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5. Mucosal Heterologous Prime/Boost Vaccination Induces Polyfunctional Systemic Immunity, Improving Protection Against

Author

Sanchez Alberti, Andrés, Bivona, Augusto E, Matos, Marina N, Cerny, Natacha, Schulze, Kai, Weißmann, Sebastian, Ebensen, Thomas, González, Germán, Morales, Celina, Cardoso, Alejandro C, Cazorla, Silvia I, Guzmán, Carlos A, Malchiodi, Emilio L, and HZI, Helmholtz Zentrum für Infektionsforschung GmbH, Inhoffenstr.7, 38124 Braunschweig, Germany.

Subjects
Chagas disease, neglected tropical disease, T cell polyfunctionality, Traspain, cell-mediated immunity, cyclic-di-AMP, prime-boost vaccine, Anti-Trypanosoma cruzi vaccine
Abstract

There are several unmet needs in modern immunology. Among them, vaccines against parasitic diseases and chronic infections lead. Trypanosoma cruzi, the causative agent of Chagas disease, is an excellent example of a silent parasitic invasion that affects millions of people worldwide due to its progression into the symptomatic chronic phase of infection. In search for novel vaccine candidates, we have previously introduced Traspain, an engineered trivalent immunogen that was designed to address some of the known mechanisms of T. cruzi immune evasion. Here, we analyzed its performance in different DNA prime/protein boost protocols and characterized the systemic immune response associated with diverse levels of protection. Formulations that include a STING agonist, like c-di-AMP in the boost doses, were able to prime a Th1/Th17 immune response. Moreover, comparison between them showed that vaccines that were able to prime polyfunctional cell-mediated immunity at the CD4 and CD8 compartment enhanced protection levels in the murine model. These findings contribute to a better knowledge of the desired vaccine-elicited immunity against T. cruzi and promote the definition of a vaccine correlate of protection against the infection.

Published
2020

6. Mucosal Heterologous Prime/Boost Vaccination Induces Polyfunctional Systemic Immunity, Improving Protection Against Trypanosoma cruzi.

Author

Sanchez Alberti, Andrés, Bivona, Augusto E., Matos, Marina N., Cerny, Natacha, Schulze, Kai, Weißmann, Sebastian, Ebensen, Thomas, González, Germán, Morales, Celina, Cardoso, Alejandro C., Cazorla, Silvia I., Guzmán, Carlos A., and Malchiodi, Emilio L.

Subjects
TRYPANOSOMA cruzi, CELLULAR immunity, CHAGAS' disease, VACCINATION, PARASITIC diseases
Abstract

There are several unmet needs in modern immunology. Among them, vaccines against parasitic diseases and chronic infections lead. Trypanosoma cruzi , the causative agent of Chagas disease, is an excellent example of a silent parasitic invasion that affects millions of people worldwide due to its progression into the symptomatic chronic phase of infection. In search for novel vaccine candidates, we have previously introduced Traspain, an engineered trivalent immunogen that was designed to address some of the known mechanisms of T. cruzi immune evasion. Here, we analyzed its performance in different DNA prime/protein boost protocols and characterized the systemic immune response associated with diverse levels of protection. Formulations that include a STING agonist, like c-di-AMP in the boost doses, were able to prime a Th1/Th17 immune response. Moreover, comparison between them showed that vaccines that were able to prime polyfunctional cell-mediated immunity at the CD4 and CD8 compartment enhanced protection levels in the murine model. These findings contribute to a better knowledge of the desired vaccine-elicited immunity against T. cruzi and promote the definition of a vaccine correlate of protection against the infection. [ABSTRACT FROM AUTHOR]

Published
2020
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7. Tailoring T helper 17 induction following vaccination by antigen dosage and adjuvant usage

Author

Weißmann, Sebastian and Dersch, Petra

Subjects
ddc:57, doctoral thesis, chemical and pharmacologic phenomena, ddc:579, ddc:5
Abstract

The adaptive immune system is orchestrated by T helper (Th) cells. In addition to Th1 and Th2 cells, a third subset named Th17 was discovered lately. The knowledge of Th17 cells and their induction is fragmentary. For each specific pathogen, the appropriate Th response is needed for optimal protection. Therefore, it is essential to elucidate how a particular Th cell type is induced (e.g. after vaccination). Previous studies suggest that antigen (Ag) dose plays an important role in Th1/Th2 polarization. In this work, Ag dose dependent Th17 induction was studied in vitro and in vivo using mouse models. In vitro proliferation assays revealed striking differences in Th17 induction between DO11.10 and OTII mice. Differences in TCR affinity to the Ag was identified as one reason for the observed phenomenon. Immunizations of wild type mice led to Th17 induction at low Ag doses. Recent studies provided evidence that Th17 cells are important in fighting influenza infections. In the work reported here, mice immunized with low H5N1 virosome dosage were fully protected against lethal challenge with the H5N1influenza virus. Since Th17 immune responses are not always beneficial for the host, the second part of this thesis focused on the specific blocking of Th17 induction by a PEGylated derivate of alpha-galactosylceramide (aGCPEG). In vitro and in vivo experiments demonstrated that natural killer T (NKT) cells released high amounts of interleukin 4 and interferon gamma post aGCPEG stimulation and subsequently blocked the induction of Th 17 cells. Taken together the results of this thesis contribute to a better understanding of Th17 biology. Knowledge about Th polarization is a key for the development of tailored immune responses following vaccinations. It is expected that the tools and strategies established during this work will facilitate the development of vaccines able to stimulate tailored Th17 responses to promote optimal protection against infection., Das adaptive Immunsystem wird von T-Helferzellen (Th-Zellen) gesteuert. Neben Th1- und Th2-Zellen wurden kürzlich Th17-Zellen entdeckt. Das Wissen über die Induktion von Th17-Zellen ist sehr begrenzt. Für jedes Pathogen muss für einen wirkungsvollen Immunschutz der passende Th-Phänotyp induziert werden. Daher ist es wichtig zu wissen, wie ein spezifischer Th-Zelltyp induziert wird. Andere Studien zeigen einen wichtigen Einfluss der Antigendosis (Ag-Dosis) auf die Th1/Th2 Polarisierung. In der vorliegenden Arbeit wurde die Ag-Dosis-abhängige Th17 Induktion in vitro und in vivo im Mausmodel untersucht. In vitro Proliferationsversuche zeigten deutlich unterschiedliche Th17-Polarisierung zwischen DO11.10 und OTII Mäusen. Als eine Ursache für dieses Phänomen wurden unterschiedliche TCR-Affinitäten zum Ag identifiziert. Immunisierungen von Wildtyp-Mäusen führten zu einer Th17-Induktion bei niedrigen Ag-Dosen. Neueste Studien weisen auf die wichtige Rolle von Th17-Zellen bei Influenzainfektionen hin. In der hier vorliegenden Arbeit wiesen Mäuse, die mit niedrigen H5N1-Virosomen-Dosen vakziniert wurden, einen vollständigen Impfschutz gegen eine tödliche Dosis H5N1-Influenza Virus auf. Da Th17 Immunantworten nicht immer von Vorteil sind, befasste sich der zweite Teil der Arbeit mit der spezifischen Blockierung der Th17 Induktion durch ein PEGyliertes Derivat von alpha-Galactosylceramid (aGCPEG). In vitro und in vivo Versuche zeigten, dass NKT-Zellen nach der Stimulierung mit aGCPEG große Mengen IL-4 und IFNg freisetzten, wodurch die Induktion von Th17-Zellen unterdrückt wurde. Die Ergebnisse dieser Arbeit tragen zu einem besseren Verständnis der Th17-Biologie bei. Fundiertes Wissen über die Th-Polarisierung spielt eine Schlüsselrolle in der Entwicklung von wirkungsvollen Impfstoffen. Die hier gewonnenen Erkenntnisse können zukünftig zu der Entwicklung von Vakzinen mit maßgeschneiderten Th17-Antworten beitragen und so einen optimalen Impfschutz gewährleisten.

Published
2012

8. Mucosal Administration of Cycle-Di-Nucleotide-Adjuvanted Virosomes Efficiently Induces Protection against Influenza H5N1 in Mice.

Author

Ebensen, Thomas, Debarry, Jennifer, Pedersen, Gabriel K., Blazejewska, Paulina, Weissmann, Sebastian, Schulze, Kai, McCullough, Kenneth C., Cox, Rebecca J., and Guzmán, Carlos A.

Subjects
H5N1 Influenza, IMMUNE response, VACCINE effectiveness, VACCINATION
Abstract

The need for more effective influenza vaccines is highlighted by the emergence of novel influenza strains, which can lead to new pandemics. There is a growing population of susceptible subjects at risk for severe complications of influenza, such as the elderly who are only in part protected by current licensed seasonal vaccines. One strategy for improving seasonal and pandemic vaccines takes advantage of adjuvants to boost and modulate evoked immune responses. In this study, we examined the capacity of the recently described adjuvant cyclic di-adenosine monophosphate (c-di-AMP) to serve as an adjuvant for improved mucosal influenza vaccines, and induce effective protection against influenza H5N1. In detail, c-di-AMP promoted (i) effective local and systemic humoral immune responses, including protective hemagglutination inhibition titers, (ii) effective cellular responses, including multifunctional T cell activity, (iii) induction of long-lasting immunity, and (iv) protection against viral challenge. Furthermore, we demonstrated the dose-sparing capacity of the adjuvant as well as the ability to evoke cross-clade protective immune responses. Overall, our results suggest that c-di-AMP contributes to the generation of a protective cell-mediated immune response required for efficacious vaccination against influenza, which supports the further development of c-di-AMP as an adjuvant for seasonal and pandemic influenza mucosal vaccines. [ABSTRACT FROM AUTHOR]

Published
2017
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9. NKT Cell Stimulation with α-Galactosylceramide Results in a Block of Th17 Differentiation after Intranasal Immunization in Mice.

Author

Zygmunt, Beata M., Weissmann, Sebastian F., and Guzman, Carlos A.

Subjects
*IMMUNE response, *IMMUNOLOGY, *CELLULAR immunity, *IMMUNOLOGICAL adjuvants, *CELLS
Abstract

In a previous study we demonstrated that intranasal (i.n.) vaccination promotes a Th17 biased immune response. Here, we show that co-administration of a pegylated derivative of a-galactosylceramide (aGCPEG) with an antigen, even in the presence of Th17-polarizing compounds, results in a strong blocking of Th17 differentiation. Additional studies demonstrated that this phenomenon is specifically dependent on soluble factors, like IL-4 and IFNc, which are produced by NKT cells. Even NK1.1 negative NKT cells, which by themselves produce IL-17A, are able to block Th17 differentiation. It follows that the use of aGCPEG as adjuvant would enable to tailor Th17 responses, according to the specific clinical needs. This knowledge expands our understanding of the role played by NKT cells in overall control of the cytokine microenvironment, as well as in the overall shaping of adaptive immune responses. [ABSTRACT FROM AUTHOR]

Published
2012
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10. Cyclic Di-Adenosine Monophosphate: A Promising Adjuvant Candidate for the Development of Neonatal Vaccines.

Author

Lirussi, Darío, Weissmann, Sebastian Felix, Ebensen, Thomas, Nitsche-Gloy, Ursula, Franz, Heiko B. G., Guzmán, Carlos A., and Saleem, Imran

Subjects
*VACCINE development, *CELLULAR immunity, *CORD blood, *HUMORAL immunity, *H1N1 influenza
Abstract

Underdeveloped immunity during the neonatal age makes this period one of the most dangerous during the human lifespan, with infection-related mortality being one of the highest of all age groups. It is also discussed that vaccination during this time window may result in tolerance rather than in productive immunity, thus raising concerns about the overall vaccine-mediated protective efficacy. Cyclic di-nucleotides (CDN) are bacterial second messengers that are rapidly sensed by the immune system as a danger signal, allowing the utilization of these molecules as potent activators of the immune response. We have previously shown that cyclic di-adenosine monophosphate (CDA) is a potent and versatile adjuvant capable of promoting humoral and cellular immunity. We characterize here the cytokine profiles elicited by CDA in neonatal cord blood in comparison with other promising neonatal adjuvants, such as the imidazoquinoline resiquimod (R848), which is a synthetic dual TLR7 and TLR8 agonist. We observed superior activity of CDA in eliciting T helper 1 (Th1) and T follicular helper (TfH) cytokines in cells from human cord blood when compared to R848. Additional in vivo studies in mice showed that neonatal priming in a three-dose vaccination schedule is beneficial when CDA is used as a vaccine adjuvant. Humoral antibody titers were significantly higher in mice that received a neonatal prime as compared to those that did not. This effect was absent when using other adjuvants that were reported as suitable for neonatal vaccination. The biological significance of this immune response was assessed by a challenge with a genetically modified influenza H1N1 PR8 virus. The obtained results confirmed that CDA performed better than any other adjuvant tested. Altogether, our results suggest that CDA is a potent adjuvant in vitro on human cord blood, and in vivo in newborn mice, and thus a suitable candidate for the development of neonatal vaccines. [ABSTRACT FROM AUTHOR]

Published
2021
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11. Non-invasive delivery of nanoparticles to hair follicles: A perspective for transcutaneous immunization.

Author

Mittal, Ankit, Raber, Anne S., Schaefer, Ulrich F., Weissmann, Sebastian, Ebensen, Thomas, Schulze, Kai, Guzmán, Carlos A., Lehr, Claus-Michael, and Hansen, Steffi

Subjects
*NANOMEDICINE, *HAIR follicles, *IMMUNIZATION, *VACCINATION, *ANTIGEN presenting cells, *IMMUNE response, *OVALBUMINS, *POLYVINYL alcohol
Abstract

Transfollicular vaccination aims to reach the peri-follicular antigen presenting cells without impairing the stratum corneum (SC) barrier. This would be an optimal vaccination strategy under critical hygienic conditions. Nanoparticles (NPs) are the ideal vehicles for transfollicular delivery of vaccines as they are able to (i) penetrate deeper into the hair follicles than molecules in solution, (ii) can help to stabilize protein based antigen and (iii) improve and modulate the immune response. This study investigates the potential of transfollicular delivery of polymeric NPs using ovalbumin (OVA) as a model antigen. NPs were prepared by a double emulsion method from pharmaceutically well characterized biocompatible and biodegradable polymers poly(lactide-co-glycolide) (PLGA) or chitosan-coated PLGA (Chit-PLGA) using polyvinyl alcohol as stabilizer. The NP formulations are available as freeze dried product which can be re-constituted with water or cell culture medium before use to yield any desired OVA/NP concentration. OVA was protected from cleavage or aggregation inside the NPs and retained its biological activity to 74% (PLGA) and 64% (Chit-PLGA). Thus, when applying a typical dose of 8.5μl/cm2 NP formulation (50mg NPs/ml, 54.3±0.047 and 66.5±0.044μg OVA/mg NPs for PLGA and Chit-PLGA NPs, respectively) an effective dose of 17μg/cm2 (PLGA) or 18μg/cm2 (Chit-PLGA) of active OVA is administered. In a cell culture assay encapsulated OVA stimulated the proliferation of CD4+ (PLGA and Chit-PLGA) and CD8+ T-cells (only Chit-PLGA) to a larger extent than OVA in solution. An adoptive transfer experiment demonstrated that the model antigen OVA can be delivered via the transfollicular route. This preliminary experiment is a proof of concept that by this transfollicular immunization approach it is possible to deliver antigens, thereby stimulating antigen-specific T cells. Both NP formulations improved the delivery efficiency of OVA into the hair follicles on excised pig ears by a factor of 2–3 compared to OVA solution. This delivery efficiency could further be increased by increasing the number of NPs applied per skin area by a factor of ≈2–2.4. Consequently formulation of OVA into PLGA and Chit-PLGA NPs may offer to reduce the dose which needs to be applied for transfollicular immunization. [ABSTRACT FROM AUTHOR]

Published
2013
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12. Gene Expression Driven by a Strong Viral Promoter in MVA Increases Vaccination Efficiency by Enhancing Antibody Responses and Unmasking CD8⁺ T Cell Epitopes.

Author

Becker PD, Nörder M, Weissmann S, Ljapoci R, Erfle V, Drexler I, and Guzmán CA

Abstract

Viral vectors are promising tools for vaccination strategies and immunotherapies. However, CD8⁺ T cell responses against pathogen-derived epitopes are usually limited to dominant epitopes and antibody responses to recombinant encoded antigens (Ags) are mostly weak. We have previously demonstrated that the timing of viral Ag expression in infected professional Ag-presenting cells strongly shapes the epitope immunodominance hierarchy. T cells recognizing determinants derived from late viral proteins have a clear disadvantage to proliferate during secondary responses. In this work we evaluate the effect of overexpressing the recombinant Ag using the modified vaccinia virus early/late promoter H5 (mPH5). Although the Ag-expression from the natural promoter 7.5 (P7.5) and the mPH5 seemed similar, detailed analysis showed that mPH5 not only induces higher expression levels than P7.5 during early phase of infection, but also Ag turnover is enhanced. The strong overexpression during the early phase leads to broader CD8 T cell responses, while preserving the priming efficiency of stable Ags. Moreover, the increase in Ag-secretion favors the induction of strong antibody responses. Our findings provide the rationale to develop new strategies for fine-tuning the responses elicited by recombinant modified vaccinia virus Ankara by using selected promoters to improve the performance of this viral vector.

Published
2014
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