Transgenic Medicago truncatula plants obtained from Agrobacterium tumefaciens -transformed roots and Agrobacterium rhizogenes-transformed hairy roots

Medicago truncatula, barrel medic, is a forage crop that has been developed into a model legume. The development of new transformation methods is important for functional genomic studies in this species. Based on Agrobacterium tumefaciens-mediated transformation of root explants, we developed an effective system for producing M. truncatula (genotype R108) transgenic plants. Among the four A. tumefaciens strains (AGL1, C58C1, EHA105 and LBA4404) tested, EHA105 and AGL1 were most effective in regenerating transgenics. Callus induction frequency from root explants was 69.8%, and plantlet/shoot regeneration frequency was 41.3% when EHA105 was used. Transgenic nature of the regenerated plants was confirmed by PCR and Southern hybridization analyses. Progeny analysis revealed stable Mendelian meiotic transmission of transgenes. Because M. truncatula is particularly useful for the study of root endosymbiotic associations, we further developed a plant regeneration system from A. rhizogenes-transformed hairy roots of M. truncatula. Fertile true transgenic plants were regenerated from the hairy roots, thus allowing the assessment of gene functions at the whole plant level. Segregation analysis revealed that the hairy root genes could be segregated out in the progenies. By coupling A. rhizogenes-mediated hairy root transformation and the regeneration system reported here, once potential genes of interest are identified, the transformed hairy roots carrying such genes could be directly regenerated into plants for more detailed characterization of the genes.     

孑遗蕨类中华水韭根系发育的研究

以发育良好的中华水韭植株为材料,用常规半薄切片法,详细观察了根的发育及其根系的特征,并讨论了水韭根的内外两种起源途径、不同粗细根的结构功能、分支及横隔的生物学意义,为探讨古老维管植物的系统演化及濒危原因提供形态学依据。结果显示:(1)中华水韭成熟植株没有主根,有近百条浅棕色管状根,既有内起源根,也有外起源根,且每条根都有多回二歧分支。(2)二歧分支的发生一般频率密集且为不均等分裂,根越细分支越早,而且分支频率越密集;二歧分支处都有由2~3层细胞组成的永久性横隔,即使在老根内这种横隔也始终存在。(3)子根尖的部分皮层细胞能够直接转化成表皮,子根尖粗细不等。研究认为,中华水韭有茎起源根和根托起源根,皮层细胞具有特殊的分化能力,横隔是古生态的高能环境所造成的适应性结构,其根系具有旺盛的再生能力及高度的复杂性。     

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.     

农杆菌转化的小冠花发状根的诱导及其植株再生

利用野生型发根农杆菌15834菌株感染小冠花15日龄无菌苗子叶和下胚轴切段,建立了高效的发状根培养及其体细胞胚胎发生再生体系。发状根可直接从受伤的外植体表面产生,也能在外植体诱导的愈伤组织上发生,在无外源激素的MS固体和液体培养基上,转化根能自主生长,表现出典型的发根特征。用适宜浓度的乙酰丁香酮处理对数生长期的农杆菌菌液2h,感染预培养2d的子叶获得了最高的转化频率(87.4%)。在附加0.2mgL2,4_D,0.5mgLNAA和0.5mgLKT的MS培养基上,发状根能100%形成胚性愈伤组织,并于含0.5mgLKT,0.2mgLIBA和300mgL脯氨酸的MS培养基上顺序经过体细胞胚胎发育的各个典型时期,转换成完整植株。再生植株除具有发达的侧根外,其它形态特征与未转化植株未见明显的差异,但在获得的5个转化克隆中,其中1个的发状根及其再生植株叶片中有毒物质3_硝基丙酸的含量显著下降,分别为未转化对照的57.68%和58.17%。冠瘿碱纸电泳检测和rolB基因PCR扩增检测均证明农杆菌Ri质粒上的T_DNA已经整合到小冠花转化细胞的基因组中。     

Regeneration of roots from callus reveals stability of the developmental program for determinate root growth in Sonoran Desert Cactaceae

In some Sonoran Desert Cactaceae the primary root has a determinate root growth: the cells of the root apical meristem undergo only a few cell division cycles and then differentiate. The determinate growth of primary roots in Cactaceae was found in plants cultivated under various growth conditions, and could not be reverted by any treatment tested. The mechanisms involved in root meristem maintenance and determinate root growth in plants remain poorly understood. In this study, we have shown that roots regenerated from the callus of two Cactaceae species, Stenocereus gummosus and Ferocactus peninsulae, have a determinate growth pattern, similar to that of the primary root. To demonstrate this, a protocol for root regeneration from callus was established. The determinate growth pattern of roots regenerated from callus suggests that the program of root development is very stable in these species. These findings will permit future analysis of the role of certain Cactaceae genes in the determinate pattern of root growth via the regeneration of transgenic roots from transformed calli.     

Ri-plasmid as a helper for introducing vector DNA into alfalfa plants

Genetic engineering of legumes and other important dicotyledonous plants is limited because of the difficulty of regenerating plants via cell culture. Since a considerable number of crop plants can be regenerated only from root culture, the introduction of foreign genes into Agrobacterium rhizogenes-induced hairy roots may expand the list of crop plants that could be genetically engineered. Here we report genetic transformation of alfalfa (Medicago sativa L.), a valuable forage legume, using a virulent strain of Agrobacterium rhizogenes containing, in addition to its Ri-plasmid, a binary vector containing a nopaline synthase gene. Plant cells transformed by this vector can be easily identified by their ability to produce nopaline. Transformed alfalfa plants were recovered from A. rhizogenes-induced hairy roots. These transgenic plants were characterized by normal leaf morphology and stem growth but a root system that was shallow and more extensive than normal. These plants were also fertile, set seeds upon self-pollination and outcrossing. Nopaline was detected in R1 progeny. Southern blot analysis confirmed the presence of multiple copies of T-DNAs from the Riplasmid in the plant genome in addition to the vector T-DNA.     

Regeneration of plants from callus tissues of hairy roots induced by Agrobacterium rhizogenes on Alhagi pseudoalhagi

INTRoDUCTIONThe hairy root disease is a patholOgical syndromeof dicotyledonous plants fOllowing wounding and in-fection with Agrobacterum rhjZOgenesI1]. The rhi-zogenicity is conferred to p1ant cel1s by a fragmentof DNA (Ri T-DNA), which is transferred from thelarge root--inducting (Ri) plasmid, haJrboured by thebacterium, to the genome, where it is stably inte-grated and expressed. Illtegration of a DNA segment(T-DNA) of pRi into the host genome 1eads to ac-tive proliferation of…     

Production of ROL gene transformed plants of Rosa hybrida L. and characterization of their rooting ability

Transgenic plants of the rootstock Rosa hybrida L. cv. Moneyway were produced via a two-step procedure. First, kanamycin-resistant roots were generated on stem slices from micropropagated shoots, which were cocultivated with Agrobacterium tumefaciens containing the neomycin phosphotransferase II (NPTII) gene for conferring kanamycin resistance, together with individual ROL genes from A. rhizogenes. Root formation was quite efficient and up to two kanamycin-resistant roots per stem slice were produced. In the second step, these roots were used to regenerate transgenic plants via somatic embryogenesis. Although regeneration lasted up to 12 months, production of several transformants was successfully accomplished. Untransformed escapes were not found, indicating that the initial selection on kanamycin resistance was reliable.The presence of a combination of ROLA, B and C genes enhanced adventitious root formation on micropropagated shoots and explants of stems and leaves. It appears that the auxin sensitivity was increased to such a degree that cells were able to respond even to endogenous auxins present in shoots and leaves. Rooting experiments in greenhouse demonstrated that adventitious root formation on cuttings was improved threefold upon introduction of these ROL genes. It is concluded that a method was developed for the production of ROL gene transformed roses with improved rooting characteristics.     

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.     

RNA interference in Agrobacterium rhizogenes-transformed roots of Arabidopsis and Medicago truncatula

RNA interference (RNAi) is a powerful reverse genetic tool to study gene function. The data presented here show that Agrobacterium rhizogenes-mediated RNAi is a fast and effective tool to study genes involved in root biology. The Arabidopsis gene KOJAK, involved in root hair development, was efficiently knocked down. A. rhizogenes-mediated root transformation is a fast method to generate adventitious, genetically transformed roots. In order to select for co-transformed roots a binary vector was developed that enables selection based on DsRED1 expression, with the additional benefit that chimaeric roots can be discriminated. The identification of chimaeric roots provided the opportunity to examine the extent of systemic spread of the silencing signal in the composite plants of both Arabidopsis and Medicago truncatula. It is shown that RNA silencing does not spread systemically to non-co-transformed (lateral) roots and only inefficiently to the non-transgenic shoot. Furthermore, evidence is presented which shows that RNAi is cell autonomous in the root epidermis.     

The consequence of peroxidase overexpression in transgenic plants on root growth and development

Transgenic tobacco plants that overproduce the tobacco anionic peroxidase wilt upon reaching maturity, although having functional stomata and normal vascular anatomy and physiology. These plants were examined further to determine the cause for wilting, and thus better understand how the anionic peroxidase functions in plant growth and development. Shoots from young peroxidase overproducing plants were grafted onto wild-type tobacco root stock to determine if the roots could absorb and transmit sufficient water to maintain leaf turgidity. These grafted plants never wilted when grown in the greenhouse though shoot peroxidase activity remained ten-fold greater than in control plants, thus indicating that wilting is a consequence of peroxidase expression in the roots. Close examination of root systems revealed considerably less root mass in the transformed plant, primarily exhibited through a decrease in branching. At flowering, root growth rate and total root mass in transformed plants were less than 50% of control plants although shoot mass and growth rate were unchanged. This is in contrast to root growth in young seedlings where transformed plants performed equivalently to controls. Root hydraulic conductivity was measured to evaluate the effect of elevated peroxidase expression on water absorption and transport; however, no significant change in hydraulic conductivity was found in transformed plants. The consequence of anionic peroxidase overexpression on indoleacetic acid (IAA) metabolism was also examined. No significant difference in IAA levels was observed; however, root elongation in plants overexpressing peroxidase was insensitive to exogenous IAA. It can be concluded that the overexpression of the tobacco anionic peroxidase in transformed plants results in diminished root mass from fewer root branches, which contributes to the wilting phenomenon seen in these plants. Further, this developmental change in transformed plants may be a consequence of the metabolism of IAA by the anionic peroxidase.     

Cucurbita pepo L. can be transformed by Agrobacterium rhizogenes

Two-week-old in vitro grown Cucurbita pepo L. intact plants and cotyledons (detached and undetached from the mother-plant) were transformed by Agrobacterium rhizogenes strain NCPPB 1855, grown for 48 h at 25 °C on YMB medium. All infected material formed vigorous hairy roots in about seven days. The transformed roots were successfully grown in liquid MS medium without plant growth regulators for an indefinite number of transfers. Genetic transformation of root DNA was proven by Southern analysis performed with a rolABC probe and a vir probe. Our results demonstrate that, in contrast with previous literature, A. rhizogenes could represent an efficient and reproducible system to transform C. pepo plants. Furthermore, we verified that plant age and incubation times/temperatures of bacterial strain influence transformation efficiency. This revised version was published online in June 2006 with corrections to the Cover Date.     

Regeneration of flax plants transformed by Agrobacterium rhizogenes

Regeneration of flax (Linum usitatissimum) following transformation by either Agrobacterium tumefaciens carrying a disarmed Ti-plasmid vector, or Agrobacterium rhizogenes carrying an unmodified Ri plasmid, was examined. Hypocotyl and cotyledon explants inoculated with A. tumefaciens formed transformed callus, but did not regenerate transformed shoots either directly or via callus. However, cotyledon explants inoculated with A. rhizogenes formed transformed roots which did regenerate transformed shoots. Ri T-DNA encoded opines were detected in the transformed plantlets and Southern hybridization analysis confirmed the presence of T-DNA from the Ri plasmid in their DNA. Transformed plantlets had curled leaves, short internodes and some had a more developed root system characterized by plagiotropic behaviour.     

Agrobacterium rhizogenes-mediated transformation of Prunus as an alternative for gene functional analysis in hairy-roots and composite plants

Resistant rootstocks offer an alternative to pesticides for the control of soil pests. In Prunus spp., resistance loci to root-knot nematodes (RKN) have been mapped and a transformation method is needed to validate candidate genes. Our efforts have focused on the generation of transformed hairy-roots and composite plants appropriate for nematode infection assays. An efficient and reliable method using the A4R strain of Agrobacterium rhizogenes for the transformation of Prunus roots with an Egfp reporter gene is given. The rooting efficiency, depending on the genotypes, was maximal for the interspecific hybrid 253 (Myrobalan plum?×?almond-peach), susceptible to RKN, that was retained for subsequent studies. From the agro-inoculated cuttings, 72% produced roots, mainly at the basal section of the stem. Transformed roots were screened by microscope detection of Egfp fluorescence and molecular analyses of the integration of the transgene. The absence of residual agrobacteria in the plants was checked by the non-amplification of the chromosomal gene chvH. Egfp was expressed visually in 76% of the rooted plants. Isolated hairy roots in Petri dishes and composite plants (transformed roots and non-transformed aerial part) in soil containers were inoculated with the RKN Meloidogyne incognita. In both cases, root transformation did not affect the ability of the nematodes to develop in the root tissues. Our results showed that isolated hairy-roots can be used to validate candidate genes and the conditions in which composite plants offer a complementary system for studying the function of root genes in physiological conditions of whole plants are discussed.     

The behaviour of normal and agravitropic transgenic roots of rapeseed (Brassica napus L.) under microgravity conditions

In the TRANSFORM experiment for IML-2 on the Space Shuttle Columbia, normal (wild type = WT) and genetically transformed agravitropic rapeseed roots were tested under microgravity conditions. The aim of the experiment was to determine if the wild-type roots behaved differently (growth, morphology, gravitropical sensitivity) from the transgenic roots. The appearance of the organelles and distribution of statoliths (i.e. amyloplasts with starch grains) in the gravitropic reactive cells (statocytes) under weightlessness was compared for the two types of roots. Attempts have also been made to regenerate new plants from the root material tested in space. Both the WT and the transgenic root types showed the expected increase in length during 36 h of photorecording. Contrary to the results of the ground controls, no significant difference in elongation rates was found between the WT and transgenic roots grown in orbit. However, there are indications that the total growth both in the WT and the transgenic roots was higher in the ground control than for roots in orbit. After a 60 min 1 x g stimulation of the roots on board the Shuttle, no detectable curvatures were obtained in either the transgenic or the WT roots. However, it cannot be excluded that a minute curvature development occurs in the root tips but was not detected due to technical reasons. The ultrastructure was well preserved in both the WT and the transgenic roots, despite the fact that the tissue was kept in the prefixative for over 3 weeks. No marked differences in ultrastructure were observed between the transformed root statocyte cells and the equivalent cells in the wild type. There were no obvious differences in root morphology during the orbital period. Light micrographs and morphometrical analysis indicate that the amyloplasts of both the wild type and transformed root statocytes are randomly distributed over the cells kept under micro-g conditions for 37 h after a 14 h stimulation on the 1 x g centrifuge. The main scientific conclusion from the TRANSFORM experiment is that the difference in growth found in the ground control between the WT and the transgenic root types seems to be eliminated under weightlessness. Explanations for this behaviour cannot be found in the root ultrastructure or in root morphology.     

种子特异表达ipt转基因棉花根和纤维的改变

将种子特异表达的菜豆蛋白启动子（Ｐｈ／Ｐ）与ｉｐｔ基因融合,构建了植物表达载体。该载体含有由３５Ｓ启动子驱动的ｇｕｓ报告基因。应用该载体通过花粉管通道法转化棉花（Ｇｏｓｓｙｐｉｕｍ ｈｉｒｓｕｔｕｍ Ｌ．）,种子萌发后剪取幼根进行ＧＵＳ染色,获得ＧＵＳ阳性植株２３棵。ＰＣＲ检测证明有３棵ＧＵＳ阳性植株中含有Ｐｈ／Ｐ－ｉｐｔ基因,并进一步用地高辛标记的ＤＮＡ探针作杂交验证了上述结果。分析表明２棵转基     

In Vitro Haustorium Development in Roots and Root Cultures of the Hemiparasitic Plant Triphysaria Versicolor

Parasitic plants in the Orobanchaceae invade host plant roots through root organs called haustoria. Parasite roots initiate haustorium development when exposed to specific secondary metabolites that are released into the rhizosphere by host plant roots. While molecular approaches are increasingly being taken to understand the genetic mechanism underlying these events, a limitation has been the lack of a transformation system for parasitic plants. Since the haustorium development occurs in roots of Orobanchaceae, root cultures may be suitable material for transient or stable transformation experiments. To this end, root cultures were obtained from explants, and subsequently calluses, from the hemiparasitic plant Triphysaria versicolor. The cultured roots retained their competence to form haustoria when exposed to host roots, host root exudates, or purified haustorium-inducing factors. The root culture haustoria invaded host roots and initiated a vascular continuity between the parasite and host roots. The ontogeny of haustoria development on root cultures was indistinguishable from that on seedlings roots. Root cultures should provide useful material for molecular studies of haustorium development.     

Transformation of Gynostermma pentaphyllum by Agrobacterium rhizogenes and Saponin Production in Hairy Root Cultures

Authors report here the establishment of an efficient transformation system for Gynosternrna pentaphyllum (Thunb.) Makino using Agrobacteriurn rhizogenes R1600. Hairy roots appeared on leaf explants 10 days after inoculation with the bacteria . Frequency of the explants transformed by R1600 was up to 94%. Transformation was confirmed by Southern analysis. Biomass of hairy root cultures suspended in hormone-free MS medium increased 9 times after 20 days of incubation. There was no callus formation on the hairy roots during suspension culture. Saponin content in the hairy root cultures was about 2 times as much as in the natural roots, saponins of the hairy root cultures were also released into growth medium as well.     

Alterations of Root and Fiber in Transgenic Cotton Plants with Chimeric Ph/P-ipt Gene Expression

The seed-specific phaseolin promoter (Ph/P) was fused to an ipt gene, then was cloned to a plant expression vector containing a gus gene driven by a 35S promoter. Cotton (Gossypium hirsutum L.) plants were transformed through pollen tube pathway methods. After seed germination, histochemical staining of the roots demonstrated that 32 GUS positive plants were obtained and three of which contained the chimeric Ph/P-ipt transgene as confirmed by PCR analysis. An immunosorbent assay showed that two of the three transgenic cotton lines contained higher levels of zeatin equivalents in seeds than the control. Seedling development of these two transgenic lines differed from the control in a reduction of the shoot growth, showing a stunted phenotype as expected, but a surprisingly developed root system with a 3-4 fold fast-growing lateral roots. In addition, fibers (seed-hairs) of the two transgenic cotton lines were considerably shorter than those of the control. These results indicate that genetic engineering may be used to manipulate the development of cotton plants, particularly cotton fibers.