二十年的植物源性候选疫苗：嵌合蛋白方法综述。

Two decades of plant-based candidate vaccines: a review of the chimeric protein approaches.

机构信息

Laboratorio de biofarmacéuticos recombinantes, Facultad de Ciencias Químicas, Universidad Autónoma de San Luis Potosí, Av. Dr. Manuel Nava 6, 78210, San Luis Potosi, SLP, Mexico.

出版信息

Plant Cell Rep. 2011 Aug;30(8):1367-82. doi: 10.1007/s00299-011-1065-3. Epub 2011 Apr 20.

DOI:10.1007/s00299-011-1065-3

PMID:21505834

Abstract

Genetic engineering revolutionized the concept of traditional vaccines since subunit vaccines became reality. Additionally, over the past two decades plant-derived antigens have been studied as potential vaccines with several advantages, including low cost and convenient administration. More specifically, genetic fusions allowed the expression of fusion proteins carrying two or more components with the aim to elicit immune responses against different targets, including antigens from distinct pathogens or strains. This review aims to provide an update in the field of the production of plant-based vaccine, focusing on those approaches based on the production of chimeric proteins comprising antigens from human pathogens, emphasizing the case of cholera toxin/E. coli enterotoxin fusions, chimeric viruses like particles approaches as well as the possible use of adjuvant-producing plants as expression hosts. Challenges for the near future in this field are also discussed.

摘要

基因工程颠覆了传统疫苗的概念，因为亚单位疫苗成为了现实。此外，在过去的二十年中，植物来源的抗原已被研究作为潜在的疫苗，具有几个优点，包括低成本和方便管理。更具体地说，基因融合允许表达携带两种或更多成分的融合蛋白，目的是引发针对不同靶标的免疫反应，包括来自不同病原体或菌株的抗原。本综述旨在提供植物源性疫苗生产领域的最新进展，重点介绍基于生产包含人类病原体抗原的嵌合蛋白的方法，强调霍乱毒素/大肠杆菌肠毒素融合物、类似颗粒的嵌合病毒等方法，以及作为表达宿主的具有产生佐剂能力的植物的可能用途。还讨论了该领域未来的挑战。

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二十年的植物源性候选疫苗：嵌合蛋白方法综述。

Two decades of plant-based candidate vaccines: a review of the chimeric protein approaches.

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