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.     

Evidence for Agrobacterium-induced apoptosis in maize cells

Agrobacterium spp. can genetically transform most dicotyledonous plant cells whereas many monocot species are recalcitrant to Agrobacterium-mediated transformation. One major obstacle is that co-cultivation of Agrobacterium spp. with plant tissues often results in cell death. Report here is that, in maize tissues, this process resembles apoptosis, with characteristic DNA cleavage into oligonucleosomal fragments and morphological changes. Two anti-apoptotic genes from baculovirus, p35 and iap, had the ability to prevent the onset of apoptosis triggered by Agrobacterium spp. in maize tissues. p35 is reported to act as a direct inhibitor of a certain class of proteases (caspase) whereas i.a.p. may act upstream to prevent their activation. This evidence raises the possibility that caspase-like proteases may also be involved in the apoptotic pathway in plant cells.     

Effect of the number of rol genes integrations on phenotypic variation in hairy root-derived Hypericum perforatum L. plants

The extent of phenotypic variation of St. John's wort (Hypericum perforatum L.) plants transformed with wild agropine ATCC 15834 Agrobacterium rhizogenes plasmid was evaluated with respect to the number of rol genes integrations. The transfer of T(L)-DNA to plant explants during each transformation event was incomplete with different rolA, rolB, and rolC copy numbers. Along with typical features representing the hairy root syndrome, an altered size, number and density of dark and translucent glands, changes in ability to synthesize secondary metabolites, and reduced fertility were observed. The highest copy number of transferred rol genes resulted in weak expression of transgenic character and comparable quantitative parameters with the controls. Only 1 out of 11 transgenic clones was able to produce seed progeny and not more than 4 out of its 35 offsprings were positive for rolC gene integration. Sterility of the clones was due to retarded development of both gametophytes.     

Hairy Root and Its Application in Plant Genetic Engineering

Agrobacterium rhizogenes Conn. causes hairy root disease In plants. Hairy root-Infected A. rhizogenes Is characterlzed by a high growth rate and genetic stability. Hairy root cultures have been proven to be an efficient means of producing secondary metabolites that are normally biosyntheslzed In roots of differentiated plants. Furthermore, a transgenlc root system offers tremendous potential for introducing additional genes along with the RI plasmld, especially with modified genes, into medicinal plant cells with A. rhizogenes vector systems. The cultures have turned out to be a valuable tool with which to study the biochemical properties and the gene expression profile of metabolic pathways. Moreover, the cultures can be used to elucidate the Intermediates and key enzymes Involved In the biosynthesis of secondary metabolites. The present article discusses various appllcations of hairy root cultures in plant genetic engineering and potential problems aseoclsted with them.     

单、双子叶植物的代谢物调节农杆菌Vir区基因表达的研究

本文研究了六种植物（三种单子叶植物,三种双子叶植物）愈伤组织的 渗出物和抽提物对农杆菌Vir基因表达的调节作用,其调节水平植物的不同而明显不同,但单,双子叶植物的代谢物对Vir基因表达的调节作用并非截然分开,即使在双子叶植物（如大豆）的抽提物与渗出物中也存在着抑制Vir基因表达的因子,而在单子叶植物（如玉米等）的抽提物与渗出物中也存在着促进Vir基因表达的调节因子,Vir位点的调节反应随渗出物与抽提物的种类不同而明显不同,不同Vir位点对同类渗出物或抽提物的反应也不同,渗出物对Vir基因表达的正调节效应优于抽提物,植物渗出物与AS对Vir区基因表达的调节并不表现简单的累加效应或协同作用,相反,在渗出物中还存在着不同程度阻抑AS对Vir基因表达正调节的因子。     

Agrobacterium-mediated transformation of sea urchin embryos

Agrobacterium-mediated transformation of higher plants is a well-known and powerful tool for transgene delivery to plant cells. In the present work, we studied whether Agrobacterium can transfer genetic information to animal (sea urchin) embryos. Sea urchin embryos were co-cultivated with A. tumefaciens strains carrying binary vectors containing the nptII marker gene and agrobacterial rolC and rolB oncogenes. Bacterial plasmid T-DNA-sea urchin DNA junction sites were identified in the genome of these embryos, thus indicating successful transformation. The nptII and both rol genes were expressed in the transformed embryos. The processes of transgene integration and transgene expression were suppressed when Agrobacteria contained mutated virA, virB or virG genes, suggesting that Agrobacterium transforms sea urchin cells by a mechanism similar to that which mediates T-DNA transfer to plants. Some of the embryos co-cultivated with Agrobacterium developed teratoma-like structures. The ability of Agrobacterium strains to trigger formation of teratoma-like structures was diminished when they contained the mutated vir genes. In summary, our results demonstrate that Agrobacterium is able to transform animal (sea urchin) embryonic cells, thus indicating a potential of this natural system for gene delivery to animal hosts. We also discuss the possibility of horizontal gene transfer from Agrobacterium to marine invertebrates.     

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.     

Residual phosphorus and long-term management strategies for an Ultisol

Due to their extensive growth potential, transgenic root systems arising from inoculation withAgrobacterium rhizogenes became popular in the last decade as model systems in domains as diverse as production of secondary metabolites, interactions with pathogens and symbionts, examination of gene importance in control of root development or in regulation of gene expression in roots. Wild-type bacterial strains have also been considered as useful tools to stimulate rooting on recalcitrant cuttings or microcuttings as they cause abundant root initiation at the site of inoculation.Root initiation and the in vitro growth characteristics of transformed roots result from the transfer of genes located on the root-inducing plasmid (Ri) to plant cells and their expression therein. Two sets of pRi genes are involved in the root induction process: therol (rootloci) genes located in the TL region and theaux genes of the TR region. Some of these genes being able to interact, the system appears also as a new tool to study the role of auxin in the process of root initiation. The distinctive phenotype of the transformed roots which are capable of hormone autonomous growth seems to be controlled mainly by therol genes. Theserol genes, i.e. the geneticloci rol A, rol B, rol C androl D correspond to open reading frames ORFs 10, 11, 12 and 15. In vitro experiments determined the functions of the Rol B and Rol C proteins but the functions of Rol A and Rol D are still unknown. Altered metabolism of developmental regulators or modified sensitivity to auxin have been suspected to mediate root induction and morphological abnormalities of transformed roots and plants.The target cells for transformation and the cells which are competent for root initiation will be characterized as well as the subsequent development of transgenic roots provided with various constructs from the whole T-DNA to singlerol genes. Results dealing with auxin contents in relation with root growth kinetics, phenotype and structure, will also be presented and discussed with the potential use of therol genes to control root biomass. F J de Bruijn Section editor     

三裂叶野葛毛状根的诱导及其固体培养和液体培养

发根农杆菌（Agrobacterium rhizogenes）ATCC15834感染三裂叶野葛(Pueraria phaseoloides)叶片外植体20 d后产生毛状根,毛状根可直接从叶片外植体叶脉处或从叶脉处产生的愈伤组织上产生。感染35d后,约85%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固体和液体培养基上自主生长。PCR扩增结果表明,发根农杆菌Ri质粒的rolB和rolC基因已在三裂叶野葛毛状根基因组中整合并得到表达。与固体培养的毛状根相比,在液体培养基中培养的毛状根不仅生长迅速,也不会形成愈伤组织。在无外源生长调节剂的液体MS培养基中培养15d的三裂叶野葛毛状根的鲜重、干重、可溶性总糖含量及细胞内活性氧(ROS)含量分别为固体培养毛状根的1.59倍、1.18倍、5.25倍和1.16倍。     

Increase in anthraquinone content in Rubia cordifolia cells transformed by rol genes does not involve activation of the NADPH oxidase signaling pathway

It has been reported that rol plant oncogenes located in Ri-plasmids of Agrobacterium rhizogenes activated synthesis of secondary metabolites in the transformed plant cells. The activator mechanism is still unknown. In this work, we studied whether the NADPH oxidase-signaling pathway, which regulates the synthesis of defense metabolites in plants, is involved in the activator function of the rol genes. It was demonstrated that the transformation of Rubia cordifolia cells by the rolB and rolC genes caused an induction of biosynthesis of anthraquinone-type phytoalexins. Inhibition studies revealed a striking difference between the rolC and rolB transformed cultures in their sensitivity to Ca²⁺ channel blockers and calcium deficiency. The rolC culture displayed lowered resistance to the inhibitors compared to the non-transformed culture, while the rolB culture was more resistant to the treatment. The assumption was made that the oncogenic potential of rol genes is realized through the alteration of calcium balance in the plant cells. Anthraquinone production was not inhibited in the non-transformed and transformed cultures by Ca²⁺ channel blockers, as well as by diphenylene iodonium, an inhibitor of NADPH oxidase, and by the protein kinase inhibitor staurosporine. These results indicate that the induction of anthraquinone production in transgenic cultures does not involve the activation of Ca²⁺-dependent NADPH oxidase pathway.     

Single genes from Agrobacterium rhizogenes influence plant development

The combined expression of the rol A, B, and C loci of Agrobacterium rhizogenes Ri-plasmids establishes, in transgenic tobacco plants, a pathological state called hairy-root syndrome. However, when expressed separately they provoke distinct developmental abnormalities characteristic for each rol gene. Moreover, changes in their mode of expression obtained by replacing the promoters of the rol B and C genes with the cauliflower mosaic virus 35S promoter elicit new and distinct developmental patterns. These results indicate that the different rol gene products have either different targets, or have a qualitatively different effect on the same target. The target(s) must be involved in the control of plant development. Although each of the three rol genes are independently able to promote root formation in tobacco, efficient root initiation and growth is best achieved through the combined activities of more than a single rol gene. Models explaining the biological effects of A. rhizogenes-derived TL-DNA genes are discussed.     

Transformed Roots of Lupinus mutabilis: Induction, Culture and Isoflavone Biosynthesis

Transformed roots of Lupinus mutabilis cv. Potosi induced by Agrobacterium rhizogenes strain R1601 were cultured on Murashige and Skoog-based medium lacking kanamycin sulphate, or with this antibiotic at 40 mg l⁻¹. The neomycin phosphotransferase gene in the genome of transformed roots was confirmed by non-radioactive Southern hybridisation. Neomycin phosphotransferase protein was detected by ELISA. Transformed roots synthesised isoflavones, but not quinolizidine alkaloids; the latter are typical secondary metabolites of lupin normally produced in aerial parts of the plant. Genistein and 2′-hydroxygenistein, were the main secondary metabolites in cultured, transformed roots, whereas the glycoside genistin was more abundant in roots of non-transformed plants. Wighteone concentrations in transgenic roots were higher than those of non-transformed roots. Transformed roots produced twice the concentration of isoflavones compared with roots from non-transformed plants, indicating that Ri plasmid T-DNA genes modified isoflavone concentration and pattern of biosynthesis.     

Eliciting secondary metabolism in plant cell cultures

Plant cell cultures are potentially rich sources of valuable pharmaceuticals and other biologically active phytochemicals, but relatively few cultures synthesize secondary compounds over extended periods in amounts comparable to those found in the whole plant. Frequently, no secondary metabolites characteristic of the intact plant are produced. So far, the manipulation of culture media, culture conditions and phytohormone levels have, in general, failed to permit commercial production of those phytochemicals useful in medicine and industry. This almost certainly reflects the lack of understanding of basic secondary metabolic regulation in cultured plant cells.

Microbial insult can induce antibiotic phytochemical synthesis in cultured plant cells: the microbial molecules which stimulate synthesis have been called ‘elicitors’. Increased synthesis of secondary products in response to elicitation of various types appear to be the general response of cultured cells. This paper illustrates the immense biotechnological potential of plant cell culture—‘elicitor’ (inducer) interactions to the large scale production of secondary metabolites, and suggests several lines of enquiry that remain to be authoritatively treated.     

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。     

地衣型真菌石果衣(疣孢菌科，子囊菌门)次级代谢产物的多样性

地衣能够产生大量的新型次级代谢产物,但以往对石果衣Endocarpon pusillum的研究中未能检测出任何次级代谢产物。然而,对其共生菌进行基因组测序发现其中含有14个沉默的PKS基因和2个沉默的NRPS基因。在此研究中,为激活其途径,使用了优化马铃薯培养基和大米培养基对石果衣共生真菌进行了培养。从优化马铃薯培养物中分离得到9个次级代谢产物,包括2个新的异吲哚-1-酮类化合物(1, 2)。而从大米培养物中分离到3个已知化合物和1个新的萘醌类化合物(9)。通过核磁共振和质谱数据确定了新化合物的结构。研究结果表明,大量地衣中未能检测出任何次级代谢产物,或仅能检测出少量次级代谢产物,可能与其基因组中的沉默基因有关。因此,通过对沉默基因的激活方法为地衣次级代谢产物资源的研究与开发开辟了有效途径。     

Isolation and characterization of diosgenin from in vitro cultured tissues of Helicteres isora L

The objective of the present study was to isolate, characterize, quantify and compare the accumulation of bioactive secondary metabolite—diosgenin from in vitro cultured cells of Helicteres isora and plant parts. The levels of this secondary compound were examined by using various biochemical techniques. The result showed that maximum diosgenin was obtained from in vitro cultured cells as compared to the plant parts. The fallout of this study is important, since levels of diosgenin detected in the in vitro cultured cells were more than in the plant parts. In vitro cultured cells accumulate comparatively higher amount of diosgenin making Helicteres isora a potentially new and indigenous source of diosgenin.