A fluidised bed vessel for the culture of immobilised plant cells and its application for the continuous production of fine cell suspensions

With the expansion of immobilised plant cell technology the need has arisen for a suitable vessel in which systems can be efficiently manipulated.Described is a vessel which incorporates many of the features of a fluidised bed, together with some of those from airlift technology to enable immobilised plant cells to be cultured at high biomass concentrations while maintaining a high mass transfer and controlled aeration under continuous flow conditions. In the case described, the vessel has been used for the continuous production of fine plant cell suspensions, although it is easily adaptable for use in cell mediated biotransformation or de novo synthesis studies.Abbreviations 2,4D 2.4 dichlorophenoxyacetic acid     

药用植物细胞生物反应器技术的研究进展

利用植物细胞生物反应器技术生产植物有用代谢产物,近些年来取得了很大发展,但植物细胞悬浮培养的工业化应用仍受到来自生物及工程技术上的限制。针对植物细胞生物反应器技术的特点及其研究进展,提出在综合考虑生物学和工艺学两方面的基础上,选育药用植物稳定高产的优良细胞系是提高植物细胞生物反应器技术可行性的关键。     

Plant tissue culture. Biotechnology. Milestones

Summary The progress in the development of the technologies of plant tissue and cell culture over the past four decades has been remarkable. This article covers my personal reflections on the various topics and is based on my involvement in the field during that period. There are three fundamental technologies which constitute most of what is referred to as plant in vitro technologies or tissue culture. The origin and some of the key persons involved in the development of each of these procedures will be discussed. The technology that is most common is growing plant tissue on gel-solidified nutrient media. That technology is being used in the most vital procedures, namely the regeneration of plants from cultured cells. The culture of plant cells in liquid suspension was developed very shortly after that, and has become a very effective technology for plant regeneration by somatic embryogenesis. The method of meristem culture arose out of a need for developing plants that were virus-free. In many species the technique is now being used to produce virus-free crop plants. Another important technology is the culture of anthers and microspores for producing haploid and homozygous plants. Included with plant tissue culture is the development of the plant protoplast and cell fusion technologies for the production of new plant hybrids. The final aspect of the development concerns the integration of tissue culture with molecular genetics, which has developed into the rapidly expanding field of biotechnology.     

Production of anthocyanins by plant cell cultures

Anthocyanins, responsible for the various attractive colors in plants, are becoming important alternative to many synthetic colorants due to increased public concerns over the safety of artificial food colors. Production of anthocyanins by plant cell cultures has been suggested as a feasible technology that has attracted considerable industrial and academic interests in the past two decades. This paper is to provide an overview of the present status and the future prospects in the commercial development of plant cell cultures for production of anthocyanins. The focus is on the strategies for enhancement of anthocyanin biosynthesis to achieve an economically viable technology for commercial applications. Through strain improvement, optimization of media and culture conditions, and intelligent process strategies such as elicitation and two-stage system, significant enhancement in productivity has been achieved in a number of cultures. However the yield of anthocyanins obtained so far is still far away from the full potential of anthocyanin synthesis by plant cell cultures. Further improvements require the insights on the regulation of anthocyanin synthesis, accumulation, storage and breakdown that will eventually lead to genetic manipulation of anthocyanin biosynthesis. Many studies have elucidated the metabolic pathway of anthocyanin biosynthesis. Preliminary studies on the regulation of anthocyanin biosynthesis on the levels of genes and enzymes are reviewed, showing that it is feasible to clone genes from secondary metabolism with an improved yield of anthocyanins. There is currently no commercial-scale trial for production of anthocyanin by plant cell cultures, but an intelligent integration of those existing strategies could provide a technology for industrial application competitive to the current production methods.     

3D-SIM结构照明超分辨率显微镜实现蛋白质在植物亚细胞器内的定位

基因表达产物蛋白质的亚细胞定位是解析基因生物学功能的重要证据之一。近年来出现的超分辨率光学成像技术已成功应用于人类和动物细胞中,预示着显微成像技术继激光共聚焦技术后的又一重要进步。由于植物细胞的特殊性和成像技术的研发取向,超分辨率光学成像技术在植物细胞蛋白质亚细胞定位的应用尚未见报道。该研究利用Delta Vision OMX显微镜技术,克服了叶绿体基粒中叶绿素自发荧光与融合蛋白荧光不易区分的缺陷,解决了受分辨率局限无法将植物细胞中蛋白质在亚细胞器内可视化精确定位的技术难题,成功地将植物蔗糖合成酶Zm SUS-SH1定位在烟草表皮细胞叶绿体基粒周围。该研究同时建立了一套基于撕片制片法的简便OMX显微镜制片方法,并针对OMX显微成像技术在植物细胞中蛋白质亚细胞定位的应用进行了讨论。     

SOMACLONAL AND GAMETOCLONAL VARIATION

For several years it has been recognized that introduction of plant cells into culture results in genetic changes. These genetic alterations have been recovered in the plants regenerated from cell cultures. More recently it has been recognized that this method of introducing genetic changes into crop plants could be used to develop new breeding lines. The technology of introducing genetic variation by using cell culture has been termed somaclonal and gametoclonal variation. This paper reviews the history of this technology and offers genetic documentation of somaclonal variation in tomato. As this variation represents a new tool for the plant breeder, breeding strategies for the use of this variation are presented and discussed. Somaclonal and gametoclonal variation are new tools for the geneticist and plant breeder that permit reduction in the time period for new variety development and that permit access to new classes of genetic variation.     

Foreign protein production using plant cell and organ cultures: Advantages and limitations

Plants and plant tissue cultures are used as host systems for expression of foreign proteins including antibodies, vaccines and other therapeutic agents. Recombinant or stably transformed plants and plant cell cultures have been applied for foreign protein production for about 20 years. Because the product concentration achieved exerts a major influence on process economics, considerable efforts have been made by commercial and academic research groups to improve foreign protein expression levels. However, post-synthesis product losses due to protease activity within plant tissues and/or extracellular protein adsorption in plant cell cultures can negate the benefits of molecular or genetic enhancement of protein expression. Transient expression of foreign proteins using plant viral vectors is also a practical approach for producing foreign proteins in plants. Adaptation of this technology is required to allow infection and propagation of engineered viruses in plant tissue cultures for transient protein expression in vitro.     

CRISPR/Cas9-mediated gfp gene inactivation in Arabidopsis suspension cells

Molecular Biology Reports - Targeted genome editing using CRISPR/Cas9 is a promising technology successfully verified in various plant species; however, it has hardly been used in plant cell...     

植物细胞生物反应器培养的研究进展(I)

利用植物细胞大规模悬浮培养生产植物有用代谢产物在近些年来取得了很大发展,但植物细胞悬浮培养的工业化应用受到来自生物及工程技术上的限制.本文针对植物细胞培养的基本特点,详细讨论了与大规模生产有关的工程技术方面的问题,如植物细胞聚集、溶氧及气体成分、流体性能、剪切力对植物细胞培养产生的影响.     

植物细胞生物反应器培养的研究进展(I)

利用植物细胞大规模悬浮培养生产植物有用代谢产物在近些年来取得了很大发展,但植物细胞悬浮培养的工业化应用受到来自生物及工程技术上的限制。本文针对植物细胞培养的基本特点,详细讨论了与大规模生产有关的工程技术方面的问题,如植物细胞聚集、溶氧及气体成分、流体性能、剪切力对植物细胞培养产生的影响。     

New trends in biotechnological production of rosmarinic acid

Rosmarinic acid (RA), an ester of caffeic acid and 3,4-dihydroxyphenyl lactic acid, is widely distributed in the plant kingdom. Interest in it is growing due to its promising biological activities, including cognitive-enhancing effects and slowing the development of Alzheimer’s disease, cancer chemoprotection or anti-inflammatory activity, among others. In order to meet the increasing demand for this compound, several biotechnological approaches to its production based on plant cell and hairy root cultures have been developed. Empirical strategies are currently being combined with metabolic engineering tools to increase RA production in plant cell platforms in a more rational way. Discussed here are the latest advances in the field, together with recent trends in plant biotechnology, such as the application of single use technology and the use of biosensors in downstream processes.     

Metabolic engineering of plants for alkaloid production.

Alkaloids purified from plants provide many pharmacologically active compounds, including leading chemotherapy drugs. As is generally true of secondary metabolites, overall productivity is low, making commercial production expensive. Alternative production methods remain impractical, leaving the plant as the best source for these valuable chemicals. Recently, significant progress in characterizing the biosynthetic pathways leading to various alkaloids has been made, and a number of relevant genes have been cloned. Metabolic engineering employing such genes provides a promising technology for improved productivity in plant cell cultures, plant tissue cultures, or intact plants. In exploring solutions though, metabolic engineers must be careful to recognize the limitations inherent in designing plant systems.     

TOPICAL PAPER: Utilization of Hairy Root Cultures for Production of Secondary Metabolites

The possibility of producing useful chemicals by plant cell cultures has been studied intensively for the past 30 years. However, problems associated with low product yields and culture instabilities have restricted wider industrial application of plant cell culture. The employment of hairy root culture technology, developed in the past 10 years, offers new opportunities for in vitro production of plant secondary metabolites. In contrast to cell suspension cultures, hairy root cultures are characterized by high biosynthetic capacity and genetic as well as biochemical stability. In this review, the establishment and cultivation of hairy root cultures as well as their properties and application for production of secondary metabolites are discussed.     

The production of pyrethrins by plant cell and tissue cultures of Chrysanthemum cinerariaefolium and Tagetes species

Pyrethrins, the most economically important natural insecticide, comprise a group of six closely related monoterpene esters. The industrial production is based on their extraction from Chrysanthemum cinerariaefolium (Pyrethrum) capitula. The world production of natural pyrethrins still falls short of global market demand stimulating the research in in vitro production as an alternative to conventional cultivation methods. The different biotechnological alternatives such as callus cultures, shoot and root cultures, plant cell suspension cultures, and bioconversion of precursors by means of enzymatic synthesis or genetically engineered microorganisms, as well as the progress achieved in methods for the identification and quantitation of insecticidal compounds have been reviewed. Although technology for plant cell culture exists, industrial applications have, to date, been limited due to both the low economical viability and technological feasibility at large scale. Bioconversion of readily available precursors looks more attractive, but more research is needed before this technology is used for the industrial production of pyrethrins.     

Techniques in plant molecular biology--progress and problems

Progress in plant molecular biology has been dependent on efficient methods of introducing foreign DNA into plant cells. Gene transfer into plant cells can be achieved by either direct uptake of DNA or the natural process of gene transfer carried out by the soil bacterium Agrobacterium. Versatile gene-transfer vectors have been developed for use with Agrobacterium and more recently vectors based on the genomes of plant viruses have become available. Using this technology the expression of foreign DNA, the functional analysis of plant DNA sequences, the investigation of the mechanism of viral DNA replication and cell to cell spread, as well as the study of transposition, can be carried out. In addition, the versatility of the gene-transfer vectors is such that they may be used to isolate genes not amenable to isolation using conventional protocols. This review concentrates on these aspects of plant molecular biology and discusses the limitations of the experimental systems that are currently available.     

Be more specific! Laser-assisted microdissection of plant cells

Laser-assisted microdissection (LAM) is a powerful tool for isolating specific tissues, cell types and even organelles from sectioned biological specimen in a manner conducive to the extraction of RNA, DNA or protein. LAM, which is an established technique in many areas of biology, has now been successfully adapted for use with plant tissues. Here, we provide an overview of the processes involved in conducting a successful LAM study in plants and review recent developments that have made this technique even more desirable. We also discuss how the technology might be exploited to answer some pertinent questions in plant biology.     

pH敏感型荧光蛋白及其在植物细胞生物学中的应用

pH敏感型荧光蛋白, 即pHluorin, 是荧光强度及光谱特征随环境pH值的变化而改变的一类荧光蛋白。人们通过对密码子使用偏好和特定剪切位点的修饰, 已使pHluorin及其衍生物成功地在动物、植物和真菌细胞中正常表达, 为测量细胞内微环境pH值的变化, 并研究活细胞内依赖或导致pH变化的生理过程提供了有力工具。该文总结了目前已报道的pH敏感型荧光蛋白的种类及特性, 并对其在细胞生物学, 特别是植物细胞生物学中的应用进行了详细介绍。随着报告基因技术及检测方法的不断改进, pHluorin将在植物科学领域发挥更大的作用。     

Detection byin-situ fluorescence of short,single-copy sequences of chromosomal DNA

Short single-copy probes have been widely used in plant molecular biology. However, they have rarely been effective in plant research usingin situ hybridization techniques, possibly due to limitations imposed by the cell wall. We recently developed two fluorescencein situ hybridization protocols for the single-copy sequence detection in soybean. By enzymatically removing the cell wall, single-copy sequences as short as 1 kb were detected by probes using standard fluorescencein situ hybridization or PCR-primedin situ hybridization (PCR-PRINS). Such technology is useful for genome analysis, in plant molecular, cellular, and biotechnological research.     

植物胞质分裂发生机制

胞质分裂(cytohnesis)是指在同一细胞中在新形成的两个子核之间形成新的间隔,将母细胞一分为二的过程。胞质分裂存在于任何一种生命形式中,从单细胞的细菌到多细胞的真核生物都能进行胞质分裂。近些年由于细胞学方法的改进和研究材料增多等因素,使得对植物胞质分裂发生机制的研究取得了很大的进展。现对植物中不同类型的胞质分裂在细胞学、分子生物学方面的研究进展作一综述。