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Campylobacter jejuni is a leading cause of diarrheal disease worldwide, and currently no preventative interventions are available. C. jejuni is an invasive mucosal pathogen that has a variety of polysaccharide structures on its surface, including a capsule. In phase 1 studies, a C. jejuni capsule conjugate vaccine was safe but poorly immunogenic when delivered alone or with aluminum hydroxide. Here, we report enhanced immunogenicity of the conjugate vaccine delivered with liposome adjuvants containing monophosphoryl lipid A without or with QS-21, known as ALF and ALFQ, respectively, in preclinical studies. Both liposome adjuvants significantly enhanced immunity in mice and nonhuman primates and improved protective efficacy of the vaccine compared to alum in a nonhuman primate C. jejuni diarrhea model, providing promising evidence that these potent adjuvant formulations may enhance immunogenicity in upcoming human studies with this C. jejuni conjugate and other malaria and HIV vaccine platforms. Campylobacter jejuni is among the most common causes of diarrheal disease worldwide and efforts to develop protective measures against the pathogen are ongoing. One of the few defined virulence factors targeted for vaccine development is the capsule polysaccharide (CPS). We have developed a capsule conjugate vaccine against C. jejuni strain 81-176 (CPS-CRM) that is immunogenic in mice and nonhuman primates (NHPs) but only moderately immunogenic in humans when delivered alone or with aluminum hydroxide. To enhance immunogenicity, two novel liposome-based adjuvant systems, the Army Liposome Formulation (ALF), containing synthetic monophosphoryl lipid A, and ALF plus QS-21 (ALFQ), were evaluated with CPS-CRM in this study. In mice, ALF and ALFQ induced similar amounts of CPS-specific IgG that was significantly higher than levels induced by CPS-CRM alone. Qualitative differences in antibody responses were observed where CPS-CRM alone induced Th2-biased IgG1, whereas ALF and ALFQ enhanced Th1-mediated anti-CPS IgG2b and IgG2c and generated functional bactericidal antibody titers. CPS-CRM + ALFQ was superior to vaccine alone or CPS-CRM + ALF in augmenting antigen-specific Th1, Th2, and Th17 cytokine responses and a significantly higher proportion of CD4 + IFN-γ + IL-2 + TNF-α + and CD4 + IL-4 + IL-10 + T cells. ALFQ also significantly enhanced anti-CPS responses in NHPs when delivered with CPS-CRM compared to alum- or ALF-adjuvanted groups and showed the highest protective efficacy against diarrhea following orogastric challenge with C. jejuni . This study provides evidence that the ALF adjuvants may provide enhanced immunogenicity of this and other novel C. jejuni capsule conjugate vaccines in humans. IMPORTANCE Campylobacter jejuni is a leading cause of diarrheal disease worldwide, and currently no preventative interventions are available. C. jejuni is an invasive mucosal pathogen that has a variety of polysaccharide structures on its surface, including a capsule. In phase 1 studies, a C. jejuni capsule conjugate vaccine was safe but poorly immunogenic when delivered alone or with aluminum hydroxide. Here, we report enhanced immunogenicity of the conjugate vaccine delivered with liposome adjuvants containing monophosphoryl lipid A without or with QS-21, known as ALF and ALFQ, respectively, in preclinical studies. Both liposome adjuvants significantly enhanced immunity in mice and nonhuman primates and improved protective efficacy of the vaccine compared to alum in a nonhuman primate C. jejuni diarrhea model, providing promising evidence that these potent adjuvant formulations may enhance immunogenicity in upcoming human studies with this C. jejuni conjugate and other malaria and HIV vaccine platforms.

Enterotoxigenic Escherichia coli (ETEC) are the most common cause of bacterial diarrhea in young children in developing countries and in travelers. Efforts to develop an ETEC vaccine have intensified in the past decade, and intestinal colonization factors (CFs) are somatic components of most investigational vaccines. CFA/I and related Class 5 fimbrial CFs feature a major stalk-forming subunit and a minor, antigenically conserved tip adhesin. We hypothesized that the tip adhesin is critical for stimulating antibodies that specifically inhibit ETEC attachment to the small intestine. To address this, we compared the capacity of donor strand complemented CfaE (dscCfaE), a stabilized form of the CFA/I fimbrial tip adhesin, and CFA/I fimbriae to elicit anti-adhesive antibodies in mice, using hemagglutination inhibition (HAI) as proxy for neutralization of intestinal adhesion. When given with genetically attenuated heat-labile enterotoxin LTR192G as adjuvant by intranasal (IN) or orogastric (OG) vaccination, dscCfaE exceeded CFA/I fimbriae in eliciting serum HAI titers and anti-CfaE antibody titers. Based on these findings, we vaccinated Aotus nancymaae nonhuman primates (NHP) with dscCfaE alone or admixed with one of two adjuvants, LTR192G and cholera toxin B-subunit, by IN and OG administration. Only IN vaccination with dscCfaE with either adjuvant elicited substantial serum HAI titers and IgA and IgG anti-adhesin responses, with the latter detectable a year after vaccination. In conclusion, we have shown that dscCfaE elicits robust HAI and anti-adhesin antibody responses in both mice and NHPs when given with adjuvant by IN vaccination, encouraging further evaluation of an ETEC adhesin-based vaccine approach.

ABSTRACT Campylobacter jejuni is among the most common causes of diarrheal disease worldwide and efforts to develop protective measures against the pathogen are ongoing. One of the few defined virulence factors targeted for vaccine development is the capsule polysaccharide (CPS). We have developed a capsule conjugate vaccine against C. jejuni strain 81-176 (CPS-CRM) that is immunogenic in mice and nonhuman primates (NHPs) but only moderately immunogenic in humans when delivered alone or with aluminum hydroxide. To enhance immunogenicity, two novel liposome-based adjuvant systems, the Army Liposome Formulation (ALF), containing synthetic monophosphoryl lipid A, and ALF plus QS-21 (ALFQ), were evaluated with CPS-CRM in this study. In mice, ALF and ALFQ induced similar amounts of CPS-specific IgG that was significantly higher than levels induced by CPS-CRM alone. Qualitative differences in antibody responses were observed where CPS-CRM alone induced Th2-biased IgG1, whereas ALF and ALFQ enhanced Th1-mediated anti-CPS IgG2b and IgG2c and generated functional bactericidal antibody titers. CPS-CRM + ALFQ was superior to vaccine alone or CPS-CRM + ALF in augmenting antigen-specific Th1, Th2, and Th17 cytokine responses and a significantly higher proportion of CD4+ IFN-γ+ IL-2+ TNF-α+ and CD4+ IL-4+ IL-10+ T cells. ALFQ also significantly enhanced anti-CPS responses in NHPs when delivered with CPS-CRM compared to alum- or ALF-adjuvanted groups and showed the highest protective efficacy against diarrhea following orogastric challenge with C. jejuni. This study provides evidence that the ALF adjuvants may provide enhanced immunogenicity of this and other novel C. jejuni capsule conjugate vaccines in humans. IMPORTANCE Campylobacter jejuni is a leading cause of diarrheal disease worldwide, and currently no preventative interventions are available. C. jejuni is an invasive mucosal pathogen that has a variety of polysaccharide structures on its surface, including a capsule. In phase 1 studies, a C. jejuni capsule conjugate vaccine was safe but poorly immunogenic when delivered alone or with aluminum hydroxide. Here, we report enhanced immunogenicity of the conjugate vaccine delivered with liposome adjuvants containing monophosphoryl lipid A without or with QS-21, known as ALF and ALFQ, respectively, in preclinical studies. Both liposome adjuvants significantly enhanced immunity in mice and nonhuman primates and improved protective efficacy of the vaccine compared to alum in a nonhuman primate C. jejuni diarrhea model, providing promising evidence that these potent adjuvant formulations may enhance immunogenicity in upcoming human studies with this C. jejuni conjugate and other malaria and HIV vaccine platforms.

Palabras-clave: Vida, bioseguridad, ventas, normativas Abstract: This article seeks to publicize the initiatives that are generated in the Peruvian territory as good practices that promote collective actions within the framework of disaster risk management from local social networks, called Encouraging Groups on Disaster Risk Management (GRIDES) that have been incorporating various dynamics and local initiatives in policies and practices at the three levels of government, with proposals and changes in the design and implementation of the actions on disaster risk management within the framework of sustainable development. The objective was to know the participatory processes in the application and generation of policies of public value for disaster risk management in Peru, and to propose based on evidence the new role of GRIDES in the new national system, for which it was developed the documentary review of four GRIDES in different regions. Among the conclusions, GRIDES can be social entities that, based on their inter-institutional articulation, support the best effectiveness and efficiency of prospective, corrective and reactive risk management in development contexts, integrating institutional and community actors in the regions of the Peru. Sin embargo, se ha prestado poca atención a las especificidades de lo que apoya o socava el capital social de las comunidades rurales remotas en los desastres.

The colonization factors (CF) of enterotoxigenic Escherichia coli (ETEC) are being targeted for inclusion in a multi-subunit ETEC vaccine. This study was designed to examine the preclinical safety and immunogenicity of CF CS6, encapsulated in a biodegradable poly( dl-lactide-co-glycolide) (meCS6), and administered in the presence or absence of a mutated heat-labile enterotoxin, LT(R192G), in the non-human primate, Aotus nancymae. A. nancymae were inoculated intranasally (IN) with meCS6 (200 μg; positive control), or intragastrically (IG) with meCS6 (200 or 1000 μg) with or without 2 μg LT(R192G) in three doses given at 2-week intervals. In a second experiment, A. nancymae were inoculated IG with 950 μg of meCS6 with or without 2 μg LT(R192G) in four doses given every 48 h. Blood was collected to assess anti-CS6 and -LT serum immunoglobulin G (IgG) and IgA responses and safety variables (complete blood count and chemistry). Safety parameters were unchanged from baseline following all vaccinations. In Experiment 1, a dose-related serologic response to CS6 was observed; 78.6 and 57.1% of monkeys given 1000 μg meCS6 ( n = 14) had a serum IgG and IgA response, respectively, compared to only 28.6% of monkeys given 200 μg meCS6 ( n = 14) with a serum IgG and IgA response. No significant effect on the number of responders or the magnitude of responses was observed with the addition of LT(R192G). The three-dose, 2-week regimen with 1000 μg meCS6 was more effective at eliciting an immune response than the four-dose, 48-h regimen with 950 μg meCS6. Results from this study indicate that A. nancymae provide a useful ETEC preclinical safety and immunogenicity model.

The colonization factors (CF) of enterotoxigenicEscherichia coli(ETEC) are being targeted for inclusion in a multi-subunit ETEC vaccine. This study was designed to examine the preclinical safety and immunogenicity of CF CS6, encapsulated in a biodegradable poly(dl-lactide-co-glycolide) (meCS6), and administered in the presence or absence of a mutated heat-labile enterotoxin, LT(R192G), in the non-human primate,Aotus nancymae.A. nancymaewere inoculated intranasally (IN) with meCS6 (200μg; positive control), or intragastrically (IG) with meCS6 (200 or 1000μg) with or without 2μg LT(R192G) in three doses given at 2-week intervals. In a second experiment,A. nancymaewere inoculated IG with 950μg of meCS6 with or without 2μg LT(R192G) in four doses given every 48h. Blood was collected to assess anti-CS6 and -LT serum immunoglobulin G (IgG) and IgA responses and safety variables (complete blood count and chemistry). Safety parameters were unchanged from baseline following all vaccinations. In Experiment 1, a dose-related serologic response to CS6 was observed; 78.6 and 57.1% of monkeys given 1000μg meCS6 (n=14) had a serum IgG and IgA response, respectively, compared to only 28.6% of monkeys given 200μg meCS6 (n=14) with a serum IgG and IgA response. No significant effect on the number of responders or the magnitude of responses was observed with the addition of LT(R192G). The three-dose, 2-week regimen with 1000μg meCS6 was more effective at eliciting an immune response than the four-dose, 48-h regimen with 950μg meCS6. Results from this study indicate thatA. nancymaeprovide a useful ETEC preclinical safety and immunogenicity model.

ABSTACT Enterotoxigenic Escherichia coli (ETEC) is a leading cause of diarrhea-associated illness in developing countries. There is currently no vaccine licensed to prevent ETEC and the development of an efficacious prophylaxis would provide an intervention with significant impact. Recent studies suggested that effective protection could be achieved by inducing immunity to block colonization of ETEC. Here, we evaluated the efficacy of secretory (s) IgA2 and dimeric (d) IgA2 of an anti-colonization factor antigen antibody, 68-61, in the Aotus nancymaae non-human primate (NHP) ETEC challenge model via oral and parental delivery. Thirty-nine animals were distributed across 3 groups of 13, and challenged with 5.0×1011 cfu of H10407 on Day 0. Group 1 received a dIgA2 68-61 subcutaneously on day 0. Group 2 received a SIgA2 68-61 orally on days −1, 0, and +1, and Group 3 received an irrelevant SIgA2 antibody orally on days −1, 0, and +1. All animals were observed for symptoms of diarrhea, and stools were collected for ETEC colony counts. SIgA2 treatment significantly lowered the attack rate, resulting in a protective efficacy of 71.4% (p=0.025) in Group 2 as compared to Group 3. Anti-CfaE dIgA2 treatment group reduced the diarrheal attack rate, although the reduction did not reach significance (57.1%; P=0.072) as compared to the irrelevant SIgA2 Group 3. Our results demonstrated the feasibility of oral administration of SIgA as a potential immunoprophylaxis against enteric infections. To our knowledge, this is the first study to demonstrate the efficacy of administrated SIgA in a non-human primate model.

The study of aquatic ecosystems as hydrologic networks requires a metacommunity framework, in which local bacterioplankton communities are interconnected via water movement across the landscape. While evidence suggests that a balance between selection (deterministic) and dispersal (stochastic) processes drives bacterioplankton community composition, little attention has been given to examining the impact of the surrounding terrestrial landscape on these aquatic communities. In this study, we assessed the relative importance of terrestrial landscape composition, local aquatic conditions, and dendritic distance for explaining the variation in aquatic bacterial communities along a small Amazonian hydrological network. Land cover composition had more explanatory power than local aquatic conditions and dendritic distance in explaining bacterial community dissimilarity, particularly in headwaters. Additionally, we observed significant differences in bacterioplankton composition between oxbow lakes and streams, which substantially differed according to local aquatic conditions. These findings underscore the critical role of both local aquatic conditions and terrestrial heterogeneity along the aquatic network in determining bacterioplankton communities. Finally, we identified shifts in the abundance of some bacterial classes associated with terrestrial heterogeneity and aquatic conditions. Our results highlight the crucial role of the terrestrial surrounding landscape as an element that interacts with hydrology and local aquatic conditions in shaping bacterioplankton community structure. Our results contribute to improve our understanding of the processes that drive the dynamics of freshwater bacterioplankton metacommunities and establish clear links between freshwater and surrounding terrestrial environments. These findings advance our knowledge of processes at the land–water interface and may inspire innovative approaches to ecosystem conservation and biomonitoring strategies that include bacterioplankton.