Peptide Amphiphile Micelles Self-Adjuvant Group A Streptococcal Vaccination

Trent, Amanda; Ulery, Bret D.; Black, Matthew; Barrett, John C.; Liang, Simon; Kostenko, Yulia; David, Natalie A.; Tirrell, Matthew

doi:10.1208/s12248-014-9707-3

Cited by 82 publications

(94 citation statements)

References 61 publications

(106 reference statements)

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“…19,20 In our previous studies, micelles were used as a vaccine delivery vehicle that induced a peptide-specific antibody response. 21 Interestingly, PAMs stimulated a stronger antibody response than peptide alone without the use of an adjuvant making it a self-adjuvanting device. Furthermore, while the hydrophobic tails enhance cell uptake by anchoring into cell membranes, 22 they do not act as pathogen recognition receptor (PRR) agonists and therefore do not function as molecular adjuvants.…”

Section: Introductionmentioning

confidence: 99%

“…Furthermore, while the hydrophobic tails enhance cell uptake by anchoring into cell membranes, 22 they do not act as pathogen recognition receptor (PRR) agonists and therefore do not function as molecular adjuvants. 21 Rather, it is thought to be the self-assembled, particular-based physical nature of PAMs that affords them immunogenicity. Self-assembly of PAs has the added benefit of being able to facilitate the fabrication of multifunctional heterogeneous micelles through simple mixing of different PAs or other amphiphilic molecules.…”

Section: Introductionmentioning

confidence: 99%

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Modular Peptide Amphiphile Micelles Improving an Antibody-Mediated Immune Response to Group A Streptococcus

Barrett

Ulery

Trent

et al. 2016

ACS Biomater. Sci. Eng.

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Inducing a strong and specific immune response is the hallmark of a successful vaccine. Nanoparticles have emerged as promising vaccine delivery devices to discover and elicit immune responses. Fine-tuning a nanoparticle vaccine to create an immune response with specific antibody and other cellular responses is influenced by many factors such as shape, size, and composition. Peptide amphiphile micelles are a unique biomaterials platform that can function as a modular vaccine delivery system, enabling control over many of these important factors and delivering payloads more efficiently to draining lymph nodes. In this study, the modular properties of peptide amphiphile micelles are utilized to improve an immune response against a Group A Streptococcus B cell antigen (J8). The hydrophobic/hydrophilic interface of peptide amphiphile micelles enabled the precise entrapment of amphiphilic adjuvants which were found to not alter micelle formation or shape. These heterogeneous micelles significantly enhanced murine antibody responses when compared to animals vaccinated with nonadjuvanted micelles or soluble J8 peptide supplemented with a classical adjuvant. The heterogeneous micelle induced antibodies also showed cross-reactivity with wild-type Group A Streptococcus providing evidence that micelle-induced immune responses are capable of identifying their intended pathogenic targets.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Modular Peptide Amphiphile Micelles Improving an Antibody-Mediated Immune Response to Group A Streptococcus

Barrett

Ulery

Trent

et al. 2016

ACS Biomater. Sci. Eng.

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“…They annealed the micelles at 70 • C to form stable long fibrils while preserving the alpha helical secondary structure. These micelles induced high IgG1 antibody titres without the assistance of TLR-2 receptors in BALB/c mice and HEK-293 cells expressing the TLR-2 receptor [190]. This study demonstrated that micellization of the peptide amphiphiles enhanced the delivery of antigens in their correct conformation.…”

Section: Vaccine Design Using Lipidated Peptide Amphiphilesmentioning

confidence: 68%

Recent advances in self-assembled peptides: Implications for targeted drug delivery and vaccine engineering

Eskandari

Guerin

Tóth

et al. 2017

Advanced Drug Delivery Reviews

307

220

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Self-assembled peptides have shown outstanding characteristics for vaccine delivery and drug targeting. Peptide molecules can be rationally designed to self-assemble into specific nanoarchitectures in response to changes in their assembly environment including: pH, temperature, ionic strength, and interactions between host (drug) and guest molecules. The resulting supramolecular nanostructures include nanovesicles, nanofibers, nanotubes, nanoribbons, and hydrogels and have a diverse range of mechanical and physicochemical properties. These molecules can be designed for cell-specific targeting by including adhesion ligands, receptor recognition ligands, or peptide-based antigens in their design, often in a multivalent display. Depending on their design, self-assembled peptide nanostructures have advantages in biocompatibility, stability against enzymatic degradation, encapsulation of hydrophobic drugs, sustained drug release, shear-thinning viscoelastic properties, and/or adjuvanting properties. These molecules can also act as intracellular transporters and respond to changes in the physiological environment. Furthermore, this class of materials has shown sequence- and structure-dependent impacts on the immune system that can be tailored to non-immunogenic for drug targeting, and immunogenic for vaccine delivery. This review explores self-assembled peptide nanostructures (beta sheets, alpha helices, peptide amphiphiles, amino acid pairing, elastin like polypeptides, cyclic peptides, short peptides, Fmoc peptides, and peptide hydrogels) and their application in vaccine delivery and drug targeting.

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“…This theme issue also includes several original research articles. Tirrell and colleagues report on recent progress in the development of peptide amphiphile micelles that selfadjuvant group A streptococcal vaccinations [9]. In their report, a streptococcus B lymphocyte antigen and a dialkyl hydrophobic moiety were covalently linked and underwent self-assembly into micelles when added to water, due to the hydrophobic interactions among the alkyl tails.…”

mentioning

confidence: 99%

“…These include peptide amphiphile micelles [9], pH responsive polymer-based nanoparticles [10], cationic liposomes [11], polysaccharide-based nanoparticles [12], and nanoparticles formed from biodegradable polymers such as p o l y l a c t i c -c o -g l y c o l i d e ( P L G A ) [ 1 3 -1 5 ] and polyanhydrides [16]. This theme issue includes a comprehensive review by Jewell and colleagues on the topic of harnessing biomaterials to engineer the lymph node microenvironment for immunity or tolerance [17].…”

mentioning

confidence: 99%

Nanoparticles in Vaccine Delivery

Salem

2015

AAPS J

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Vaccines have been responsible for the effective control or elimination of many potentially fatal diseases. However, many other diseases such as cancers and those caused by intracellular pathogens still lack effective prophylactic or therapeutic vaccines. Furthermore, in developing countries, there is a need for vaccine formulations with stable shelf lives that eliminate or limit the number of boosts that are needed. With an increasing understanding of the immune system, much research has been focused on improving the current approach toward vaccine development in these areas. Nano and microparticle-based delivery systems have the potential to enhance the duration of antigen presence (depot formation), enhance dendritic cell (DC)-mediated antigen uptake, direct the stimulation of DCs, and promote cross-presentation. Nanoparticles also offer the potential to protect antigens and adjuvant from premature enzymatic and proteolytic degradation. Nanoparticle delivery systems offer the added strength of multi-component loading which is of considerable significance particularly in immunotherapy where simultaneous delivery of antigens, immunoadjuvants, and targeting ligands is ideal [1][2][3][4][5][6][7][8]. Additionally, due to their large surface area, nanoparticles can be readily surface-engineered with proteins, peptides, polymers, cell-penetrating moieties, reporter groups, and other functional and targeting ligands. The ease of design and use combined with multifunctionality makes using nanoparticles a versatile and useful delivery strategy for vaccines and immunotherapies.In this special theme issue, we cover recent progress in the development and application of a variety of different classes of nanoparticles in immunotherapeutic applications. . This theme issue includes a comprehensive review by Jewell and colleagues on the topic of harnessing biomaterials to engineer the lymph node microenvironment for immunity or tolerance [17]. The focus on the lymph nodes is important because the lymph nodes and other secondary lymphoid organs, such as the spleen, play crucial roles in determining if and how immune responses develop following vaccination or immunotherapy. This theme issue also includes several original research articles. Tirrell and colleagues report on recent progress in the development of peptide amphiphile micelles that selfadjuvant group A streptococcal vaccinations [9]. In their report, a streptococcus B lymphocyte antigen and a dialkyl hydrophobic moiety were covalently linked and underwent self-assembly into micelles when added to water, due to the hydrophobic interactions among the alkyl tails. Upon vaccination of mice with these micelles, a potent IgG1 antibody response was induced that was similar to responses obtained from co-administration of soluble peptide with two classical adjuvants. Stayton and colleagues report on the enhancement of MHC-I antigen presentation via architectural control of pH-responsive endosomolytic polymer nanoparticles [10]. In their study, increased MHC-I antigen presentat...

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Peptide Amphiphile Micelles Self-Adjuvant Group A Streptococcal Vaccination

Cited by 82 publications

References 61 publications

Modular Peptide Amphiphile Micelles Improving an Antibody-Mediated Immune Response to Group A Streptococcus

Modular Peptide Amphiphile Micelles Improving an Antibody-Mediated Immune Response to Group A Streptococcus

Recent advances in self-assembled peptides: Implications for targeted drug delivery and vaccine engineering

Nanoparticles in Vaccine Delivery

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