Vaccine Self-Assembling Immune Matrix Is a New Delivery Platform That Enhances Immune Responses to Recombinant HBsAg in Mice

Grenfell, Rafaella Fortini Queiroz; Shollenberger, Lisa M.; Samli, E. Farah; Harn, Donald A.

doi:10.1128/cvi.00714-14

Cited by 27 publications

(25 citation statements)

References 40 publications

(41 reference statements)

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“…Platforms that share structural similarities with Q11 and which may be interesting to study in this regard include other peptides that form into long, high-aspect ratio nanofibers. For example the peptide KFE8 has been explored previously in vaccinations against cocaine addiction [43]; the peptide RADA4 has been explored as a depotforming material in vaccines against hepatitis B [44]; the peptide EAK16 has been investigated in vaccines against HIV [45]; the peptide Ac-AAVVLLLW-COOH has been explored in anticancer vaccines [46]; and Q11 has been explored in applications including malaria [47], influenza [19], S. aureus vaccines [20], and cancer [48]. Other fibrous self-assemblies include those composed of peptide amphiphiles, which have been explored in anticancer vaccines [49] and vaccines against group A streptococcus [50].…”

Section: Discussionmentioning

confidence: 99%

Active immunotherapy for TNF-mediated inflammation using self-assembled peptide nanofibers

et al. 2017

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Active immunotherapies raising antibody responses against autologous targets are receiving increasing interest as alternatives to the administration of manufactured antibodies. The challenge in such an approach is generating protective and adjustable levels of therapeutic antibodies while at the same time avoiding strong T cell responses that could lead to autoimmune reactions. Here we demonstrate the design of an active immunotherapy against TNF-mediated inflammation using short synthetic peptides that assemble into supramolecular peptide nanofibers. Immunization with these materials, without additional adjuvants, was able to break B cell tolerance and raise protective antibody responses against autologous TNF in mice. The strength of the anti-TNF antibody response could be tuned by adjusting the epitope content in the nanofibers, and the T-cell response was focused on exogenous and non-autoreactive T-cell epitopes. Immunization with unadjuvanted peptide nanofibers was therapeutic in a lethal model of acute inflammation induced by intraperitoneally delivered lipopolysaccharide, whereas formulations adjuvanted with CpG showed comparatively poorer protection that correlated with a more Th1-polarized response. Additionally, immunization with peptide nanofibers did not diminish the ability of mice to clear infections ofListeria monocytogenes. Collectively this work suggests that synthetic self-assembled peptides can be attractive platforms for active immunotherapies against autologous targets.

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Section: Discussionmentioning

confidence: 99%

Active immunotherapy for TNF-mediated inflammation using self-assembled peptide nanofibers

et al. 2017

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“…Increasing numbers of peptide-based nanofibers (PNFs) are being used for biomedical applications, including tissue engineering, 1 promoting angiogenesis, 2 vaccination, 3 and cell labeling. 4 Particularly in drug delivery, PNFs have been used to promote the delivery of hydrophobic drug molecules to treat diseases such as myocardial infarction, 5 fracture healing, 6 cervical spinal cord injury, 7 and cancer.…”

Section: Introductionmentioning

confidence: 99%

Smart Nanotransformers with Unique Enzyme-Inducible Structural Changes and Drug Release Properties

et al. 2016

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We previously reported a high aspect ratio peptide nanofiber that could be effectively delivered to tumors with minimal nonspecific uptake by other organs. The peptidic nature offers the design flexibility of smart formulation with unique responsiveness. Two new formulations that behave congruously as nanotransformers (NTFs) are reported herein. NTF1 and NTF2 could biomechanically remodel upon enzyme activation to generate a degradable and an aggregable effect, respectively, within the lysosomal compartment. These NTFs were further evaluated as carriers of mertansine (DM1), a microtubule inhibitor. DM1-loaded NTF1 could be degraded by cathepsin B (CathB) to release the same active metabolite, as previously described in the lysosomal degradation of antibody-DM1 conjugate. In contrast, CathB only partially digested DM1-loaded NTF2 and induced aggregate formation to become a storage reservoir with slow payload release property. The DM1-loaded NTF1 exhibited a comparable cytotoxicity to the free drug and was more effective than the NTF2 formulation in eradicating triple negative breast cancer. Our data suggested that biological transformers with distinct enzyme-induced structural changes and payload release profiles could be designed for the intracellular delivery of cytotoxic and imaging agents.

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“…The goal of this approach is to generate a persistent source of antigen for prolonged immunostimulation, a partial mechanism of action of alum and other current adjuvants used in the clinic [15] . This fiber-based approach was employed to deliver a hepatitis B antigen with CpG, which triggered enhanced humoral and cellular responses when compared with a formulation containing alum and an equivalent dose of EIII [122] . Together, these results support the potential to use self-assembled materials to generate in vivo depots of antigen and immunostimulatory cues that can enhance immunogenicity.…”

Section: Pre-clinical Studies Using Self-assembled Materials Demonstrmentioning

confidence: 99%

Engineering self-assembled materials to study and direct immune function

Tostanoski

Jewell

2017

Advanced Drug Delivery Reviews

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The immune system is an awe-inspiring control structure that maintains a delicate and constantly changing balance between pro-immune functions that fight infection and cancer, regulatory or suppressive functions involved in immune tolerance, and homeostatic resting states. These activities are determined by integrating signals in space and time; thus, improving control over the densities, combinations, and durations with which immune signals are delivered is a central goal to better combat infectious disease, cancer, and autoimmunity. Self-assembly presents a unique opportunity to synthesize materials with well-defined compositions and controlled physical arrangement of molecular building blocks. This review highlights strategies exploiting these capabilities to improve the understanding of how precisely-displayed cues interact with immune cells and tissues. We present work centered on fundamental properties that regulate the nature and magnitude of immune response, highlight pre-clinical and clinical applications of self-assembled technologies in vaccines, cancer, and autoimmunity, and describe some of the key manufacturing and regulatory hurdles facing these areas.

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Vaccine Self-Assembling Immune Matrix Is a New Delivery Platform That Enhances Immune Responses to Recombinant HBsAg in Mice

Cited by 27 publications

References 40 publications

Active immunotherapy for TNF-mediated inflammation using self-assembled peptide nanofibers

Active immunotherapy for TNF-mediated inflammation using self-assembled peptide nanofibers

Smart Nanotransformers with Unique Enzyme-Inducible Structural Changes and Drug Release Properties

Engineering self-assembled materials to study and direct immune function

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