Your search keyword '"nanoparticle vaccines"' showing total 5 results

1. In Vivo Assembly of Nanoparticles Achieved through Synergy of Structure‐Based Protein Engineering and Synthetic DNA Generates Enhanced Adaptive Immunity

Author

Ziyang Xu, Megan C. Wise, Neethu Chokkalingam, Susanne Walker, Edgar Tello‐Ruiz, Sarah T. C. Elliott, Alfredo Perales‐Puchalt, Peng Xiao, Xizhou Zhu, Ruth A. Pumroy, Paul D. Fisher, Katherine Schultheis, Eric Schade, Sergey Menis, Stacy Guzman, Hanne Andersen, Kate E. Broderick, Laurent M. Humeau, Kar Muthumani, Vera Moiseenkova‐Bell, William R. Schief, David B. Weiner, and Daniel W. Kulp

Subjects

DNA vaccines, in vivo self‐assembly, infectious diseases, nanoparticle vaccines, protein engineering, Science

Abstract

Abstract Nanotechnologies are considered to be of growing importance to the vaccine field. Through decoration of immunogens on multivalent nanoparticles, designed nanovaccines can elicit improved humoral immunity. However, significant practical and monetary challenges in large‐scale production of nanovaccines have impeded their widespread clinical translation. Here, an alternative approach is illustrated integrating computational protein modeling and adaptive electroporation‐mediated synthetic DNA delivery, thus enabling direct in vivo production of nanovaccines. DNA‐launched nanoparticles are demonstrated displaying an HIV immunogen spontaneously self‐assembled in vivo. DNA‐launched nanovaccines induce stronger humoral responses than their monomeric counterparts in both mice and guinea pigs, and uniquely elicit CD8+ effector T‐cell immunity as compared to recombinant protein nanovaccines. Improvements in vaccine responses recapitulate when DNA‐launched nanovaccines with alternative scaffolds and decorated antigen are designed and evaluated. Finally, evaluation of functional immune responses induced by DLnanovaccines demonstrates that, in comparison to control mice or mice immunized with DNA‐encoded hemagglutinin monomer, mice immunized with a DNA‐launched hemagglutinin nanoparticle vaccine fully survive a lethal influenza challenge, and have substantially lower viral load, weight loss, and influenza‐induced lung pathology. Additional study of these next‐generation in vivo‐produced nanovaccines may offer advantages for immunization against multiple disease targets.

Published

2020

2. In Vivo Assembly of Nanoparticles Achieved through Synergy of Structure‐Based Protein Engineering and Synthetic DNA Generates Enhanced Adaptive Immunity.

Author

Xu, Ziyang, Wise, Megan C., Chokkalingam, Neethu, Walker, Susanne, Tello‐Ruiz, Edgar, Elliott, Sarah T. C., Perales‐Puchalt, Alfredo, Xiao, Peng, Zhu, Xizhou, Pumroy, Ruth A., Fisher, Paul D., Schultheis, Katherine, Schade, Eric, Menis, Sergey, Guzman, Stacy, Andersen, Hanne, Broderick, Kate E., Humeau, Laurent M., Muthumani, Kar, and Moiseenkova‐Bell, Vera

Subjects

*ARTIFICIAL chromosomes, *PROTEIN engineering, *SYNTHETIC proteins, *GUINEA pigs, *VACCINE effectiveness, *DNA synthesis, *CD8 antigen

Abstract

Nanotechnologies are considered to be of growing importance to the vaccine field. Through decoration of immunogens on multivalent nanoparticles, designed nanovaccines can elicit improved humoral immunity. However, significant practical and monetary challenges in large‐scale production of nanovaccines have impeded their widespread clinical translation. Here, an alternative approach is illustrated integrating computational protein modeling and adaptive electroporation‐mediated synthetic DNA delivery, thus enabling direct in vivo production of nanovaccines. DNA‐launched nanoparticles are demonstrated displaying an HIV immunogen spontaneously self‐assembled in vivo. DNA‐launched nanovaccines induce stronger humoral responses than their monomeric counterparts in both mice and guinea pigs, and uniquely elicit CD8+ effector T‐cell immunity as compared to recombinant protein nanovaccines. Improvements in vaccine responses recapitulate when DNA‐launched nanovaccines with alternative scaffolds and decorated antigen are designed and evaluated. Finally, evaluation of functional immune responses induced by DLnanovaccines demonstrates that, in comparison to control mice or mice immunized with DNA‐encoded hemagglutinin monomer, mice immunized with a DNA‐launched hemagglutinin nanoparticle vaccine fully survive a lethal influenza challenge, and have substantially lower viral load, weight loss, and influenza‐induced lung pathology. Additional study of these next‐generation in vivo‐produced nanovaccines may offer advantages for immunization against multiple disease targets. [ABSTRACT FROM AUTHOR]

Published

2020

3. Computational design of vaccine immunogens

Author

Castro, Karla M., Scheck, Andreas, Xiao, Shuhao, and Correia, Bruno E.

Subjects

elicitation, AIDS Vaccines, epitope, Vaccines, Biomedical Engineering, Bioengineering, accurate design, functional sites, Protein Engineering, Antibodies, Neutralizing, antigen, nanoparticle vaccines, viruses, protein, neutralizing antibody-responses, induction, Biotechnology

Abstract

Computational protein engineering has enabled the rational design of customized proteins, which has propelled both sequence-based and structure-based immunogen engineering and delivery. By discerning antigenic determinants of viral pathogens, computational methods have been implemented to successfully engineer representative viral strains able to elicit broadly neutralizing responses or present antigenic sites of viruses for focused immune responses. Combined with improvements in customizable nanoparticle design, immunogens are multivalently displayed to enhance immune responses. These rationally designed immunogens offer unique and powerful approaches to engineer vaccines for pathogens, which have eluded traditional approaches.

Published

2022

4. Nanoparticle Vaccines: In Vivo Assembly of Nanoparticles Achieved through Synergy of Structure‐Based Protein Engineering and Synthetic DNA Generates Enhanced Adaptive Immunity (Adv. Sci. 8/2020)

Author

Xizhou Zhu, Kate E. Broderick, Katherine Schultheis, Stacy Guzman, Sergey Menis, Karuppiah Muthumani, Eric Schade, William R. Schief, Megan C. Wise, Hanne Andersen, Alfredo Perales-Puchalt, David B. Weiner, Sarah T. C. Elliott, Edgar Tello-Ruiz, Laurent Humeau, Paul Fisher, Peng Xiao, Daniel W. Kulp, Ruth A. Pumroy, Vera Y. Moiseenkova-Bell, Neethu Chokkalingam, Susanne Walker, and Ziyang Xu

Subjects

Chemistry, General Chemical Engineering, Inside Back Cover, General Engineering, General Physics and Astronomy, Medicine (miscellaneous), Nanoparticle, protein engineering, Protein engineering, Acquired immune system, infectious diseases, Biochemistry, Genetics and Molecular Biology (miscellaneous), humanities, DNA vaccination, DNA vaccines, Synthetic DNA, In vivo, Biophysics, Structure based, General Materials Science, in vivo self‐assembly, nanoparticle vaccines

Abstract

In article number https://doi.org/10.1002/advs.201902802, David B. Weiner, Daniel W. Kulp, and co‐workers demonstrate that synthetic DNA delivery and adaptive electroporation can launch de novo assembly of different nanoparticle vaccines in the hosts to elicit significantly improved responses while reducing required doses. Next‐generation designer vaccines can now be rapidly evaluated in vivo to facilitate clinical translation for the betterment of human and animal health.

Published

2020

5. Nanoparticle Vaccines: In Vivo Assembly of Nanoparticles Achieved through Synergy of Structure‐Based Protein Engineering and Synthetic DNA Generates Enhanced Adaptive Immunity (Adv. Sci. 8/2020).

Author

Xu, Ziyang, Wise, Megan C., Chokkalingam, Neethu, Walker, Susanne, Tello‐Ruiz, Edgar, Elliott, Sarah T. C., Perales‐Puchalt, Alfredo, Xiao, Peng, Zhu, Xizhou, Pumroy, Ruth A., Fisher, Paul D., Schultheis, Katherine, Schade, Eric, Menis, Sergey, Guzman, Stacy, Andersen, Hanne, Broderick, Kate E., Humeau, Laurent M., Muthumani, Kar, and Moiseenkova‐Bell, Vera

Subjects

*ARTIFICIAL chromosomes, *PROTEIN engineering, *SYNTHETIC proteins, *VACCINES, *DNA synthesis, *DNA vaccines

Published

2020