Josiah D. Smith scite author profile

Vaccines are one of the best health care advances ever developed, having led to the eradication of smallpox and near eradication of polio and diphtheria. While tremendously successful, traditional vaccines (i.e., whole-killed or live-attenuated) have been associated with some undesirable side effects, including everything from mild injection site inflammation to the autoimmune disease Guillain–Barré syndrome. This has led recent research to focus on developing subunit vaccines (i.e., protein, peptide, or DNA vaccines) since they are inherently safer because they deliver only the bioactive components necessary (i.e., antigens) to produce a protective immune response against the pathogen of interest. However, a major challenge in developing subunit vaccines is overcoming numerous biological barriers to effectively deliver the antigen to the secondary lymphoid organs where adaptive immune responses are orchestrated. Peptide amphiphile micelles are a class of biomaterials that have been shown to possess potent self-adjuvanting vaccine properties, but their optimization capacity and underlying immunostimulatory mechanism are not well understood. The present work investigated the influence of micelle size and charge on the materials’ bioactivity, including lymph node accumulation, cell uptake ability, and immunogenicity. The results generated provide considerable insight into how micelles exert their biological effects, yielding a micellar toolbox that can be exploited to either enhance or diminish host immune responses. This exciting development makes peptide amphiphile micelles an attractive candidate for both immune activation and suppression applications.

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Instructive Design of Triblock Peptide Amphiphiles for Structurally Complex Micelle Fabrication

Zhang

Morton

Smith

et al. 2018

ACS Biomater. Sci. Eng.

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Hydrophobically driven self-assembly is a well-understood principle that has been shown to facilitate micelle formation. Although quite useful, the library of structures accessible is limited to only a few simplistic geometric configurations that are suboptimal for complex applications. It is believed that other physical phenomena like hydrogen bonding and electrostatic interactions can be exploited to complement hydrophobic interactions allowing for the design of structurally complex, aggregated micelles. To test this theory, ABC triblock peptide amphiphiles comprising an application-specific peptide, a zwitterion-like peptide, and a hydrophobic lipid were synthesized for which block sequence modifications and order changes were used to investigate their impact on micelle formation. The results provide significant evidence that both hydrophobic and electrostatic driving forces influence the formation of complex micellar structures. Specifically, hydrophobic self-assembly facilitates individual micelle formation, whereas dipole electrostatic interactions govern the association of micelle units into complex architectures. Initial results indicate that there exists considerable flexibility in the choice of application-specific peptide allowing these structures to serve as a platform technology for a variety of fields.

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Nanoparticles as synthetic vaccines

Smith¹,

Morton²,

Ulery³

2015

Current Opinion in Biotechnology

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Aptamer-displaying peptide amphiphile micelles as a cell-targeted delivery vehicle of peptide cargoes

Smith¹,

Cardwell²,

Porciani³

et al. 2018

Phys. Biol.

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Peptide amphiphile micelles (PAMs) are attractive vehicles for the delivery of a variety of therapeutic and prophylactic peptides. However, a key limitation of PAMs is their lack of preferential targeting ability. In this paper, we describe our design of a PAM system that incorporates a DNA oligonucleotide amphiphile (antitail amphiphile-AA) to form A/PAMs. A cell-targeting DNA aptamer with a 3' extension sequence (tail) complementary to the AA is annealed to the surface to form aptamer-displaying PAMs (Aptamer~A/PAMs). Aptamer~A/PAMs are small, anionic, stable nanoparticles capable of delivering a large mass percentage peptide amphiphile (PA) compared to targeting DNA components. Aptamer~A/PAMs are stable for over 4 h in the presence of biological fluids. Additionally, the aptamer retains its cell-targeting properties when annealed to the A/PAM, thus leading to enhanced delivery to a specifically-targeted B-cell leukemia cell line. This exciting modular technology can be readily used with a library of different targeting aptamers and PAs, capable of improving the bioavailability and potency of the peptide cargo.

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Vaccine Adjuvant Incorporation Strategy Dictates Peptide Amphiphile Micelle Immunostimulatory Capacity

Zhang

Kramer

Smith

et al. 2018

AAPS J

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Current vaccine research has shifted from traditional vaccines (i.e., whole-killed or live-attenuated) to subunit vaccines (i.e., protein, peptide, or DNA) as the latter is much safer due to delivering only the bioactive components necessary to produce a desirable immune response. Unfortunately, subunit vaccines are very weak immunogens requiring delivery vehicles and the addition of immunostimulatory molecules termed adjuvants to convey protective immunity. An interesting type of delivery vehicle is peptide amphiphile micelles (PAMs), unique biomaterials where the vaccine is part of the nanomaterial itself. Due to the modularity of PAMs, they can be readily modified to deliver both vaccine antigens and adjuvants within a singular construct. Through the co-delivery of a model antigenic epitope (Ovalbumin-OVA) and a known molecular adjuvant (e.g., 2,3-dipalmitoyl-S-glyceryl cysteine-PamC), greater insight into the mechanisms by which PAMs can exert immunostimulatory effects was gained. It was found that specific combinations of antigen and adjuvant can significantly alter vaccine immunogenicity both in vitro and in vivo. These results inform fundamental design rules that can be leveraged to fabricate optimal PAM-based vaccine formulations for future disease-specific applications. Graphical Abstract.

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Josiah D. Smith

Peptide Amphiphile Micelle Vaccine Size and Charge Influence the Host Antibody Response

Instructive Design of Triblock Peptide Amphiphiles for Structurally Complex Micelle Fabrication

Nanoparticles as synthetic vaccines

Aptamer-displaying peptide amphiphile micelles as a cell-targeted delivery vehicle of peptide cargoes

Vaccine Adjuvant Incorporation Strategy Dictates Peptide Amphiphile Micelle Immunostimulatory Capacity

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