重组人血清白蛋白表达研究进展

本文综述了重组人血清白蛋白在细菌,酵母,植物和动物等表达系统中表达的研究进展。用酵母表达系统,尤其是毕赤酵母,表达的重组白蛋白产量高且提取工艺简单,是其产业化最具有前途的表达系统。同时在转基因动物、植物中培养表达也具有诱人的前景。     

重组人血清白蛋白表达研究进展

本文综述了重组人血清白蛋白在细菌,酵母,植物和动物等表达系统中表达的研究进展。用酵母表达系统,尤其是毕赤酵母,表达的重组白蛋白产量高且提取工艺简单,是其产业化最具有前途的表达系统。同时在转基因动物、植物中培养表达也具有诱人的前景。     

人血清白蛋白及其重组表达研究进展

人血清白蛋白在医疗方面有广泛的应用,其可作为血容量扩张剂和辅助治疗剂、培养基组分和保护剂、药物制剂、诊断试剂和医疗器械包被剂等。基因重组技术提供了一种规模制备人血清白蛋白的有效途径,并已建立了多种人血清白蛋白的重组表达系统。本文综述了重组人血清白蛋白在细菌、真菌、转基因植物和转基因动物等表达系统中的发展和应用概况。     

转基因植物疫苗的研究进展

近些年,随着遗传技术和植物基因工程的发展进步,疫苗（亚单位疫苗、活载体疫苗和核酸疫苗等）的研究迅速发展起来。尤其是利用转基因植物技术生产植物疫苗的研究受到了广泛的关注,在转基因植物（蔬菜、水果、农作物）的可食用部位表达抗原生产人或动物治疗用重组蛋白和疫苗的技术为可食性疫苗的研制开辟了新途径,展现了诱人的开发前景。植物来源的疫苗具有很多优势,如生产成本低、易于保存、免疫接种方便、甚至不需提取纯化等处理而直接食用。目前已有很多转基因植物疫苗产品投入开发和生产。文章综述了近几年转基因植物疫苗在表达系统、生产、生物安全／管理、公众健康等方面的研究进展,对转基因植物疫苗存在的问题进行了分析,并对其研究前景提出了展望。     

转基因植物表达重组蛋白的研究进展

植物表达系统的一些潜在优点 ,如重组蛋白的高积累水平 ,糖基化 ,细胞内的定位和自然储藏的稳定性是目前植物生产重组蛋白系统研究成为热点的主要原因 .在研究和选择转基因植物表达系统的过程中 ,转化 ,转化后 ,翻译 ,翻译后等环节都会影响到最终产物的数量和质量 ,因此应该了解基因表达的规律 ,以制定植物生产重组蛋白合适的策略 ,重组蛋白积累水平是关键 ,但其它因素如植物的选择 ,转基因植物的处理 ,下游加工等同样重要 .某些情形下 ,仅下游加工的成本一项就影响到特定植物表达系统的实际应用价值 .     

生产重组蛋白的植物表达系统

作为高附加值重组蛋白生产平台,由于在成本和安全性方面的优势,植物已成为继微生物、哺乳动物等表达系统之后,获得广泛认同的极具潜力的蛋白表达系统。植物表达系统主要包括转基因植株,叶绿体转化植物,瞬时表达系统,细胞悬浮培养。综述了这些表达系统生产重组蛋白的产量和质量,尤其是各种表达系统的优缺点。     

转基因植物作为生物反应器生产口蹄疫疫苗的研究进展

利用转基因植物作为生物反应器表达重组蛋白,生产外源蛋白质作为动物疫苗是一个很有吸引力的廉价生产系统,它有可能代替生产成本较高的传统疫苗的发酵生产系统。通过口蹄疫病毒VPI结构蛋白基因在转基因植物中的表达,口蹄疫疫苗已在植物中产生。在植物中生产的抗原能够保持其自身的免疫原性。本文简要综述了近十年来用转基因植物作为生物反应器生产口蹄疫疫苗的研究进展、特点及其应用前景。     

转基因植物作为生物反应器生产口蹄疫疫苗的研究进展

利用转基因植物作为生物反应器表达重组蛋白,生产外源蛋白质作为动物疫苗是一个很有吸引力的廉价生产系统,它有可能代替生产成本较高的传统疫苗的发酵生产系统。通过口蹄疫病毒VP1结构蛋白基因在转基因植物中的表达,口蹄疫疫苗已在植物中产生。在植物中生产的抗原能够保持其自身的免疫原性。本文简要综述了近十年来用转基因植物作为生物反应器生产口蹄疫疫苗的研究进展、特点及其应用前景 。     

转基因动物反应器

转基因动物反应器是解决目前对重组药用蛋白质日益增长需求的强有力工具之一。转基因动物能以高效而经济的方式在不同组织中表达复杂的、有生物学活性的重组蛋白质。构建动物反应器,最重要的就是构建出能高效表达的载体。该就出现的各种表达重组蛋白质的系统进行了比较,并对转基因动物的产生、转基因的表达、转录区域的优化及其将来的前景作介绍。     

植物口服疫苗的动物和临床实验*

利用转基因植物生产亚单位疫苗用于口服主动免疫具有安全、廉价和方便等优点。植物可以正确地表达细菌和病毒抗原基因,对动物及人类的临床实验研究表明：食用表达某种抗原的转基因植物可在实验动物或人群体内激起系统免疫和粘膜免疫,产生相应的特异性抗体,这些结果表明了植物口服疫苗的可行性。此外,在治疗自身免疫疾病以及癌症等方面,植物口服疫苗也具有值得关注的作用。     

Main Strategies of Plant Expression System Glycoengineering for Producing Humanized Recombinant Pharmaceutical Proteins

Most the pharmaceutical proteins are derived not from their natural sources, rather their recombinant analogs are synthesized in various expression systems. Plant expression systems, unlike mammalian cell cultures, combine simplicity and low cost of procaryotic systems and the ability for posttranslational modifications inherent in eucaryotes. More than 50% of all human proteins and more than 40% of the currently used pharmaceutical proteins are glycosylated, that is, they are glycoproteins, and their biological activity, pharmacodynamics, and immunogenicity depend on the correct glycosylation pattern. This review examines in detail the similarities and differences between N- and O–glycosylation in plant and mammalian cells, as well as the effect of plant glycans on the activity, pharmacokinetics, immunity, and intensity of biosynthesis of pharmaceutical proteins. The main current strategies of glycoengineering of plant expression systems aimed at obtaining fully humanized proteins for pharmaceutical application are summarized.     

GMP issues for recombinant plant-derived pharmaceutical proteins

Recombinant proteins can be produced in a diverse array of plant-based systems, ranging from whole plants growing in the soil to plant suspension cells growing in a fully-defined synthetic medium in a bioreactor. When the recombinant proteins are intended for medical use (plant-derived pharmaceutical proteins, PDPs) they fall under the same regulatory guidelines for manufacturing that cover drugs from all other sources, and when such proteins enter clinical development this includes the requirement for production according to good manufacturing practice (GMP). In principle, the well-characterized GMP regulations that apply to pharmaceutical proteins produced in bacteria and mammalian cells are directly transferrable to plants. In practice, the cell-specific terminology and the requirement for a contained, sterile environment mean that only plant cells in a bioreactor fully meet the original GMP criteria. Significant changes are required to adapt these regulations for proteins produced in whole-plant systems and it is only recently that the first GMP-compliant production processes using plants have been delivered.     

The production of biopharmaceuticals in plant systems

Biopharmaceuticals present the fastest growing segment in the pharmaceutical industry, with an ever widening scope of applications. Whole plants as well as contained plant cell culture systems are being explored for their potential as cheap, safe, and scalable production hosts. The first plant-derived biopharmaceuticals have now reached the clinic. Many biopharmaceuticals are glycoproteins; as the Golgi N-glycosylation machinery of plants differs from the mammalian machinery, the N-glycoforms introduced on plant-produced proteins need to be taken into consideration. Potent systems have been developed to change the plant N-glycoforms to a desired or even superior form compared to the native mammalian N-glycoforms. This review describes the current status of biopharmaceutical production in plants for industrial applications. The recent advances and tools which have been utilized to generate glycoengineered plants are also summarized and compared with the relevant mammalian systems whenever applicable.     

Bioreactor systems for in vitro production of foreign proteins using plant cell cultures

Plant cells have been demonstrated to be an attractive heterologous expression host (using whole plants and in vitro plant cell cultures) for foreign protein production in the past 20years. In recent years in vitro liquid cultures of plant cells in a fully contained bioreactor have become promising alternatives to traditional microbial fermentation and mammalian cell cultures as a foreign protein expression platform, due to the unique features of plant cells as a production host including product safety, cost-effective biomanufacturing, and the capacity for complex protein post-translational modifications. Heterologous proteins such as therapeutics, antibodies, vaccines and enzymes for pharmaceutical and industrial applications have been successfully expressed in plant cell culture-based bioreactor systems including suspended dedifferentiated plant cells, moss, and hairy roots, etc. In this article, the current status and emerging trends of plant cell culture for in vitro production of foreign proteins will be discussed with emphasis on the technological progress that has been made in plant cell culture bioreactor systems.     

Molecular farming of pharmaceutical proteins

Molecular farming is the production of pharmaceutically important and commercially valuable proteins in plants. Its purpose is to provide a safe and inexpensive means for the mass production of recombinant pharmaceutical proteins. Complex mammalian proteins can be produced in transformed plants or transformed plant suspension cells. Plants are suitable for the production of pharmaceutical proteins on a field scale because the expressed proteins are functional and almost indistinguishable from their mammalian counterparts. The breadth of therapeutic proteins produced by plants range from interleukins to recombinant antibodies. Molecular farming in plants has the potential to provide virtually unlimited quantities of recombinant proteins for use as diagnostic and therapeutic tools in health care and the life sciences. Plants produce a large amount of biomass and protein production can be increased using plant suspension cell culture in fermenters, or by the propagation of stably transformed plant lines in the field. Transgenic plants can also produce organs rich in a recombinant protein for its long-term storage. This demonstrates the promise of using transgenic plants as bioreactors for the molecular farming of recombinant therapeutics, including vaccines, diagnostics, such as recombinant antibodies, plasma proteins, cytokines and growth factors. This revised version was published online in August 2006 with corrections to the Cover Date.     

Current achievements in the production of complex biopharmaceuticals with moss bioreactors

Transgenic plants are promising alternatives for the low-cost and safe pathogen-free production of complex recombinant pharmaceutical proteins (molecular farming). Plants as higher eukaryotes perform posttranslational modifications similar to those of mammalian cells. However, plant-specific protein N-glycosylation was shown to be immunogenic, a fact that represents a drawback for many plant systems in biopharmaceutical production. The moss Physcomitrella patens offers unique properties as a contained system for protein production. It is grown in the predominant haploid gametophytic stage as tissue suspension cultures in photobioreactors. Efficient secretory signals and a transient transfection system allow the secretion of freshly synthesized proteins to the surrounding medium. The key advantage of Physcomitrella compared to other plant systems is the feasibility of targeted gene replacements. By this means, moss strains with non-immunogenic humanized glycan patterns were created. Here we present an overview of the relevant aspects for establishing moss as a production system for recombinant biopharmaceuticals.     

Advances in plant molecular farming

Plant molecular farming (PMF) is a new branch of plant biotechnology, where plants are engineered to produce recombinant pharmaceutical and industrial proteins in large quantities. As an emerging subdivision of the biopharmaceutical industry, PMF is still trying to gain comparable social acceptance as the already established production systems that produce these high valued proteins in microbial, yeast, or mammalian expression systems. This article reviews the various cost-effective technologies and strategies, which are being developed to improve yield and quality of the plant-derived pharmaceuticals, thereby making plant-based production system suitable alternatives to the existing systems. It also attempts to overview the different novel plant-derived pharmaceuticals and non-pharmaceutical protein products that are at various stages of clinical development or commercialization. It then discusses the biosafety and regulatory issues, which are crucial (if strictly adhered to) to eliminating potential health and environmental risks, which in turn is necessary to earning favorable public perception, thus ensuring the success of the industry.     

Transient protein expression systems in plants and their applications

The production of recombinant proteins is important in academic research to identify protein functions. Moreover, recombinant enzymes are used in the food and chemical industries, and high-quality proteins are required for diagnostic, therapeutic, and pharmaceutical applications. Though many recombinant proteins are produced by microbial or mammalian cell-based expression systems, plants have been promoted as alternative, cost-effective, scalable, safe, and sustainable expression systems. The development and improvement of transient expression systems have significantly reduced the period of protein production and increased the yield of recombinant proteins in plants. In this review, we consider the importance of plant-based expression systems for recombinant protein production and as genetic engineering tools.     

转基因植物生产药用蛋白的研究进展

利用转基因植物作为生物反应器生产具有重要价值的多肽和蛋白质,包括抗体、疫苗、药用蛋白等较之其他生产系统具有很多优越性,已成为当前植物医药基因工程和药物生物技术领域中的研究热点,本文着重就这一领域近年采国内外的研究现状、发展趋势以及目前存在的问题及对策进行综述。