for immunization against cholera. A specific membrane anchor sequence was used to insert the human immunodeficiency virus type 1 (HIV-1) reverse transcriptase (RT) fusion protein into the cell envelope of V. cholerae. The identity of the expression products was confirmed by Western blot analysis employing an RT-specific monoclonal antibody. HIV-1 RT was chosen as a model for the purpose of evaluating heterologous gene expression in V. cholerae and the carrier potential of VCG. Intraperitoneal immunization of mice was used to evaluate the immunogenic potential of VCG. Preliminary results showed significant seroconversions to intact whole-cell vibrio antigens in mice immunized with VCG or a heat-killed whole-cell vibrio preparation.

Identification of the flagellar antigens of Vibrio cholerae El Tor and their role in protection.

Antiserum to the surface antigens of the wild-type flagellate strain KB207 of Vibrio cholerae El Tor was absorbed with isogenic aflagellate mutant CD12. Antibodies remaining in the absorbed serum exhibited specificity to KB207 but not to CD12 and inhibited motility of KB207. Proteins from cell-free lysates of KB207 and CD12 were analysed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. CD12 differed from KB207 in the absence of two proteins of 40 and 38 kDa. These proteins were detected in KB207 when electrophoretically separated proteins were immunoblotted with unabsorbed and absorbed sera. These two proteins were isolated by immunoaffinity chromatography using purified antibodies from absorbed serum. Although antigenic, the 40 and 38 kDa proteins did not induce protection against cholera in the rabbit ileal loop model.

Identification of a 33 kDa antigen associated with an adhesive and colonizing strain of Vibrio cholerae El Tor and its role in protection.

Proteins from the cell-free lysates of the wild-type strain KB207 of Vibrio cholerae El Tor and the isogenic non-adhesive mutant CD11 were analysed by native and denaturing polyacrylamide gel electrophoresis. A protein of 33 kDa present in KB207 was absent from CD11. Antiserum to the surface antigens of KB207 was absorbed with CD11. Antibodies remaining in the serum after absorption reacted to KB207 but not to CD11 as judged by slide agglutination, double gel diffusion and dot blot ELISA. Antibodies in the absorbed serum inhibited adherence of KB207 to rabbit intestinal mucosa and colonization in an infant mice model. The 33 kDa protein was isolated from KB207 by immunoaffinity chromatography. Antibodies present in the absorbed serum were used as ligand. The 33 kDa antigen was immunogenic and conferred protection in the rabbit ileal loop model. Combined administration of 33 kDa protein and B-subunit of cholera toxin offered full protection.

Pili of vibrio cholerae widely distributed in serogroup O1 strains.

The distribution of Vibrio cholerae O1 pili consisting of 16 kDa subunit protein (16K-pili) was examined by Western blotting, using 211 strains from various origins and specific anti-16K-pili sera. The 16 kDa protein was detected in all 211 strains. The pili were purified from 3 El Tor and 3 classical strains, and characterized by hemagglutination and inhibition tests. All purified pili were hemagglutinative. However, the hemagglutinating activity of classical pili disappeared after exposure to 5 M urea and the agglutination induced by the classical pili was inhibited by D-mannose, alpha-methylmannoside, D-glucose and N-acetylglucosamine. On the contrary, El Tor pili were resistant to these sugars and urea.

Vacunas contra el cólera / Vaccines against cholera

El cólera es una enfermedad aguda e infecciosa que fue descrita antes de la época de Hipócrates en el siglo V AC. Se describieron varias epidemias de esta enfermedad en Asia entre los siglos XV y XVIII. A mediados del siglo XIX John Snow en Inglaterra fue el primero en describir las medidas de prevención de la enfermedad a raíz de una epidemia ocurrida en Londres. En 1883, Robert Koch realizó el descubrimiento del agente causal, Vibrio cholerae, un bacilo curvo de gran movilidad. Durante los siglos XIX y XX han ocurrido siete pandemias de cólera; en la actualidad ocurre la transmisión de la séptima. El cólera es una de las causas más importantes de morbilidad y mortalidad de algunos países de Asia y Africa y desde 1991 también en Latinoamérica. Desde principios del siglo se ha empleado una vacuna parenteral elaborada con una cepa de V. cholerae 01, inactivada con calor, la cual únicamente induce 50 por ciento de protección en jóvenes y adultos, durante un período de aproximadamente 6 meses. El empleo de adyuvantes no ha tenido influencia en su eficiencia, sino por el contrario incrementa las reacciones colaterales. Las perspectivas para el desarrollo de una vacuna eficaz contra el cólera se basan en el hecho de que más del 90 por ciento de los sujetos infectados en forma natural quedan protegidos para una segunda reinfección. El avance del desarrollo de las vacunas del cólera se ha podido efectuar gracias a un mejor conocimiento de los mecanismos de patogenicidad y antigenicidad del agente etiológico, aunque persisten incógnitas importantes. La vacuna ideal contra el cólera debería ser tan eficaz como la infección natural, sin riesgo de causar enfermedad infecciosa, de fácil administración, de bajo costo, de una sola dosis, inocua, que proteja contra la infección y obviamente contra la enfermedad grave, con protección de larga duración y probablemente de administración oral

[An oral chemical vaccine from the hypertoxigenic strains of the causative agent of cholera KM-76 Inaba and KM-68 Ogawa]. / Oral'naia khimicheskaia vaktsina iz gipertoksigennykh shtammov KM-76 Inaba i KM-68 Ogava vozbuditel'a kholery.

The material on the development of chemical vaccine, prepared from two newly formed strains (KM-76 Inaba and KM-68 Ogawa) and intended for oral administration, is presented. The conditions for the submerged cultivation of these strains have been established, which makes it possible to increase the production of choleragen 8- to 10-fold and O-antigen 3- to 4-fold in comparison with V. cholerae natural strain 569B. The maximum accumulation of neuraminidase, protease, phospholipase, along with choleragen, has been registered in the logarithmic phase and that of O-antigen, in the stationary phase of growth. The use of strains KM-76 and KM-68 has led to the fourfold increase of the specific activity of the main immunogens, thus permitting the respective increase of the yield of the oral vaccine without changes in its high capacity for the formation of specific antibodies and its low residual toxigenicity.

Immunogenicity of two formulations of oral cholera vaccines in Thai volunteers.

A formulation of oral vaccine consisting of Vibrio cholerae lipopolysaccharides (LPS), cell-bound haemagglutinin (CHA) and procholeragenoid (P), namely vaccine A, was compared with another formulation, vaccine B, prepared from killed whole vibrios plus procholeragenoid on their immunogenicity and reactogenicity in Thai male volunteers. Volunteers were randomly allocated into three groups. The first two groups received orally three doses of vaccines A and B, respectively at 14-day intervals. Volunteers in group 3 were controls and received orally 100 ml 5% (w/v) NaHCO3 also at 14-day intervals. Serum samples were collected from all volunteers before each immunization. Intestinal lavage was performed 3 to 7 days before the first dose of vaccine or placebo and 7, 21 and 45 days after the last dose. Serum vibriocidal antibodies were determined and class-specific, antigen-specific antibodies of all serum and lavage samples were assessed by indirect enzyme-linked immunosorbent assay (ELISA) using purified LPS, CHA and cholera toxin (CT) as antigens. Diarrhoea occurred in 10 and 40% of the vaccinees ingesting the vaccines A and B, respectively. The immunogenicity of the vaccine B in terms of seroconversion for vibriocidal antibodies and anti-LPS was higher than the vaccine A. Both vaccines had equal immunogenicity concerning serum anti-CT, while the vaccine A was slightly better than the vaccine B on serum anti-CHA response. The immunogenicity of the two vaccines in evoking intestinal responses was different from the systemic one.(ABSTRACT TRUNCATED AT 250 WORDS)

Research priorities for diarrhoeal disease vaccines: memorandum from a WHO meeting.

Diarrhoeas caused by rotaviruses, Shigella, Vibrio cholerae, and enterotoxigenic Escherichia coli (ETEC) represent a major health burden in developing countries, and have stimulated much effort towards vaccine development in order to protect against these four disease agents. This Memorandum describes the state of the art and points the way to future research and test trials in this area.

PIP: WHO's Programme for Control of Diarrheal Diseases (CDD) promoted and supported research the purpose of which is to develop and evaluate vaccines against diarrheal diseases, but it focused on diarrhea control. In 1991, the WHO/UNDP Programme for Vaccine Development (PVD) began coordinating diarrheal disease vaccine research, yet CDD remained actively involved in vaccine trials. In March 1991, CDD and PVD cosponsored a meeting to specify new research priorities toward vaccines against rotaviruses, Shigella, cholera, and enterotoxigenic Escherichia coli (ETEC) infections. Synopses of clinical trials on vaccines that have undergone clinical trials are presented. Different methods of developing vaccines against rotavirus included heterologous rotavirus adapted to tissue cultures, incorporating the VP7 surface protein of human rotaviruses into an animal rotavirus, and naturally attenuated. Live oral vaccines, different ways to immunize with oral encapsulated antigens, and a gycoconjugate approach comprised the Shigella vaccine research. There were many candidate Shigella vaccines which the meeting participants found to be promising and challenging. Cholera vaccines included killed and live oral vaccines. The results of a large field trial of cholera vaccines (killed whole cell/B subunit and whole cell culture) in Bangladesh revealed marked improvements over injected vaccines. A study of children in Indonesia showed promise for strain CVD-103HgR as a 1 dose, live oral vaccine against cholera. Adult volunteers who received milk immunoglobulin concentrate with antibodies against several colonization factor fimbriae (LT and O antigens) and then challenged experimentally with ETEC were 100% protected. WHO emphasized the need to develop both living and nonliving oral ETEC vaccines which will grant broad spectrum immunity to young children. Specific recommendations follow each section on the various vaccines and general recommendations are included.

Recombinant attenuated Vibrio cholerae strains used as live oral vaccines.

Although great strides have been made in the development of recombinant attenuated Vibrio cholerae vaccine strains, the task has not been as simple as once imagined. The initial vaccine candidates proved to be unexpectedly reactogenic but further derivatives, such as CVD103-HgR, are well-tolerated, immunogenic and protective after a single dose. In addition, this strain carries a selectable marker to distinguish it from wild strains and has been evaluated in a practical, lyophilized formulation (Levine et al., 1988b). While CVD103-HgR is being further evaluated in expanded trials, we are also investigating a new secretogenic factor which could possibly explain the diarrhoea seen with the earlier vaccine strains. Hopefully, these studies will achieve the long-sought goal of a safe and effective vaccine for the prevention of cholera.