Self-Assembled, Adjuvant/Antigen-Based Nanovaccine Mediates Anti-Tumor Immune Response against Melanoma Tumor

Rajendrakumar, Santhosh Kalash; Mohapatra, Adityanarayan; Singh, Bijay; Revuri, Vishnu; Lee, Yong-Kyu; Kim, Chang Seong; Cho, Chong‐Su; Park, In Kyu

doi:10.3390/polym10101063

Cited by 18 publications

(11 citation statements)

References 44 publications

(50 reference statements)

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“…Splenocytes were isolated from mice that showed complete regression of distant tumors. Effector T cells were prepared and purified using a nylon column method as previously described. , Collected effector T cells were labeled with 2 μM carboxyfluorescein succinimidyl ester (CFSE) (BioLegend) for 5 min at room temperature. CT26 cells were labeled with CellTracker Red CMTPX dye (Invitrogen) at room temperature and then cocultured with CFSE-labeled T cells in a 24-well plate at a T cell:target cell ratio of 100:1.…”

Section: Methodsmentioning

confidence: 99%

In Situ Nanoadjuvant-Assembled Tumor Vaccine for Preventing Long-Term Recurrence

et al. 2019

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Although immune checkpoint inhibitors have emerged as a breakthrough in cancer therapy, a monotherapy approach is not sufficient. Here, we report an immune checkpoint inhibitor-modified nanoparticle for an in situ-assembled tumor vaccine that can activate immune systems in the tumor microenvironment and prevent the long-term recurrence of tumors. Adjuvant-loaded nanoparticles were prepared by entrapping imiquimod (IQ) in photoresponsive polydopamine nanoparticles (IQ/PNs). The surfaces of IQ/PNs were then modified with anti-PDL1 antibody (PDL1Ab-IQ/PNs) for in situ assembly with inactivated tumor cells and immune checkpoint blocking of PDL1 (programmed cell death 1 ligand 1). The presence of anti-PDL1 antibodies on IQ/PNs increased the binding of nanoparticles to CT26 cancer cells overexpressing PDL1. Subsequent near-infrared (NIR) irradiation induced a greater photothermal anticancer effect against cells treated with PDL1Ab-IQ/PNs than cells treated with plain PNs or unmodified IQ/PNs. To mimic the tumor microenvironment, we cocultured bone marrow-derived dendritic cells with CT26 cells treated with various nanoparticle formulations and NIR irradiated. This coculture study revealed that NIR-inactivated, PDL1Ab-IQ/PN-bound CT26 cells induced maturation of dendritic cells to the greatest extent. Following a single intravenous administration of different nanoparticle formulations in CT26 tumor-bearing mice, PDL1Ab-IQ/PNs showed greater tumor tissue accumulation than unmodified nanoparticles. Subsequent NIR irradiation of mice treated with PDL1Ab-IQ/PNs resulted in tumor ablation. In addition to primary tumor ablation, PDL1Ab-IQ/PNs completely prevented the growth of a secondarily challenged CT26 tumor at a distant site, producing 100% survival for up to 150 days. A long-term protection study revealed that treatment with PDL1Ab-IQ/PNs followed by NIR irradiation inhibited the growth of distant, secondarily challenged CT26 tumors 150 days after the first tumor inoculation. Moreover, increased infiltration of T cells was observed in tumor tissues treated with PDL1Ab-IQ/PNs and NIR-irradiated, and T cells isolated from splenocytes of mice in which tumor recurrence was prevented showed active killing of CT26 cells. These results suggest that PDL1Ab-IQ/PNs in conjunction with NIR irradiation induce a potent, in situ-assembled, all-in-one tumor vaccine with adjuvant-containing nanoparticle-bound, inactivated tumor cells. Such in situ nanoadjuvant-assembled tumor vaccines can be further developed for long-term prevention of tumor recurrence without the need for chemotherapy.

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Section: Methodsmentioning

confidence: 99%

In Situ Nanoadjuvant-Assembled Tumor Vaccine for Preventing Long-Term Recurrence

et al. 2019

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“…This enhanced permeability and retention (EPR) principle is one of the key concepts for cancer nanotechnology; carriers with a hydrodynamic diameter larger than ∼20 nm avoid rapid kidney filtration, and carriers smaller than the tumor-dependent interendothelial spacing can extravasate into the tumor tissue. , Thus, polymeric carriers for solid tumors have generally been designed to have hydrophilic shielding and range in size between 20 and 200 nm in diameter . These design principles have been applied to polymeric formulations for tumor delivery of peptides in murine cancer models. ,, However, the broad relevance of EPR-based tumor delivery for clinical nanomedicines is the subject of significant discussion and debate. , Many nanomedicines that perform well in animal models have not translated to clinical success . A broad analysis of tumor accumulation by nanoparticle formulations revealed that a median 0.7% injected dose is delivered to the solid tumor across varying materials, size, charge, and tumor models .…”

Section: Rational Design Of Polymeric Carriers For Improved Peptide D...mentioning

confidence: 99%

“…In another vaccine system, Rajendrakumar et al . formulated nanocomplexes containing poly(sorbitol)- co -PEI (PSPEI) complexed with tumor lysate protein and adjuvant poly I:C (PSPEI–PAA) . In a B16F10 subcutaneous model, PSPEI–PAA showed high DC uptake in lymph nodes and increased tumor infiltration by CTLs.…”

Section: Rational Design Of Polymeric Carriers For Improved Peptide D...mentioning

confidence: 99%

Design of Polymeric Carriers for Intracellular Peptide Delivery in Oncology Applications

Sylvestre

Prossnitz

et al. 2021

Chem. Rev.

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In recent decades, peptides, which can possess high potency, excellent selectivity, and low toxicity, have emerged as promising therapeutics for cancer applications. Combined with an improved understanding of tumor biology and immuno-oncology, peptides have demonstrated robust antitumor efficacy in preclinical tumor models. However, the translation of peptides with intracellular targets into clinical therapies has been severely hindered by limitations in their intrinsic structure, such as low systemic stability, rapid clearance, and poor membrane permeability, that impede intracellular delivery. In this Review, we summarize recent advances in polymer-mediated intracellular delivery of peptides for cancer therapy, including both therapeutic peptides and peptide antigens. We highlight strategies to engineer polymeric materials to increase peptide delivery efficiency, especially cytosolic delivery, which plays a crucial role in potentiating peptide-based therapies. Finally, we discuss future opportunities for peptides in cancer treatment, with an emphasis on the design of polymer nanocarriers for optimized peptide delivery.

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“…The development of biomimetic NPs with chemical and structural modifications to mimic the biological environment is an established approach for cancer therapy. Nanovaccines are novel platforms for delivery of both adjuvants and antigens that generate a strong antitumor response by modulating the immune system [124]. Various type of nanovaccines, such as liposomes, protein NPs, and cell-membrane-coated nanomicelles, have been recently developed for successful anti-cancer therapy [125,126].…”

Section: Applications Of Biomimetic Nanovaccinesmentioning

confidence: 99%

Recent Advances in Nanovaccines Using Biomimetic Immunomodulatory Materials

et al. 2019

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The development of vaccines plays a vital role in the effective control of several fatal diseases. However, effective prophylactic and therapeutic vaccines have yet to be developed for completely curing deadly diseases, such as cancer, malaria, HIV, and serious microbial infections. Thus, suitable vaccine candidates need to be designed to elicit appropriate immune responses. Nanotechnology has been found to play a unique role in the design of vaccines, providing them with enhanced specificity and potency. Nano-scaled materials, such as virus-like particles, liposomes, polymeric nanoparticles (NPs), and protein NPs, have received considerable attention over the past decade as potential carriers for the delivery of vaccine antigens and adjuvants, due to their beneficial advantages, like improved antigen stability, targeted delivery, and long-time release, for which antigens/adjuvants are either encapsulated within, or decorated on, the NP surface. Flexibility in the design of nanomedicine allows for the programming of immune responses, thereby addressing the many challenges encountered in vaccine development. Biomimetic NPs have emerged as innovative natural mimicking biosystems that can be used for a wide range of biomedical applications. In this review, we discuss the recent advances in biomimetic nanovaccines, and their use in anti-bacterial therapy, anti-HIV therapy, anti-malarial therapy, anti-melittin therapy, and anti-tumor immunity.

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Self-Assembled, Adjuvant/Antigen-Based Nanovaccine Mediates Anti-Tumor Immune Response against Melanoma Tumor

Cited by 18 publications

References 44 publications

In Situ Nanoadjuvant-Assembled Tumor Vaccine for Preventing Long-Term Recurrence

In Situ Nanoadjuvant-Assembled Tumor Vaccine for Preventing Long-Term Recurrence

Design of Polymeric Carriers for Intracellular Peptide Delivery in Oncology Applications

Recent Advances in Nanovaccines Using Biomimetic Immunomodulatory Materials

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