Structure and function of root-inducing (Ri) plasmids and their relation to tumor-inducing (Ti) plasmids

The abilities of Agrobacterium tumefaciens and A. rhizogenes to transform dicotyle-dons and cause crown gall and hairy root disease are caused by the presence of tumor inducing (Ti) and root inducing (Ri) plasmids. During transformation plasmid T-DNA (transferred DNA) is inserted into the plant genome. The T-region is flanked by 25 bp direct repeats, which are essential for transfer. The T-regions contain oncogenes that are expressed in the plants. Some of these code for enzymes that synthesize auxin or cytokinin. Another type, present in Ri plasmids only, appears to impose a high hormone sensitivity on the infected tissue. The T-DNA also contains genes for enzymes synthesizing opines, which the bacteria catabolize. The T-DNA transfer is initiated by the induction of genes in the virulence (vir) region of the plasmid by phenolic compounds secreted by wounded tissue. The products of the vir -genes and of chromosomal genes mediate transfer of T-DNA to the plant cells. Crown gall disease is caused by production of auxin and cytokinin by the transferred T-DNA. The T-DNA of Ri plasmids codes for at least three genes that each can induce root formation, and that together cause hairy root formation from plant tissue. Current results indicate that the products of these genes induce a potential for increased auxin sensitivity that is expressed when the transformed cells are subjected to a certain level of auxin. After this stage the transformed roots can be grown in culture without exogenous supply of hormones.     

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。     

Analysis of unique variable region of a plant root inducing plasmid, pRi1724, by the construction of its physical map and library.

Ri plasmids in Agrobacterium rhizogenes specifically induce the hairy root syndrome on various dicotyledonous plants. Its T-DNA transfer system as well as those of Ti plasmids have successfully provided the fundamental technique to introduce exogenous genes into plants. To study the Ri genome structure, we constructed a complete BamHI physical map and a lambda library of pRi1724 of A. rhizogenes strain 1724. By using these, we carried out the complete sequence of the 74-kb region between the right border of T-DNA and tra operon, which is the highly variable region (VAR) among Ri and Ti plasmids. As a result, we found three kinds of putative ABC-type transport operons, histidine utilization operon, glycerol utilization operon and two chemoreceptor genes. In addition, a virulence-related gene, tzs was located independently of the vir region.     

Improved podophyllotoxin production by transformed cultures of Linum album

Various cell and hairy root cultures of L. album were developed and analyzed for podophyllotoxin content. Transformed callus and hairy root cultures developed from infection of stem portions of in vitro-germinated L. album plant with Agrobacterium rhizogenes NCIM 5140 strain were selected on the basis of high podophyllotoxin content and growth. Based on the integration of Ri T(L)-DNA and T(R)-DNA, integration of only the ags and not the rol gene in transformed cell culture indicated fragmented integration pattern. The effect of different cultivation media and carbon source on growth and podophyllotoxin production were studied in shake-flask suspension cultures. Detailed batch growth and production kinetics with sugar consumption profile were also established. Maximum volumetric productivity of 4.40 and 2.75 mg/L per day was obtained in cell suspension and hairy root cultures, respectively.     

The Genetic Transformation of Pueraria as Medicinal Plant by Agrobacterium rhizogenes

Pueraria radix (the dried root of Pueraria plant) is known as a traditional Chinese drug. Hairy roots of Pueraria lobata (Willd.) Ohwi, P.lobata var. montana and P. phaseoloides (Roxb.) Benth. transformed by Agrobacterium rhizogenes (Riker et al .) Conn R1601 were developed directly from the surface of sterile leaves in vitro . The transformation frequency was 16.6%, 16.2% and 26.6%, respectively. All hairy roots in the three species displayed the typical phenotypes of rapid growth, highly branched and plagiotropism, and also exhibited hormone autotrophy and resistance to kanamycin.The genetic transformations were confirmed by opine paper electrophoretic analysis, rol gene PCR amplification and molecular hybridization.     

褐脉少花龙葵毛状根的诱导、培养及其澳洲茄胺的产生

利用发根农杆茵的遗传转化和液体培养技术,研究了褐脉少花龙葵(solanum nigrum L.Var.Dauciforum)毛状根的诱导和离体培养及其澳洲茄胺的产生以及液体培养过程中培养基中N源和钙的消耗变化.结果表明.发根农杆菌ATCC15834感染褐脉少花龙葵叶片外植体5 d后产生毛状根.感染25d后,约90%的叶片外植体产生毛状根.毛状根能在无外源生长调节剂的MS固体和体培养基上自主生长.PCR扩增结果显示发根农杆菌Ri质粒的rilB和rolC基因已在少花龙葵毛状根基因组中整合并得到表达.所产生的毛状根能产生药用次生物质澳洲茄胺,其含量约为非转化植株根的1.3倍,达到582.05μg/g干重.少花龙葵毛状根液体培养0-5 d内处于生长迟滞期、5-15 d为快速生长期、15d后进入生长平台期.培养基的硝态氮和铵态氮在毛状根液体培养过程中被逐渐吸收和消耗,至培养15 d时铵态氮被消耗殆尽.而硝态氮仍剩余44.7%;培养基中钙的浓度在培养过程中虽逐渐降低,但在培养25d时仍未被完全消耗,其浓度约为起始浓度的43.5%.该结果为今后设计合适的培养基来规模培养褐脉少花龙葵毛状根生产药用次生物质澳洲茄胺提供了可能性.     

Getting to the root: The role of the Agrobacterium rhizogenes rol genes in the formation of hairy roots

Agrobacterium tumefaciens and A. rhizogenes are the causative agents of the crown gall and hairy root diseases, respectively. The pathogenicity of both species is caused by an inter-kingdom transfer of DNA from the bacteria to wounded plant cells. This 'transfer-DNA' (T-DNA) contains oncogenes whose expression transforms the plant recipient cell into a rapidly dividing tumour cell. In the case of A. tumefaciens , three of these oncogenes have been shown to encode enzymes catalyzing the biosynthesis of the plant growth hormones auxin and cytokinin. Therefore, the unorganized cell division in the crown gall tumour can be largely explained by an unregulated overproduction of these plant growth regulators. In contrast, the hairy root disease is characterized by a massive growth of adventitious roots at the site of infection. Because of the similarities of the infection processes, and because A. rhizogenes and A. tumefaciens are very closely related, it has been suggested that the most important A. rhizogenes oncogenes, the so called rol genes, are also encoding proteins involved in the regulation of plant hormone metabolism. However, recent data indicate that this is not the case. Thus the rol genes have functions that most likely are different from producing mere alterations of plant hormone concentrations. This review summarizes recent results concerning the expression and function of the rol genes, and presents a model for the role of these genes, especially rolB and rolC , in the A. rhizogenes infection process.     

Terpenoid indole alkaloid production by Catharanthus roseus hairy roots induced by Agrobacterium tumefaciens harboring rol ABC genes

We have established Catharanthus roseus hairy root cultures transgenic for the rol ABC genes from T(L)-DNA of the agropine-type Agrobacterium rhizogenes strain A4. The rol ABC hairy root lines exhibit a wild-type hairy root syndrome in terms of growth and morphology on solid medium. However, they differ from wild-type hairy root lines in that they more frequently have excellent adaptability to liquid medium and do not appear to form calli during cultivation. Moreover, they do not produce detectable levels of mannopine and agropine which, in contrast, are often synthesized abundantly in wild-type hairy root lines. The absence of these opines does not appear to cause the rol ABC lines to have higher levels of terpenoid indole alkaloids than wild-type hairy root lines. Unlike wild-type lines, rol ABC lines produce very similar levels of total alkaloids despite wide variations in individual alkaloid contents. This work demonstrates that the three genes rol ABC are sufficient to induce high-quality hairy roots in Catharanthus roseus.     

Morphometric and biochemical characterization of red beet (<Emphasis Type="Italic">Beta vulgaris</Emphasis> L.) hairy roots obtained after single and double transformations

It is known that T-DNA of Agrobacterium rhizogenes affects processes of plant development and activates the synthesis of secondary metabolites in transformed plant cells. In the present investigation, we provide evidence that different strains of A. rhizogenes significantly affect morphometric, morphological and functional characteristics of hairy roots of red beet (Beta vulgaris L.). Infection with four strains of A. rhizogenes (A4, A 2/83, A 20/83 and LMG-150) resulted in ten clones of hairy roots, which were named accordingly as A4(1), A4(2), A4(3), A 2/83(1), A 2/83(2), A 2/83(3), A 20/83(1), A 20/83(2), A 20/83(3) and LMG-150. Their growth characteristics, pigment content, levels of endogenous auxin and T-DNA copy number showed significant differences probably due to the physiological status of the host cell rather than the T-DNA copy number. Although A 2/83 showed highest hairy root induction capacity, the best hairy root clone was obtained with strain LMG-150 that produced highest biomass and pigments. In this root clone, the enzyme peroxidase was found involved in altering the endogenous auxin pool. When root clone LMG-150 was re-transformed to insert additional individual rol genes, two double transformed clones were obtained, one for rolABC and the other for rolC gene where the former produced higher biomass and betalaine than the latter. Despite the established fact that rol genes of T-DNA influence endogenous phytohormones, no direct correlation among the single transformants and the double transformants was found. This is the first report, in our knowledge, where a hairy root clone has been used to obtain double transformants.