A disarmed binary vector from Agrobacterium tumefaciens functions in Agrobacterium rhizogenes : Frequent co-transformation of two distinct T-DNAs

Genomic consequences associated with Agrobacterium-mediated transformation of plants

Attenuated strains of the naturally occurring plant pathogen Agrobacterium tumefaciens can transfer virtually any DNA sequence of interest to model plants and crops. This has made Agrobacterium-mediated transformation (AMT) one of the most commonly used tools in agricultural biotechnology. Understanding AMT, and its functional consequences, is of fundamental importance given that it sits at the intersection of many fundamental fields of study, including plant-microbe interactions, DNA repair/genome stability, and epigenetic regulation of gene expression. Despite extensive research and use of AMT over the last 40 years, the extent of genomic disruption associated with integrating exogenous DNA into plant genomes using this method remains underappreciated. However, new technologies like long-read sequencing make this disruption more apparent, complementing previous findings from multiple research groups that have tackled this question in the past. In this review, we cover progress on the molecular mechanisms involved in Agrobacterium-mediated DNA integration into plant genomes. We also discuss localized mutations at the site of insertion and describe the structure of these DNA insertions, which can range from single copy insertions to large concatemers, consisting of complex DNA originating from different sources. Finally, we discuss the prevalence of large-scale genomic rearrangements associated with the integration of DNA during AMT with examples. Understanding the intended and unintended effects of AMT on genome stability is critical to all plant researchers who use this methodology to generate new genetic variants.

Role of hydroxymethylglutaryl-coenzyme A (HMG-CoA) reductase 1 in nodule development of soybean

Autoregulation of nodulation (AON) plays a central role in nodulation by inhibiting the formation of excess number of legume root nodules. In this study, the effect of hydroxymethylglutaryl-coenzyme A reductase 1 (GmHMGR1) gene expression on nodulation and the AON system in Glycine max (L.) Merr was investigated. Wild-type soybean (cultivar Bragg) and its near-isogenic supernodulating mutant (nitrate tolerant symbiotic) nts1007 were selected to identify the expression pattern of this gene in rootlets after inoculation by its microsymbiont Bradyrhizobium. For further analysis, the full length of GmHMGR1 and its promoter were cloned after amplification by inverse-PCR and BAC library screening. Also, we constructed an intron hairpin RNA interference (ihpRNAi) and a GmHMGR1 promoter: β-glucuronidase fusion constructs, consequently for suppression of GmHMGR1 and histochemical analysis in transgenic soybean hairy roots induced by Agrobacterium rhizogenes strain K599. The GmHMGR1 gene was functional during the early stages of nodulation with the AON system having a negative effect on GmHMGR1 expression and nodule formation in wild-type rootlets. GmHMGR1 was particularly expressed in the developing phloem within the root, nodules and nodule lenticels. Expression of GmHMGR1 in transgenic hairy roots was suppressed by RNAi silencing approximately 85% as compared to empty vector controls. This suggests that the GmHMGR1 gene has an important role in triggering nodule formation as its suppression caused a reduction of nodule formation in nts mutant lines with a deficient AON system.

Silencing of germacrene A synthase genes reduces guaianolide oxalate content in Cichorium intybus L

Chicory (Cichorium intybus L.) is a medicinal and industrial plant from the Asteraceae family that produces a variety of sesquiterpene lactones (STLs), most importantly bitter guaianolides: lactucin, lactucopicrin and 8-deoxylactucin as well as their modified forms such as oxalates. These compounds have medicinal properties; however, they also hamper the extraction of inulin - a very important food industry product from chicory roots. The first step in guaianolide biosynthesis is catalyzed by germacrene A synthase (GAS) which in chicory exists in two isoforms - GAS long (encoded by CiGASlo) and GAS short (encoded by CiGASsh). AmiRNA silencing was used to obtain plants with reduced GAS gene expression and level of downstream metabolites, guaianolide-15-oxalates, as the major STLs in chicory. This approach could be beneficial for engineering new chicory varieties with varying STL content, and especially varieties with reduced bitter compounds more suitable for inulin production.

Production of functional human CuZn-SOD and EC-SOD in bitransgenic cloned goat milk

Human copper/zinc superoxide dismutase (CuZn-SOD) and extracellular superoxide dismutase (EC-SOD) are two superoxide dismutases that scavenge reactive oxygen species (ROS). Their biological role of eliminating oxidative stress caused by excessive ROS levels in living organisms has been utilized in medical treatment, preventing skin photoaging and food preservation. In this study, we employed two sequences that encode human CuZn-SOD and EC-SOD, along with goat beta-casein 5' and 3' regulatory elements, to construct mammary gland-specific expression vectors. Bitransgenic goats were generated using somatic cell nuclear transfer (SCNT), which employed co-transfection to generate bitransgenic goat fetal fibroblast cells as donor cells, and the expression of human CuZn-SOD and EC-SOD and their biological activities were assayed in the milk. PCR and Southern blot analysis confirmed that the cloned goat harbors both hCuZn-SOD and hEC-SOD transgenes. rhCuZn-SOD and rhEC-SOD were expressed in the mammary glands of bitransgenic goat, as determined by western blotting. The expression levels were 100.14 ± 5.09 mg/L for rhCuZn-SOD and 279.10 ± 5.38 mg/L for rhEC-SOD, as determined using ELISA. A total superoxide dismutase assay with WST-8 indicates that the biological activity of rhCuZn-SOD and rhEC-SOD in goat milk is 1451 ± 136 U/mL. The results indicate that two expression vectors can simultaneously transfect goat fetal fibroblast cells as donor cells to produce transgenic goats by SCNT, and the CuZn-SOD and EC-SOD proteins secreted in the mammary glands showed biological activity. The present study thus describes an initial step in the production of recombinant human SODs that may potentially be used for therapeutic purposes.

Metabolic engineering of fatty alcohol production in transgenic hairy roots of Crambe abyssinica

Biotechnological production of fatty alcohols, important raw materials in the chemical industry, has been receiving considerable attention in recent years. Fatty alcohols are formed by the reduction of fatty acyl-CoAs or fatty acyl-ACPs catalyzed by a fatty acyl reductase (FAR). In this study, we introduced genes encoding FARs from Arabidopsis thaliana (AtFAR5) and Simmondsia chinensis (ScFAR) into Crambe abyssinica hairy roots via Agrobacterium rhizogenes-mediated transformation. The efficiency of the transformation ranged between 30 and 45%. The fatty alcohols were only detected in the transgenic hairy root lines expressing ScFAR gene. In all tested lines stearyl alcohol (18:0-OH), arachidyl alcohol (20:0-OH), and behenyl alcohol (22:0-OH) were produced. The content of 18:0-OH varied from 1 to 3% of total fatty acids and fatty alcohols, while the amount of either 20:0-OH and 22:0-OH did not exceed 2%. The transgenic hairy root lines produced from 0.98 to 2.59 nmol of fatty alcohols per mg of dry weight. Very low activity of ScFAR was detected in the microsomal fractions isolated from the selected hairy root lines. To our knowledge, this is the first report on the fatty alcohol production in the hairy root cultures. Biotechnol. Bioeng. 2017;114: 1275-1282. © 2016 Wiley Periodicals, Inc.

Improvement of hairy root cultures and plants by changing biosynthetic pathways leading to pharmaceutical metabolites: strategies and applications

A plethora of bioactive plant metabolites has been explored for pharmaceutical, food chemistry and agricultural applications. The chemical synthesis of these structures is often difficult, so plants are favorably used as producers. While whole plants can serve as a source for secondary metabolites and can be also improved by metabolic engineering, more often cell or organ cultures of relevant plant species are of interest. It should be noted that only in few cases the production for commercial application in such cultures has been achieved. Their genetic manipulation is sometimes faster and the production of a specific metabolite is more reliable, because of less environmental influences. In addition, upscaling in bioreactors is nowadays possible for many of these cultures, so some are already used in industry. There are approaches to alter the profile of metabolites not only by using plant genes, but also by using bacterial genes encoding modifying enzymes. Also, strategies to cope with unwanted or even toxic compounds are available. The need for metabolic engineering of plant secondary metabolite pathways is increasing with the rising demand for (novel) compounds with new bioactive properties. Here, we give some examples of recent developments for the metabolic engineering of plants and organ cultures, which can be used in the production of metabolites with interesting properties.

Gene transfer in cereals

Until recently, gene transfer in plants was achieved only by sexual hybridization. Now, in addition, plant genetic manipulation, with the use of both recombinant DNA and protoplast fusion technology, is being applied to an increasing range of plants. The soil bacterium Agrobacterium tumefaciens, with its associated plasmid, is used as a vector for introducing DNA into the genomes of dicotyledonous plants, but it has not proved suitable for cereals. Instead, the direct uptake of plasmid DNA into cereal protoplasts is being used for the transformation of cells in rice, wheat, and maize. Transformation efficiencies, in some cases, are becoming comparable to those obtained in dicotyledons with Agrobacterium. In rice it is now possible to regenerate efficiently whole plants from protoplasts, and this capability may soon be extended to the other cereals. By means of direct interaction of cereal protoplasts with plasmids, coupled with improved procedures for the regeneration of plants from their protoplasts, gene transfer in the cereals is becoming established at the frontiers of recombinant DNA technology.

Transgenic plants as tools to study the molecular organization of plant genes

Transgenic plants are generated in nature by Agrobacterium tumefaciens, a pathogen that produces disease through the transfer of some of its own DNA into susceptible plants. The genes are carried on a plasmid. Much has been learned about how the plasmid is transferred, how the plasmid-borne genes are organized, regulated, and expressed, and how the bacteria's pathogenic effects are produced. The A. tumefaciens plasmid has been manipulated for use as a general vector for the transfer of specific segments of foreign DNA of interest (from plants and other sources) into plants; the activities of various genes and their regulation by enhancer and silencer sequences have been assessed. Future uses of the vector (or others like it that have different host ranges) by the agriculture industry are expected to aid in moving into vulnerable plants specific genes that will protect them from such killers as nonselective herbicides, insects, and viruses.

Hairy root-activation tagging: a high-throughput system for activation tagging in transformed hairy roots

Activation tagging is a powerful technique for generating gain-of-function mutants in plants. We developed a new vector system for activation tagging of genes in "transformed hairy roots". The binary vector pHR-AT (Hairy Root-Activation Tagging) and its derivative pHR-AT-GFP contain a cluster of rol (rooting locus) genes together with the right border facing four tandem repeats of the cauliflower mosaic virus (CaMV) 35S enhancer element on the same T-DNA. Transformation experiments using Arabidopsis, potato, and tobacco as model plants revealed that upon inoculating plants with Agrobacterium tumefaciens harboring these vectors, a large number of independently transformed roots could be induced from explants within a short period of time, and root culture lines were subsequently established. Molecular analyses of the pHR-AT-GFP-transformed Arabidopsis lines showed that expression of the genes adjacent to the T-DNA insertion site was significantly increased. This system may facilitate application of the activation-tagging approach to plant species that are recalcitrant to the regeneration of transgenic plants. High-throughput metabolic profiling of activation-tagged root culture lines will offer opportunities for identifying regulatory or biosynthetic genes for the production of valuable secondary metabolites of interest.

Binary transformation systems based on 'shooter' mutants of Agrobacterium tumefaciens: a simple, efficient and universal gene transfer technology that permits marker gene elimination

A simple transformation procedure with a positive selection scheme using the expression of the isopentenyl transferase ( ipt) gene of transfer DNA (T-DNA) 'shooter' mutants of Agrobacterium tumefaciens was elaborated. After comparing several 'shooter' mutants we found that particular strains frequently produced phenotypically normal shoots after co-culturing with tobacco leaf explants. Shoots selected for normal phenotype showed apical dominance and could be rooted with the same efficiency as non-transformed shoots. When binary vectors were introduced into these strains, stably integrated binary vector T-DNA sequences were found in some regenerants, which were produced under non-selective conditions on growth-regulator-free medium. Such phenotypically normal transformants typically lacked a stably integrated ipt gene. Normal looking shoots could also be produced in tomato, muskmelon and sweet pepper.

T-DNA integration into genomic DNA of rice following Agrobacterium inoculation of isolated shoot apices

This paper establishes that the isolated shoot meristem of monocotyledons can be infected and transformed using Agrobacterium. Since this explant from nearly any cereal cultivar can rapidly regenerate into a plant, using this explant effectively eliminates the genotype regeneration restrictions to cereal crop transformation allowing direct transformation of elite germplasm. Shoot apices of Oryza sativa L. Tropical Japonica, cv. Maybelle were explants used for cocultivation, and gene transfer was accomplished using Agrobacterium containing plasmids for the bar gene expression driven by the CaMV 35S promoter or by the rice actin 1 promoter. Experiments to determine the survival rates of isolated shoot apices on media containing the herbicide, glufosinate-ammonium (PPT), established that no shoot apices survived on 0.5 or 1.0 mg/l PPT. After shoot apices were cocultivated with Agrobacterium, 2.8% (overall 20 out of 721 shoot apices) survived on 0.5 mg/l PPT. Results demonstrated that the use of the actin 1 promoter-based expression vector and an extra-wounding treatment of the meristematic cells appeared to be most effective in promoting transformation. Integration, expression and transmission of the transferred foreign genes in primary, R1 and R2 generation plants were confirmed by molecular analyses and herbicide application tests. A germination test of R2 progeny from one of the transgenic plants (R1) established a phenotype segregation ratio showing a non-Mendelian inheritance pattern. Inactivation of the transferred foreign gene in R2 progeny appeared to result from transgene methylation.

Cotransformation and differential expression of introduced genes into potato (Solanum tuberosum L.) cv Bintje

The Dutch potato cultivar Bintje has been transformed by Agrobacterium strain LBA1060KG, which contains two plasmids carrying three different DNAs (TL- and TR-DNA on the Agrobacterium rhizogenes plasmid and TKG-DNA on the pBI121 plasmid). Several transformed root clones were obtained after transformation of leaf, stem, and tuber segments, and plants were then regenerated from these root clones. The expression of the various marker genes [rol, opine, β-glucuronidase (GUS), and neomycin phosphotransferase (NPTII)] was determined in several root clones and in regenerated plants. The selection of vigorously growing root clones was as efficient as selection for kanamycin resistance. In spite of the location of NPTII and GUS genes on the same T-DNA, 17% of the root clones did not show GUS activity. Nevertheless, Southern blot analysis showed that these root clones contained at least three copies of the GUS gene. Sixty-four per cent of the root clones contained opines. The expression of these genes, however, was negatively correlated with plant regeneration capacity and normal plant development. The differential expression of the marker genes in the transgenic potato tissues is discussed.

Plant chromosome/marker gene fusion assay for study of normal and truncated T-DNA integration events

During Agrobacterium tumefaciens infection, the T-DNA flanked by 24 bp imperfect direct repeats is transferred and stably integrated into the plant chromosome at random positions. Here we measured the frequency with which a promoterless reporter gene is activated after insertion into the Nicotiana tabacum SR1 genome. When adjacent to the right or left T-DNA border sequences, at least 35% of the transformants express the marker gene, suggesting preferential T-DNA insertion (greater than 70%) in transcriptionally active regions of the plant genome. When the promoterless neomycin phosphotransferase II (nptII) gene is located internally in the T-DNA, the activation frequency drops to 1% since gene activation requires T-DNA truncation. These truncation events in the nptII upstream region occur independently of the nature of the upstream sequence and of the T-DNA length. Deletion of the right border region prevents the detection of activated marker genes. Therefore, T-DNA truncation probably occurs after synthesis of a normal T-DNA intermediate during the transfer and/or integration process. In the absence of border regions, expression of the nptII selectable marker directed by the nopaline synthase promoter was detected in 1 out of 10(5) regenerated calli, suggesting the possibility that any DNA sequence from the Ti plasmid can be transformed into the plant genome, albeit at a low frequency.

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.

Over-expressing a yeast ornithine decarboxylase gene in transgenic roots of Nicotiana rustica can lead to enhanced nicotine accumulation

Transformed root cultures of Nicotiana rustica have been generated in which the gene from the yeast Saccharomyces cerevisiae coding for ornithine decarboxylase has been integrated. The gene, driven by the powerful CaMV35S promoter with an upstream duplicated enhancer sequence, shows constitutive expression throughout the growth cycle of some lines, as demonstrated by the analysis of mRNA and enzyme activity. The presence of the yeast gene and enhanced ornithine decarboxylase activity is associated with an enhanced capacity of cultures to accumulate both putrescine and the putrescine-derived alkaloid, nicotine. Even, however, with the very powerful promoter used in this work the magnitude of the changes seen is typically only in the order of 2-fold, suggesting that regulatory factors exist which limit the potential increase in metabolic flux caused by these manipulations. Nevertheless, it is demonstrated that flux through a pathway to a plant secondary product can be elevated by means of genetic manipulation.

Stable transfer and expression of chimeric genes in licorice (Glycyrrhiza uralensis) using an Ri plasmid binary vector

The pharmaceutically important plant, licorice (Glycyrrhiza uralenesis Fisher), was transformed with a binary vector system of an Ri plasmid, pRi15834, and a mini Ti vector, pGSGluc1, containing chimeric neo and gus genes. The transgenic state of transformed roots was confirmed by detection of agropine and mannopine and by Southern blot hybridization with T-DNA of pGSGluc1. One to three copies of T-DNA of pGSGluc1 was integrated into the genomic DNA of G. uralensis. The expression of chimeric neo and gus genes driven by TR 1' and 2' promoters, respectively, was demonstrated by enzymatic assays. Histochemical analysis showed that the chimeric TR2'-gus gene was expressed specifically in phloem and pericycle tissues of the transformed licorice roots.

Expression and inheritance of inserted markers in binary vector carrying Agrobacterium rhizogenes-transformed potato (Solanum tuberosum L.)

Transgenic shoots were regenerated from eight diploid potato hairy root clones obtained by transformation with Agrobacterium rhizogenes harboring next to its wild-type Ri-plasmid a binary vector containing the neomycin phosphotransferase and the β-glucuronidase genes. The plants exhibited the typical hairy root phenotype. Of the plants isolated, 58% were tetraploid and 38% were diploid. Flowering and tuberization was much better in the diploid than in the tetraploid plants. Transgenic plants formed a significantly larger root system when grown on kanamycin-containing medium as compared to growth on kanamycin-free medium. Direct evidence for genetic transformation was obtained by opine, neomycin phosphotransferase and β-glucuronidase assays, and by molecular hybridization. Fourteen flowering diploid plants were reciprocally crossed with untransformed S. tuberosum plants, but only six were successful. Seedlings obtained from four crosses showed that all traits were transmitted to the offspring. Molecular analysis confirmed the presence of multiple integrations (copies) of both vector T-DNA and Ri-T-DNA. The genetic data, furthermore, suggest that the traits derived from Ri-T-DNA and binary vector T-DNA are linked, as no recombination between the different traits was observed.

Efficient transformation of potato (Solanum tuberosum L.) using a binary vector in Agrobacterium rhizogenes

We transformed three potato (Solanum tuberosum L.) genotypes by using A. rhizogenes or a mixture of A. rhizogenes and A. tumefaciens. Inoculations of potato stem segments were performed with Agrobacterium rhizogenes AM8703 containing two independent plasmids: the wild-type Ri-plasmid, pRI1855, and the binary vector plasmid, pBI121. In mixed inoculation experiments, Agrobacterium rhizogenes LBA1334 (pRI1855) and Agrobacterium tumefaciens AM8706 containing the disarmed Ti-plasmid (pAL4404) and the binary vector plasmid (pBI121) were mixed in a 1∶1 ratio. The T-DNA of the binary vector plasmid pBI121 contained two marker genes encoding neomycin phosphotransferase, which confers resistance to kanamycin, and β-glucuronidase. Both transformation procedures gave rise to hairy roots on potato stem segments within 2 weeks. With both procedures it was possible to obtain transformed hairy roots, able to grow on kanamycin and possessing β-glucuronidase activity, without selection pressure. The efficiency of the A. rhizogenes AM8703 transformation, however, was much higher than that of the "mixed" transformation. Up to 60% of the hairy roots resulting from the former transformation method were kanamycin resistant and possessed β-glucuronidase activity. There was no correlation between the height of the kanamycin resistance and that of the β-glucuronidase activity in a root clone. Hairy roots obtained from a diploid potato genotype turned out to be diploid in 80% of the cases. Transformed potato plants were recovered from Agrobacterium rhizogenes AM8703-induced hairy roots.

Efficient transformation with regeneration of the tropical pasture legumeStylosanthes humilis usingAgrobacterium rhizogenes and a Ti plasmid-binary vector system

Agrobacterium rhizogenes carrying the binary Ti plasmid vector pGA492 was used to transform leaf and stem explants of the tropical pasture legumeStylosanthes humilis. Conditions which yielded kanamycin resistant roots at a frequency of up to 86% and subsequent plant regeneration at a frequency of 23% were defined. Transgenic plants were fertile and either grew normally or had stunted growth but otherwise showed only minor morphological abnormalities. Transgenic plants with normal phenotypes were obtained in the progeny of the primary regenerants. The presence of active neomycin phosphotransferase enzyme activity and binary vector DNA and TL-DNA was demonstrated in the regenerated plants. Evidence for the independent transfer of binary vector and TL-DNA was also obtained. This high frequency production of transgenic plants ofS. humilis is a major improvement over previous methods using disarmed strains ofA. tumefaciens as helper.

Expression of a mouse metallothionein gene in transgenic plant tissues

Three gene constructions based on a mouse metallothionein I gene (mMT-I) were introduced into tobacco using a Ri plasmid vector system to test the effectiveness of animal gene regulatory signals in plant cells. No transcription from the native mouse gene was observed. In plant cells bearing chimeric mMT-I genes in which transcription was driven by the nopaline synthase promoter, neither polyadenylation nor splicing of mMT-I pre-mRNA was observed. Detailed comparisons of mMT-I sequences with those of known plant genes were carried out; slight differences in regions of known consensus sequences may be at least partly responsible for the non-recognition of mMT-I gene regulatory signals in plant cells, though other as yet unidentified, potentially necessary sequences may also be involved.

Analysis of TR-DNA/plant junctions in the genome of a Convolvulus arvensis clone transformed by Agrobacterium rhizogenes strain A4

A Charon 4A phage library, containing insert DNA isolated from a morning glory (Convolvulus arvensis) plant genetically transformed by Ri T-DNA from Agrobacterium rhizogenes strain A4, was used to isolate a lambda clone that contains part of the Ri TL-DNA and the complete TR-DNA. The two Ri T-DNAs were recovered adjacent to each other in a tail-to-tail configuration (i.e. with the TR-DNA inverted with respect to the TL-DNA). Comparison of nucleotide sequences from this lambda clone with the corresponding sequences from the Ri plasmid allowed us to determine the location of the T-DNA/plant junction for the right end of the TL-DNA and the left and right ends of the TR-DNA. We located, near each of these borders, a 24 bp sequence that is similar to the 24 bp consensus sequence found near the pTi T-DNA extremities. In addition, sequences similar to the "core" overdrive sequence from pTi are located near each right border. Hybridization and nucleotide sequence analysis of the DNA adjacent to the TL/TR junction shows that no plant DNA is located between the TL and TR-DNAs and suggests that the plant DNA adjacent to the end of the TR-DNA may have been rearranged during the integration into the plant genome.

Genetic transformation of 9 in vitro clones of Alnus and Betula by Agrobacterium tumefaciens

Crown gall tumorigenesis, integration and expression of T-DNA encoded genes from Agrobacterium tumefaciens were investigated in 9 clones of Alnus glutinosa, A. incana and Betula papyrifera. Tumor formation on in vitro shoots was frequent in all clones with strain Ach5 and present in 8 clones with strain C58. Tumors excised from shoots were selected for autotrophic growth in vitro and axenic cultures were established. Octopine or nopaline, respective of the strain type used for inoculation, was detected in tumorous cultures. Southern blot analyses demonstrated T-DNA integration by hybridization of DNA from tumors with tmr and nos gene probes. One clone of B. papyrifera produced tumors with a morphogenic character, unusual in calli of this species, generating viable shoots which did not synthesize opine.

T-DNA length variability in mannopine hairy root: more than 50 kilobasepairs of pRi T-DNA can integrate in plant cells

Independent carrot (Daucus carota) hairy root lines were established by inoculation of discs taken from the same carrot with Agrobacterium rhizogenes 8196 and A. tumefaciens C58C1(pRi8196) carrying pRi8196. Several lines were compared with respect to T-DNA length. One of them was found to have integrated sequences covering more than 50 kbp of the Ri plasmid.

Segregation of genes transferred to one plant cell from two separate Agrobacterium strains

Agrobacterium tumefaciens and Agrobacterium rhizogenes are soil bacteria which transfer DNA (T-DNA) to plant cells. Two Agrobacterium strains, each with a different T-DNA, can infect plants and give rise to transformed tissue which has markers from both T-DNAs. Although marker genes from both T-DNAs are in the tissue, definitive proof that the tissue is a cellular clone and that both T-DNAs are in a single cell is necessary to demonstrate cotransformation. We have transferred two distinguishable T-DNAs, carried on binary vectors in separate Agrobacterium rhizogenes strains, into tomato cells and have recovered hairy roots which received both T-DNAs. Continued expression of marker genes from each T-DNA in hairy roots propagated from individual root tips indicated that both T-DNAs were present in a single meristem. Also, we have transferred the two different T-DNAs, carried on identical binary vector plasmids in separate Agrobacterium tumefaciens strains, into tobacco cells and recovered plants which received both T-DNAs. Transformed plants with marker genes from each T-DNA were outcrossed to wild-type tobacco plants. Distribution of the markers in the F1 generation from three cotransformed plants of independent origin showed that both T-DNAs in the plants must have been present in the same cell and that the T-DNAs were genetically unlinked. Cotransformation of plant cells with T-DNAs from two bacterial strains and subsequent segregation of the transferred genes should be useful for altering the genetic content of higher plants.

Assessment of the efficiency of cotransformation of the T-DNA of disarmed binary vectors derived from Agrobacterium tumefaciens and the T-DNA of A. rhizogenes

Co-transfer of Agrobacterium rhizogenes T-DNA and T-DNA from the A. tumefaciens binary vector pBin19 (Bevan, 1984) was studied in detail using Nicotiana rustica. High frequencies of co-transfer of T-DNA's were observed, even when no selection pressure was exerted. Increased levels of pBin19 T-DNA were found in hairy root cultures with selection at higher levels of kanamycin sulphate (50-200 μg ml(-1)). Several other species were also transformed by A. rhizogenes carrying pBin19 and A. rhizogenes harbouring a different binary factor, pAGS125 (Van den Elzen et al., 1985), was used to transform N. rustica hairy roots to confer hygromycin B resistance.

Segregation of T-DNA copies in the progeny of a regenerant plant from a mannopine-positive hairy root line

We have analyzed opine content, T-DNA content, and developmental features of one hairy root culture line and its progeny. Opine-positive progeny still have the hairy root phenotype and have essentially the same T-DNA structure as the parental plant. Opineless progeny do not exhibit the hairy root phenotype. Some of them do not contain any T-DNA sequences, whereas others contain only the left part of T-DNA. These results are compatible with the hypothesis that, in the hairy root line analyzed, the left part of T-DNA is integrated independently from the core T-DNA and can therefore segregate during sexual reproduction.

Structure, organization and expression of transferred DNA in Nicotiana plumbaginifolia crown-gall tissues

Data are provided which show that transferred DNA (T-DNA) present in Nicotiana plumbaginifolia crown-gall lines in most cases was scrambled and not intact. Both wild-type, and 'rooter'- and 'shooter'-type mutants of octopine-type Agrobacterium tumefaciens were used to infect N. plumbaginifolia plantlets, cultured in vitro. Resulting tumors were excised from the plantlets and cultured for more than three years. During subculturing the tumor lines were scored for the following phenotypic traits: phytohormone autonomous growth in vitro (Aut(+)), spontaneous shoot regeneration (Reg(+)), root deficiency of shoots (Rod(+)), octopine production (Ocs(+)) and mannopine and agropine production (Mas(+)Ags(+)). An unexpectedly large variety of phenotypes was observed. For instance, two out of three tumor lines induced on haploid plantlets by the rooter mutant LBA4210 regenerated shoots, a phenomenon which is not observed for octopine tobacco tumor lines. Fifty percent of the crown-gall lines studied did not contain octopine. Only one line out of six independent lines analyzed was found to have a 'regular' T-DNA structure. Occurrence of aberrant T-DNA structures was not correlated with the ploidy level of infected plantlets, nor with the T-region structure of the inciting bacterial strain. The pattern of TL-DNA transcripts was studied for one line and correlated well with the aberrant T-DNA structure detected. Segments of TR-DNA, having irregular structures as well, were detected in two out of the six lines studied. The scrambled nature of the TR-DNA explained the absence of mannopine and agropine in these two lines. In addition, it was observed that N. plumbaginifolia tissue lines which did not carry T-DNA, became readily phytohormone autotrophic (habituated) at an early stage in tissue culture.

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.

A new vector derived from Agrobacterium rhizogenes plasmids: a micro-Ri plasmid and its use to construct a mini-Ri plasmid

A new binary vector system has been constructed, based on agropine-type root-inducing plasmid (pRi) left transferred-region border sequences cloned in a plasmid containing the replication origin of another A. rhizogenes plasmid (pArA4a). This micro-pRi has been used to introduce a chimeric kanamycin resistance gene into tobacco plants, vir functions being provided by either octopine or nopaline tumor-inducing plasmids deleted of their own transferred regions. In addition, we show that cloning of pRi EcoRI fragment 15, which contains three open reading frames (which may correspond to loci rolA, B and C), in the micro-Ri vector generates a mini-pRi capable of inducing the proliferation of transformed roots.

Transformation of cucumber (Cucumis sativus L.) plants with Agrobacterium rhizogenes

Transgenic cucumber plants (Cucumis sativus L., cv. 'Straight Eight') were regenerated from roots induced by inoculation of inverted hypocotyl sections with Agrobacterium rhizogenes containing the vector pARC8 in addition to the resident Ri-plasmid. The DNA transferred to the plant from the vector (T-DNA) included a gene which encoded the enzyme neomycin phosphotransferase II, and thus conferred on the plant cells resistance to kanamycin. The transgenic plants looked normal and were positive for the neomycin phosphotransferase II. Southern blot analysis of the transgenic plants revealed that all plants contained vector DNA, but only some of them contained DNA from the Ri plasmid.

Transformation of cultivated tomato by a binary vector in Agrobacterium rhizogenes: transgenic plants with normal phenotypes harbor binary vector T-DNA, but no Ri-plasmid T-DNA

Cultivated tomato was genetically transformed using two procedures. In the first procedure, punctured cotyledons were infected with "disarmed" Agrobacterium tumefaciens strain LBA4404 or with A. rhizogenes strain A4, each containing the binary vector pARC8. The chimeric neomycin phosphotransferase (NPT II) gene on pARC8 conferred on transformed plant cells the ability to grow on medium containing kanamycin. Transformation reproducible yielded kanamycin-resistant transformants in different tomato genotypes. NPT II activity was detected in transformed calli and in transgenic plants. All of these plants were phenotypically normal, fertile and set seeds. Using the second procedure, inverted cotyledons, we recovered transformed tomato plants from A. rhizogenes-induced hairy roots. In this case, all of the transgenic plants exhibited phenotypes similar to hairy root-derived plants reported for other species. Southern blot analysis on these plants revealed that the plant DNA hybridized with both probes representing pARC8-T-DNA, and the T-DNAs of the A4 Ri-plasmid. However, southern analysis on those phenotypically normal transgenic plants from the first procedure revealed that only the pARC8-T-DNA was present in the plant genome, thus indicating that the pARC8-T-DNA integrated into the plant genome independently of the pRi A4-T-DNA. Genetic analysis of these phenotypically normal transgenic plants for the kanamycin-resistance trait showed Mendelian ratios, 3∶1 and 1∶1, for selfed (R1) and in crossed progeny, respectively.