Rezvan Jamaledin, Rossella Sartorius, Concetta Di Natale, Valentina Onesto, Roberta Manco, Valentina Mollo, Raffaele Vecchione, Piergiuseppe De Berardinis, Paolo Antonio Netti
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The main goal of this study was to provide tunable formulations of the bacteriophage encapsulated in polymeric microparticles (MPs). We used poly (lactic-co-glycolic-acid) as a biocompatible and biodegradable polymer with ammonium bicarbonate as a porogen to encapsulate bacteriophage expressing OVA (257-264) antigenic peptide. We demonstrate that nano-engineered fdOVA bacteriophages encapsulated in MPs preserve their structure and are immunologically active, inducing a strong immune response towards the delivered peptide. Moreover, MP encapsulation prolongs bacteriophage stability over time also at room temperature. Additionally, in this study, we show the ability of in silico-supported approach to predict and tune the release of bacteriophages. 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引用次数: 0
摘要
噬菌体在生物工程领域引起了极大的关注,涉及从组织工程到治疗和临床应用等多个研究领域。尽管噬菌体的血浆不稳定性和降解限制了其在医药市场上的应用,但在蛋白囊上携带多份外来肽的重组丝状噬菌体已成功用于疫苗递送。将噬菌体封装在聚合物材料中的技术可用于保持噬菌体的活性,延长其半衰期,并精细调节其在目标环境中的释放。本研究的主要目标是提供包裹在聚合物微颗粒(MPs)中的噬菌体可调配方。我们使用聚(乳酸-共聚-乙醇酸)作为生物相容性和可生物降解的聚合物,以碳酸氢铵作为致孔剂,来封装表达 OVA(257-264)抗原肽的噬菌体。我们证明,封装在 MPs 中的纳米工程 fdOVA 噬菌体能保持其结构,并具有免疫活性,能诱导对输送的肽产生强烈的免疫反应。此外,MP 封装还能延长噬菌体在室温下的稳定性。此外,在这项研究中,我们还展示了硅支持方法预测和调整噬菌体释放的能力。这些结果为基于噬菌体的多功能疫苗递送系统奠定了框架,该系统可成功地持续产生强大的免疫反应,用作抗击癌症和新出现疾病的平台。PLGA 微颗粒释放噬菌体,诱导树突状细胞活化,增强抗原递呈和特异性 T 细胞反应。噬菌体包裹的微针有可能进入人体并产生强大的免疫反应。
PLGA microparticle formulations for tunable delivery of a nano-engineered filamentous bacteriophage-based vaccine: in vitro and in silico-supported approach.
Bacteriophages have attracted great attention in the bioengineering field in diverse research areas from tissue engineering to therapeutic and clinical applications. Recombinant filamentous bacteriophage, carrying multiple copies of foreign peptides on protein capsid has been successfully used in the vaccine delivery setting, even if their plasma instability and degradation have limited their use on the pharmaceutical market. Encapsulation techniques in polymeric materials can be applied to preserve bacteriophage activity, extend its half-life, and finely regulate their release in the target environment. The main goal of this study was to provide tunable formulations of the bacteriophage encapsulated in polymeric microparticles (MPs). We used poly (lactic-co-glycolic-acid) as a biocompatible and biodegradable polymer with ammonium bicarbonate as a porogen to encapsulate bacteriophage expressing OVA (257-264) antigenic peptide. We demonstrate that nano-engineered fdOVA bacteriophages encapsulated in MPs preserve their structure and are immunologically active, inducing a strong immune response towards the delivered peptide. Moreover, MP encapsulation prolongs bacteriophage stability over time also at room temperature. Additionally, in this study, we show the ability of in silico-supported approach to predict and tune the release of bacteriophages. These results lay the framework for a versatile bacteriophage-based vaccine delivery system that could successfully generate robust immune responses in a sustained manner, to be used as a platform against cancer and new emerging diseases.
Graphical abstract: Synopsis: administration of recombinant bacteriophage-loaded PLGA microparticles for antigen delivery. PLGA microparticles release the bacteriophages, inducing activation of dendritic cells and enhancing antigen presentation and specific T cell response. Bacteriophage-encapsulated microneedles potentially can be administered into human body and generate robust immune responses.
期刊介绍:
The Journal of Nanostructure in Chemistry (JNC) publishes cutting-edge research at the intersections of chemistry, biology, biotechnology, materials science, physics, and engineering. It features high-quality research, perspectives, and review articles covering various disciplines within the natural sciences, biomedicine, and engineering. The journal's scope includes, but is not limited to, the following topics:
Target drug and gene delivery
Tissue engineering and regenerative medicine
Cancer therapy
Diagnosis and Bioimaging
Electrochemical detection and sensing
Food industry and packaging
Environments (catalyst, coatings, and water treatment)
Energy (fuel cells, capacitor, laser)