Transformed root cultures for biotechnology

This review is concerned with the application of hairy roots, i.e. plant roots formed from plant cells after transformation by Agrobacterium rhizogenes for the production of bioactive compounds. Transformed root cultures have been established from numerous species of dicotyledonous plants. The plants, as well as the main products accumulated in hairy root cultures derived from these plants, are listed in this paper. Data are presented on novel compounds, hitherto detected only in transformed roots but not occurring in the corresponding intact plants. The possible use of hairy root cultures for the over-production of secondary metabolites and biotransformation of chemicals is discussed. In order to enhance the productivity of hairy root cultures, various methods have been derived, and optimized procedures are proposed. They include selection of high-producing clones, elicitation, composition of growth media, culture conditions and genetic approach. Hairy roots usually store secondary metabolites in vacuoles inside the cells. Therefore, several methods have been used to increase the amount of products released into the medium. Unfortunately, no general procedure is known that works in all cases, and the excretion behaviour of hairy root cultures varies from one species to another and even within one species from one clone to another. Special attention is given to the cultivation methods and bioreactor systems for hairy root cultures. Hairy roots are cultivated usually in shake flasks; however, shake flask culture is not suitable for the complex optimization and continuous control of the culture conditions. In this paper, we are going to present bioreactors proposed for the cultivation of hairy roots under more or less controlled conditions. Modifications of typical bacterial bioreactors, i.e. stirred tanks, airlift loop reactors and other constructions, are presented. A very special type of bioreactor providing good conditions for loose root mass multiplication without oxygen or substrate limitations, is the mist bioreactor. Nowadays, it is practically impossible to select the one best bioreactor type for hairy root culture.     

Production of biomass and useful compounds from adventitious roots of high-value added medicinal plants using bioreactor

The increasing global demand for biomass of medicinal plant resources reflects the issues and crisis created by diminishing renewable resources and increasing consumer populations. Moreover, diverse usage of plants and reduced land for cultivation in the world accelerated the deficiency of plant resources. In addition, the preparation of safety of plant based medicine whips up demand for biomass of valuable medicinal plants. As one of alternative approach to upswing the productivity of plant-based pharmaceutical compounds, automation of adventitious root culture system in air-lift bioreactor was adopted to produce cosmic amount of root biomass along with enriched diverse bioactive molecules. In this review, various physiological, engineering parameters, and selection of proper cultivation strategy (fed-batch, two-stage etc.) affecting the biomass production and secondary metabolite accumulation have been discussed. In addition, advances in adventitious root cultures including factors for process scale-up as well as recent research aimed at maximizing automation of the bioreactor production processes are also highlighted. Examples of the scale-up of cultures of adventitious roots of Morinda citrifolia, Echinacea purpurea and angustifolia, Hypericum perforatum and Panax ginseng by applying 20L to 10,000L bioreactors in our lab were demonstrated with a view of commercial application.     

A novel life cycle arising from leaf segments in plants regenerated from horseradish hairy roots

Summary Horseradish (Armoracia rusticana) hairy root clones were established from hairy roots which were transformed with the Ri plasmid in Agrobacterium rhizogenes 15834. The transformed plants, which were regenerated from hairy root clones, had thicker roots with extensive lateral branches and thicker stems, and grew faster compared with non-transformed horseradish plants. Small sections of leaves of the transformed plants generated adventitious roots in phytohormone-free G (modified Gamborg's) medium. Root proliferation was followed by adventitious shoot formation and plant regeneration. Approximately twenty plants were regenerated per square centimeter of leaf. The transformed plants were easily transferable from sterile conditions to soil. When leaf segments of the transformed plants were cultured in a liquid fertilizer under non-sterile conditions, adventitious roots were generated at the cut ends of the leaves. Adventitious shoots were generated at the boundary between the leaf and the adventitious roots and developed into complete plants. This novel life cycle arising from leaf segments is a unique property of the transformed plants derived from hairy root clones.     

Ri质粒介导的毛状根体系建立及其在植物次生代谢产物合成中的研究进展

发根农杆菌Ri质粒可诱导植物产生毛状根体系,该体系具有遗传性状稳定且增殖速度快的特点,可用于药用植物次生代谢产物的生产研究,为利用生物反应器技术进行药用植物有效成分工业化水平的发酵培养开辟了新途径。本文主要综述了发根农杆菌Ri质粒介导的植物毛状根体系遗传转化机理,并对毛状根体系在药用植物次生代谢产物生产中的研究现状进行了深入分析,为从基因水平上调控植物次生代谢产物的合成提供新思路。     

Biosafe Ginseng: A Novel Source for Human Well‐Being

Given the enormous biodiversity in field cultivation, bioengineers were only to look within nature to find new promising phytomolecules or biochemical pathways from plant biofactories. The present review discusses pilot‐scale bioreactor cultivation of adventitious roots of ginseng and the enhanced production of pesticide‐free bioactive phytomolecules. This biotechnological method is described together with a discussion on economic and biosafety aspects. Besides the “classical” tissue culture as a subject of research on ginseng, new developments and efforts in pilot‐scale bioreactor tissue modeling and in the generation of artificial adventitious roots are considered. Additionally, recent progress in the field of medicinal and nutritional roles of adventitious roots produced in a pilot‐scale bioreactor are discussed.     

Transgenic hairy roots. recent trends and applications

Agrobacterium rhizogenes causes hairy root disease in plants. The neoplastic roots produced by A. rhizogenes infection is characterized by high growth rate and genetic stability. These genetically transformed root cultures can produce higher levels of secondary metabolites or amounts comparable to that of intact plants. Hairy root cultures offer promise for production of valuable secondary metabolites in many plants. The main constraint for commercial exploitation of hairy root cultures is their scaling up, as there is a need for developing a specially designed bioreactor that permits the growth of interconnected tissues unevenly distributed throughout the vessel. Rheological characteristics of heterogeneous system should also be taken into consideration during mass scale culturing of hairy roots. Development of bioreactor models for hairy root cultures is still a recent phenomenon. It is also necessary to develop computer-aided models for different parameters such as oxygen consumption and excretion of product to the medium. Further, transformed roots are able to regenerate genetically stable plants as transgenics or clones. This property of rapid growth and high plantlet regeneration frequency allows clonal propagation of elite plants. In addition, the altered phenotype of hairy root regenerants (hairy root syndrome) is useful in plant breeding programs with plants of ornamental interest. In vitro transformation and regeneration from hairy roots facilitates application of biotechnology to tree species. The ability to manipulate trees at a cellular and molecular level shows great potential for clonal propagation and genetic improvement. Transgenic root system offers tremendous potential for introducing additional genes along with the Ri T-DNA genes for alteration of metabolic pathways and production of useful metabolites or compounds of interest. This article discusses various applications and perspectives of hairy root cultures and the recent progress achieved with respect to transformation of plants using A. rhizogenes.     

Agrobacterium rhizogenes-mediated transformation of Taraxacum platycarpum and changes of morphological characters

Transformed hairy roots were efficiently induced from seedlings of Taraxacum platycarpum by infection with Agrobacterium rhizogenes 15834. Root explants produced transformed roots at a higher frequency (76.5±3.5%) as compared to stem (32.7±4.8%) or cotyledon (16.2±5.7%). Hairy roots exhibited active elongation with high branching of roots on growth regulator-free medium. The competence of plant regeneration from non-transformed adventitious roots and transformed hairy roots was compared. The frequency of adventitious shoot formation from transformed roots was much higher (88.5±9.8%) than that of non-transformed roots (31.7 ±9.5%) on hormone-free medium. Rooting of hairy root-derived adventitious shoots occurred easily on growth regulator-free medium but no rooting was observed on non-transformed shoots. The stable introduction of rol genes into Taraxacum plants was confirmed by PCR and Southern hybridization. Transgenic plantlets showed considerable differences in their morphology when compared to the corresponding wild-type (non-transgenic) plants. Plantlets formed from transformed roots had numerous fibrous roots with abundant lateral branches instead of the thickened taproots in non-transformed plants. The differences observed may reflect the modification of morphological root characters by introduction of rol genes.Communicated by M.R. Davey     

Hairy root research: recent scenario and exciting prospects

High stability of the production of secondary metabolites is an interesting characteristic of hairy root cultures. For 25 years, hairy roots have been investigated as a biological system for the production of valuable compounds from medicinal plants. A better understanding of the molecular mechanism of hairy root development, which is based on the transfer of Agrobacterium rhizogenes T-DNA into the plant genome, has facilitated its increasing use in metabolic engineering. Hairy roots can also produce recombinant proteins from transgenic roots, and thereby hold immense potential for the pharmaceutical industry. In addition, hairy roots offer promise for phytoremediation because of their abundant neoplastic root proliferation. Recent progress in the scaling-up of hairy root cultures is making this system an attractive tool for industrial processes.     

纤维植物罗布麻发根的诱导及植株再生

利用3种发根农杆菌(LBA9402.R601,和R1000)转化纤维植物罗布麻无菌种子苗的根茎叶不同外植体部位,首次诱导其生成发根并实现了直接由发根途径的植株再生.罗布麻发根诱导与所用的发根农杆菌菌株,外植体部位及光周期密切相关.发根农杆菌LBA9402感染罗布麻的根外植体,实现了最高转化率达100%.与LBA9402及R601相比,被发根农杆菌R1000感染的根外植体适合在黑暗环境下培养.其诱导生成的发根密度可达平均每个外植体22条.在不加激素的1/2 MS培养基上,LBA9402和R601诱导产生的发根可以诱导生成不定芽,不定芽诱导率达20%.不定芽切下后,在不加激素的1/2 MS培养基上2周内可以诱导生根.通过聚合酶链式反应(PCR)对发根及再生植株进行了鉴定,证明发根农杆菌的T-DNA插入了植物的基因组.为罗布麻的分子育种建立了稳定的转化及再生体系,为下一步通过转入外源基因改善其农艺性状奠定了基础.     

Regeneration of horseradish hairy roots incited by Agrobacterium rhizogenes infection

Surface-sterilized leaf disks of horse-radish (Armoracia lapathifolia) were immersed in a suspension of Agrobacterium rhizogenes harboring the root-inducing plasmid (pRi) and cultured on a solid medium. Within about 10 days after inoculation, adventitious roots (hairy roots) emerged from the leaf disks. No roots emerged from the uninoculated leaf disks. The excised hairy roots grew vigorously in the dark and exhibited extensive lateral branches in the absence of phytohormones. When the hairy roots were moved into the light, numerous adventitious buds thrust out of the roots within about 10 days, and they developed into complete plants (R0 generation). R0 plants revealed leaf wrinkle. Root masses of cultured R0 plants were of two types. One had fibrous roots only and the other had both fibrous and tuberous roots Leaf disks of the R0 plants proliferated adventitious roots (R1 generation) on a solid medium after 1–2 weeks of culture. Phenotypical characters of the R1 roots were the same as those observed with the initial hairy roots. The T-DNA sequences of pRi were detected within DNA isolated from the hairy roots and their regenerants.     

生物技术在传统药材生产中的应用前景

生物技术在传统药材生产中的应用前景刘涤胡之璧（上海中医药大学中药生物工程研究室,上海２０００３２）我国的中药材是一个具有数千年历史的医药宝库,至今仍在中国和许多国家和地区广为使用。传统药材中,８０％为野生资源,但由于盲目挖掘,不仅使野生资源日益减少,而且严重破坏了自然界的生态平衡;人工种植又面临品质退化,农药污染和种子带病等问题。而且,人工种植的药材,活性成分的种类和数量往往因地区及气候不同...     

Production and metabolic engineering of bioactive substances in plant hairy root culture

In the past three decades, hairy roots research for the production of valuable biological active substances has received a lot of attention. The addition of knowledge to enhance the yields of desired substances and the development of novel tools for biomass engineering offer new possibilities for large-scale cultivation of the plant hairy root. Hairy roots can also produce recombinant proteins through the transfer of Agrobacterium T-DNA into the plant genome, and thereby hold immense potential for the pharmaceutical industry. This review highlights some of the significant progress made in the past few years and outlines future prospects for exploiting the potential utility of hairy root cultures as “chemical factories” for producing bioactive substances.     

广藿香毛状根多倍体诱导及其植株再生

为了提高药用植物广藿香的次生物质广藿香醇含量,采用秋水仙素人工诱导染色体加倍技术,进行了广藿香毛状根多倍体诱导及其植株再生、倍性鉴定和挥发油组分广藿香醇含量的测定。结果表明,广藿香毛状根多倍体诱导的最佳条件为0.05%秋水仙素处理36 h,其多倍体诱导率可达40%以上;经秋水仙素加倍的广藿香毛状根在MS+6-BA 0.2 mg/L+NAA 0.1 mg/L培养基中培养60 d后可获得毛状根多倍体再生植株。与对照(二倍体植株)相比,广藿香毛状根多倍体再生植株根系更发达、茎更粗、节间变短、叶片的长度、宽度和厚度均较二倍体明显增大。根尖细胞染色体压片观察证实,所获得的广藿香毛状根多倍体再生植株为四倍体,其根尖细胞染色体数约为128;同时,其叶片的气孔保卫细胞体积及其叶绿体数目均约为对照的两倍;但其气孔密度则随着倍性增加而下降,二倍体植株叶片的气孔密度约为四倍体植株叶片的1.67倍。GC-MS测定结果表明,广藿香毛状根多倍体再生植株的广藿香挥发油组分广藿香醇的含量为4.25 mg/g干重,约为二倍体植株的2.30倍。该结果证实毛状根多倍体化可提高药用植物广藿香的广藿香醇含量。     

Tanshinone biosynthesis in Salvia miltiorrhiza and production in plant tissue cultures

Salvia miltiorrhiza Bunge (Lamiaceae) root, generally called Danshen, is an important herb in Chinese medicine widely used for treatment of cardiovascular diseases. Diterpenoid tanshinons are major bioactive constituents of Danshen with notable pharmacological activities and the potential as new drug candidates against some important human diseases. The importance of Danshen for traditional and modern medicines has motivated the research interest over two decades in the biosynthesis and biotechnological production of tanshinones. Although diterpenes in plants are presumably derived from the non-mevalonate (MVA) pathway, tanshinone biosynthesis in S. miltiorrhiza may also depend on the MVA pathway based on some key enzymes and genes detected in the early steps of these pathways. Plant tissue cultures are the major biotechnological processes for rapid production of tanshinones and other bioactive compounds in the herb. Various in vitro cultures of S. miltiorrhiza have been established, including cell suspension, adventitious root, and hairy root cultures, which can accumulate the major tanshinones as in the plant roots. Tanshinone production in cell and hairy root cultures has been dramatically enhanced with various strategies, including medium optimization, elicitor stimulation, and nutrient feeding operations. This review will summarize the above developments and also provide our views on future trends.     

MALDI‐TOF characterization of hGH1 produced by hairy root cultures of Brassica oleracea var. italica grown in an airlift with mesh bioreactor

Expression systems based on plant cells, tissue, and organ cultures have been investigated as an alternative for production of human therapeutic proteins in bioreactors. In this work, hairy root cultures of Brassica oleracea var. italica (broccoli) were established in an airlift with mesh bioreactor to produce isoform 1 of the human growth hormone (hGH1) as a model therapeutic protein. The hGH1 cDNA was cloned into the pCAMBIA1105.1 binary vector to induce hairy roots in hypocotyls of broccoli plantlets via Agrobacterium rhizogenes. Most of the infected plantlets (90%) developed hairy roots when inoculated before the appearance of true leaves, and keeping the emerging roots attached to hypocotyl explants during transfer to solid Schenk and Hildebrandt medium. The incorporation of the cDNA into the hairy root genome was confirmed by PCR amplification from genomic DNA. The expression and structure of the transgenic hGH1 was assessed by ELISA, western blot, and MALDITOF‐MS analysis of the purified protein extracted from the biomass of hairy roots cultivated in bioreactor for 24 days. Production of hGH1 was 5.1 ± 0.42 µg/g dry weight (DW) for flask cultures, and 7.8 ± 0.3 µg/g DW for bioreactor, with productivity of 0.68 ± 0.05 and 1.5 ± 0.06 µg/g DW*days, respectively, indicating that the production of hGH1 was not affected by the growth rate, but might be affected by the culture system. These results demonstrate that hairy root cultures of broccoli have potential as an alternative expression system for production of hGH1, and might also be useful for production of other therapeutic proteins. © 2013 American Institute of Chemical Engineers Biotechnol. Prog., 30:161–171, 2014     

Hairy root type plant in vitro systems as sources of bioactive substances

“Hairy root” systems, obtained by transforming plant tissues with the “natural genetic engineer” Agrobacterium rhizogenes, have been known for more than three decades. To date, hairy root cultures have been obtained from more than 100 plant species, including several endangered medicinal plants, affording opportunities to produce important phytochemicals and proteins in eco-friendly conditions. Diverse strategies can be applied to improve the yields of desired metabolites and to produce recombinant proteins. Furthermore, recent advances in bioreactor design and construction allow hairy root-based technologies to be scaled up while maintaining their biosynthetic potential. This review highlights recent progress in the field and outlines future prospects for exploiting the potential utility of hairy root cultures as “chemical factories” for producing bioactive substances.     

香石竹毛状根诱导、离体培养及其植株再生

为了探讨利用发根农杆菌遗传转化所产生的毛状根来创新香石竹种质的可能性,本文采用叶盘法,建立了发根农杆菌Agrobacterium rhizogenes对香石竹Dianthus caryophyllus L.叶片外植体的遗传转化及其植株再生体系。结果表明,发根农杆菌ATCC15834感染香石竹幼嫩叶片外植体12 d后,从叶片外植体切口中脉处产生白色毛状根,21 d后约90%的叶片外植体产生毛状根。所获得的无菌毛状根能在无外源激素的MS固体和液体培养基中快速自主生长。PCR扩增和硅胶薄层层析结果显示发根农杆菌Ri质粒的rol B和rol C基因以及冠瘿碱合成酶基因已在香石竹毛状根基因组中整合并得到表达。将毛状根置于MS+6-BA 1.0-3.0 mg/L+NAA 0.1-0.2 mg/L中培养15 d后产生淡黄绿色的疏松愈伤组织。愈伤组织不定芽分化的最适培养基为MS+6-BA 2.0 mg/L+NAA 0.02 mg/L,培养6周后不定芽分化率为100%;平均每个愈伤组织产生30-40个不定芽;将不定芽转至1/2 MS或1/2 MS+0.5 mg/L NAA的培养基中10 d后产生不定根,发育成再生植株。再生植株移植于栽培基质中20 d后,成活率达95%以上。     

Design of bioreactors suitable for plant cell and tissue cultures

Plant cell suspension cultures and hairy roots are potential sources of secondary metabolites and recombinant proteins. In contrast to traditionally grown “whole wild plants” or “whole transgenic plants”, their production in bioreactors guarantees defined controlled process conditions and therefore minimizes or even prevents variations in product yield and quality, which simplifies process validation and product registration. Moreover, bioreactors and their configuration significantly affect cultivation results by accomplishing and controlling the optimum environment for effective cell growth and production of bioactive substances. This review highlights the main design criteria of the most widely used bioreactor types, both for plant cell suspension cultures and for hairy roots, and outlines suitable low-cost disposable bioreactors which have found increasing acceptance over the last 10 years. Plants for human health in the post-genome era, PSE congress 26.8.2007–29.8.2007, Helsinki.     

Plant Hairy Roots for Remediation of Aqueous Pollutants

Significant progress has been made in recent years in enhancing the ability of plants to tolerate, remove, and degrade pollutants. Plant root remediation of contaminated soils and groundwater shows great potential for future development due to its environmental compatibility and cost-effectiveness. Hairy roots are disease manifestations developed by plants that are wounded and infected by Agrobacterium rhizogenes. The application of transgenic hairy roots in phytoremediation has been suggested mainly because of their biochemical resemblance to the roots of the plant from which they are derived. The application of genetic engineering has greatly augmented removal rates of hazardous pollutants. In addition, the rhizospheric bacteria that live on or around plant hairy roots also lead to improved tolerance to normally phytotoxic chemicals and increased removal of pollutants. This paper provides a broad overview of the evidence supporting the suitability and prospects of hairy roots in phytoremediation of organic pollutants and heavy metals.