Physical and functional map of supervirulent Agrobacterium tumefaciens tumor-inducing plasmid pTiBo542

An Improved Agrobacterium-Mediated Transformation and Genome-Editing Method for Maize Inbred B104 Using a Ternary Vector System and Immature Embryos

For maize genome-editing and bioengineering, genetic transformation of inbred genotypes is most desired due to the uniformity of genetic background in their progenies. However, most maize inbred lines are recalcitrant to tissue culture and transformation. A public, transformable maize inbred B104 has been widely used for genome editing in recent years. This is primarily due to its high degree of genetic similarity shared with B73, an inbred of the reference genome and parent of many breeding populations. Conventional B104 maize transformation protocol requires 16-22 weeks to produce rooted transgenic plants with an average of 4% transformation frequency (number of T0 plants per 100 infected embryos). In this Method paper, we describe an advanced B104 transformation protocol that requires only 7-10 weeks to generate transgenic plants with an average of 6.4% transformation frequency. Over 66% of transgenic plants carried CRISPR/Cas9-induced indel mutations on the target gene, demonstrating that this protocol can be used for genome editing applications. Following the detailed and stepwise procedure described here, this quick and simplified method using the Agrobacterium ternary vector system consisting of a T-DNA binary vector and a compatible helper plasmid can be readily transferable to interested researchers.

Agrobacterium strains and strain improvement: Present and outlook

Almost 40 years ago the first transgenic plant was generated through Agrobacterium tumefaciens-mediated transformation, which, until now, remains the method of choice for gene delivery into plants. Ever since, optimized Agrobacterium strains have been developed with additional (genetic) modifications that were mostly aimed at enhancing the transformation efficiency, although an optimized strain also exists that reduces unwanted plasmid recombination. As a result, a collection of very useful strains has been created to transform a wide variety of plant species, but has also led to a confusing Agrobacterium strain nomenclature. The latter is often misleading for choosing the best-suited strain for one's transformation purposes. To overcome this issue, we provide a complete overview of the strain classification. We also indicate different strain modifications and their purposes, as well as the obtained results with regard to the transformation process sensu largo. Furthermore, we propose additional improvements of the Agrobacterium-mediated transformation process and consider several worthwhile modifications, for instance, by circumventing a defense response in planta. In this regard, we will discuss pattern-triggered immunity, pathogen-associated molecular pattern detection, hormone homeostasis and signaling, and reactive oxygen species in relationship to Agrobacterium transformation. We will also explore alterations that increase agrobacterial transformation efficiency, reduce plasmid recombination, and improve biocontainment. Finally, we recommend the use of a modular system to best utilize the available knowledge for successful plant transformation.

Effects of Arabidopsis Ku80 deletion on the integration of the left border of T-DNA into plant chromosomal DNA via Agrobacterium tumefaciens

T-DNA integration into plant chromosomal DNA via Agrobacterium tumefaciens can be achieved by exploiting the double-strand break repair system of the host's DNA. However, the detailed mechanism of T-DNA integration remains unclear. Here, a sequence analysis of the junction sequences of T-DNA and chromosomal DNA was performed to assess the mechanism of T-DNA integration. T-DNA was introduced into Arabidopsis wild-type and NHEJ-deficient ku80 mutant plants using the floral dip method; the junctions of the left border (LB) of T-DNA were subsequently analyzed by adapter PCR. The most frequent junction of the LB of T-DNA with chromosomal DNA was of the filler DNA type in both lines. The lengths of direct or inverted repeat sequences within or around the filler DNA sequence were greater in the ku80 mutant. In addition, the frequency of T-DNA integration near a transcription start site was significantly higher in the ku80 mutant. Our observations suggest that the presence of the Ku80 protein affects the location of the integration of T-DNA and the pattern of formation of repeat sequences within or around the filler DNA during LB integration into chromosomal DNA.

Improved G-AgarTrap: A highly efficient transformation method for intact gemmalings of the liverwort Marchantia polymorpha

Liverworts are key species for studies of plant evolution, occupying a basal position among the land plants. Marchantia polymorpha has emerged as a highly studied model liverwort, and many relevant techniques, including genetic transformation, have been established for this species. Agrobacterium-mediated transformation is widely used in many plant species because of its low cost. Recently, we developed a simplified Agrobacterium-mediated method for transforming M. polymorpha, known as AgarTrap (agar-utilized transformation with pouring solutions). The AgarTrap procedure, which involves culturing the liverwort tissue in various solutions on a single solid medium, yields up to a hundred independent transformants. AgarTrap is a simple procedure, requiring minimal expertise, cost, and time. Here, we investigated four factors that influence AgarTrap transformation efficiency: (1) humidity, (2) surfactant in the transformation buffer, (3) Agrobacterium strain, and (4) light/dark condition. We adapted the AgarTrap protocol for transforming intact gemmalings, achieving an exceptionally high transformation efficiency of 97%. The improved AgarTrap method will enhance the molecular biological study of M. polymorpha. Furthermore, this method provides new possibilities for improving transformation techniques for a variety of plant species.

An extra repABC locus in the incRh2 Ti plasmid pTiBo542 exerts incompatibility toward an incRh1 plasmid

Ti/Ri plasmids in pathogenic Agrobacterium species are repABC replicons that are stably maintained by the function of repABC genes. Two Ti plasmids, pTiBo542 and pTiS4, belonging to incRh2 and incRh4 incompatibility groups, respectively, were reported to carry two repABC loci. In the present study, to reveal the roles of the two repABC loci in the two plasmids, we constructed mini-replicons carrying any one or both of the repABC loci (referred to as repABC1 and repABC2 here) and examined their replication and incompatibility properties. The introduction of mini-replicons into A. tumefaciens C58C1 strains suggested that repABC1 functions as replicator genes but repABC2 does not in both the Ti plasmids. Because the components of repABC2 of pTiBo542 have highly similar amino acid and nucleotide sequences to those of the incRh1-type repABC replicon, we introduced repABC2-containing replicons into cells harboring an incRh1 plasmid in order to check their incompatibility traits. As a result, the repABC2-containing replicon expelled the resident incRh1 plasmid, indicating that the extra repABC locus is dispensable for replication and could work as an incompatibility determinant against incRh1 group plasmids. We suggest that the locus contributes to plasmid retention by eliminating the burden of co-existing competitive plasmids in host cells through its incompatibility.

Inducible Expression of Agrobacterium Virulence Gene VirE2 for Stringent Regulation of T-DNA Transfer in Plant Transient Expression Systems

Agrotransfection with viral vectors is an effective solution for the transient production of valuable proteins in plants grown in contained facilities. Transfection methods suitable for field applications are desirable for the production of high-volume products and for the transient molecular reprogramming of plants. The use of genetically modified (GM) Agrobacterium strains for plant transfections faces substantial biosafety issues. The environmental biosafety of GM Agrobacterium strains could be improved by regulating their T-DNA transfer via chemically inducible expression of virE2, one of the essential Agrobacterium virulence genes. In order to identify strong and stringently regulated promoters in Agrobacterium strains, we evaluated isopropyl-β-d-thiogalactoside-inducible promoters Plac, Ptac, PT7/lacO, and PT5/lacOlacO and cumic acid-inducible promoters PlacUV5/CuO, Ptac/CuO, PT5/CuO, and PvirE/CuO. Nicotiana benthamiana plants were transfected with a virE2-deficient A. tumefaciens strain containing transient expression vectors harboring inducible virE2 expression cassettes and containing a marker green fluorescent protein (GFP) gene in their T-DNA region. Evaluation of T-DNA transfer was achieved by counting GFP expression foci on plant leaves. The virE2 expression from cumic acid-induced promoters resulted in 47 to 72% of wild-type T-DNA transfer. Here, we present efficient and tightly regulated promoters for gene expression in A. tumefaciens and a novel approach to address environmental biosafety concerns in agrobiotechnology.

Agrobacterium tumefaciens Gene Transfer: How a Plant Pathogen Hacks the Nuclei of Plant and Nonplant Organisms

Agrobacterium species are soilborne gram-negative bacteria exhibiting predominantly a saprophytic lifestyle. Only a few of these species are capable of parasitic growth on plants, causing either hairy root or crown gall diseases. The core of the infection strategy of pathogenic Agrobacteria is a genetic transformation of the host cell, via stable integration into the host genome of a DNA fragment called T-DNA. This genetic transformation results in oncogenic reprogramming of the host to the benefit of the pathogen. This unique ability of interkingdom DNA transfer was largely used as a tool for genetic engineering. Thus, the artificial host range of Agrobacterium is continuously expanding and includes plant and nonplant organisms. The increasing availability of genomic tools encouraged genome-wide surveys of T-DNA tagged libraries, and the pattern of T-DNA integration in eukaryotic genomes was studied. Therefore, data have been collected in numerous laboratories to attain a better understanding of T-DNA integration mechanisms and potential biases. This review focuses on the intranuclear mechanisms necessary for proper targeting and stable expression of Agrobacterium oncogenic T-DNA in the host cell. More specifically, the role of genome features and the putative involvement of host's transcriptional machinery in relation to the T-DNA integration and effects on gene expression are discussed. Also, the mechanisms underlying T-DNA integration into specific genome compartments is reviewed, and a theoretical model for T-DNA intranuclear targeting is presented.

Agrobacterium-mediated transformation of rice using immature embryos or calli induced from mature seed

Here, we provide comprehensive, highly efficient protocols for Agrobacterium tumefaciens-mediated transformation of a wide range of rice genotypes. Methods that use either immature embryos (japonica and indica rice) or calli (japonica cultivars and the indica cultivar, Kasalath) as a starting material for inoculation with Agrobacterium are described. Immature embryos are pretreated with heat and centrifugal force, which significantly enhances the efficiency of gene transfer, and then infected with Agrobacterium. Callus is induced from mature seeds and infected. Transformed cells proliferated from these tissues are selected on the basis of hygromycin resistance, and transgenic plants are eventually regenerated. A single immature japonica or Kasalath embryo will produce between 10 and 18 independent transgenic plants; for other non-Kasalath indica varieties, the number of transgenic plants expected will be between 5 and 13. For japonica and Kasalath, transformants should be obtained from between 50 and 90% of calli. From inoculation with Agrobacterium to transplanting to soil will take 55 d for japonica and Kasalath, and 74 d for indica other than Kasalath using the immature embryo method, and 50 d for japonica and Kasalath using the callus method.

Agrobacterium-mediated transformation of maize

Maize may be transformed very efficiently using Agrobacterium tumefaciens-mediated methods. The most critical factor in the transformation protocol is the co-cultivation of healthy immature embryos of the correct developmental stage with A. tumefaciens; the embryos should be collected only from vigorous plants grown in well-conditioned glasshouses. With the protocol described here, approximately 50% of immature embryos from the inbred line A188 and 15% from inbred lines A634, H99 and W117 will produce transformants. About half of the transformed plants are expected to carry one or two copies of the transgenes, which are inherited by the progeny in a mendelian fashion. More than 90% of transformants are expected to be normal in morphology. The protocol takes about 3 months from the start of co-cultivation to the planting of transformants into pots.

A highly selectable and highly transferable Ti plasmid to study conjugal host range and Ti plasmid dissemination in complex ecosystems

A conjugal donor system, ST2, was constructed to study the conjugal dissemination of a Ti plasmid to wild-type recipient bacteria in vitro and in situ. The system consisted of a polyauxotrophic derivative of C58 harboring a hyperconjugative and highly selectable Ti plasmid, pSTiEGK, which was constructed by inserting a multiple antibiotic resistance cassette in the traM- mcpA region of pTiC58Delta accR. ST2 transfers pSTiEGK constitutively at frequencies up to 10(-1) to plasmidless Agrobacterium recipients. The host range of pSTiEGK includes all the known genomic species of Agrobacterium, indigenous soil agrobacteria and some Rhizobium and Phyllobacterium spp. All transconjugants became pathogenic upon acquisition of the Ti plasmid and were also able to transfer pSTiEGK by conjugation. This host range was indistinguishable from that of its wild-type parent pTiC58, and therefore pSTiEGK constitute a valid proxy to study the dissemination of Ti plasmids directly in the environment. Transconjugants can be selected on a combination of four antibiotics, which efficiently prevents the growth of the indigenous microbiota present in complex environments. The transfer of pSTiEGK to members of the genus Agrobacterium was affected primarily by the plasmid content of the recipient strain (10(3)- to 10(5)-fold reduction), e.g., the presence of incompatible plasmids. As a consequence, a species should be considered permissive to Ti transfer whenever one permissive isolate is found.

Agrobacterium-mediated plant transformation: the biology behind the "gene-jockeying" tool

Agrobacterium tumefaciens and related Agrobacterium species have been known as plant pathogens since the beginning of the 20th century. However, only in the past two decades has the ability of Agrobacterium to transfer DNA to plant cells been harnessed for the purposes of plant genetic engineering. Since the initial reports in the early 1980s using Agrobacterium to generate transgenic plants, scientists have attempted to improve this "natural genetic engineer" for biotechnology purposes. Some of these modifications have resulted in extending the host range of the bacterium to economically important crop species. However, in most instances, major improvements involved alterations in plant tissue culture transformation and regeneration conditions rather than manipulation of bacterial or host genes. Agrobacterium-mediated plant transformation is a highly complex and evolved process involving genetic determinants of both the bacterium and the host plant cell. In this article, I review some of the basic biology concerned with Agrobacterium-mediated genetic transformation. Knowledge of fundamental biological principles embracing both the host and the pathogen have been and will continue to be key to extending the utility of Agrobacterium for genetic engineering purposes.

Efficient vir gene induction in Agrobacterium tumefaciens requires virA, virG, and vir box from the same Ti plasmid

The vir genes of octopine, nopaline, and L,L-succinamopine Ti plasmids exhibit structural and functional similarities. However, we observed differences in the interactions between octopine and nopaline vir components. The induction of an octopine virE(A6)::lacZ fusion (pSM358cd) was 2.3-fold higher in an octopine strain (A348) than in a nopaline strain (C58). Supplementation of the octopine virG(A6) in a nopaline strain with pSM358 did not completely restore virE(A6) induction. However, addition of the octopine virA(A6) to the above strain increased virE(A6) induction to a level almost comparable to that in octopine strains. In a reciprocal analysis, the induction of a nopaline virE(C58)::cat fusion (pUCD1553) was two- to threefold higher in nopaline (C58 and T37) strains than in octopine (A348 and Ach5) and L,L-succinamopine (A281) strains. Supplementation of nopaline virA(C58) and virG(C58) in an octopine strain (A348) harboring pUCD1553 increased induction levels of virE(C58)::cat fusion to a level comparable to that in a nopaline strain (C58). Our results suggest that octopine and L,L-succinamopine VirG proteins induce the octopine virE(A6) more efficiently than they do the nopaline virE(C58). Conversely, the nopaline VirG protein induces the nopaline virE(C58) more efficiently than it does the octopine virE(A6). The ability of Bo542 virG to bring about supervirulence in tobacco is observed for an octopine vir helper (LBA4404) but not for a nopaline vir helper (PMP90). Our analyses reveal that quantitative differences exist in the interactions between VirG and vir boxes of different Ti plasmids. Efficient vir gene induction in octopine and nopaline strains requires virA, virG, and vir boxes from the respective Ti plasmids.

Construction of a derivative of Agrobacterium tumefaciens C58 that does not mutate to tetracycline resistance

Agrobacterium tumefaciens C58 mutates to tetracycline resistance at high frequency, complicating the use of many broad-host-range cloning and binary vectors that code for resistance to this antibiotic as the selection marker. Such mutations are associated with a resistant gene unit, tetC58, that is present in the genome of this strain. By deleting the tetC58 locus, we constructed NTL4, a derivative of C58 that no longer mutates to tetracycline resistance. The deletion had no detectable effect on genetic or physiological traits of NTL4 or on the ability of this strain to transform plants.

Incompatibility properties of tartrate utilization plasmids derived from Agrobacterium vitis strains

The incompatibility properties of two tumor-inducing (Ti) and seven tartrate (Tr) plasmids, derived from various Agrobacterium vitis strains, were characterized using incRh1, incRh2, incRh3, and incRh4 clones which were established for the identification and classification of Agrobacterium plasmids. The tested A. vitis plasmids could be allocated into four groups on the basis of their incompatibility with incRh1, incRh2, and incRh4 clones. The two octopine tumor-inducing plasmids, pTiAT6 and pTiAB3, expressed incompatibility both to incRh1 and to incRh2 clones. Three pTrs could not be allocated either to incRh1-4 and incAg1 or to the wide-host-range incP1, incQ, and incW groups.

Transformation of rice mediated by Agrobacterium tumefaciens

Agrobacterium tumefaciens has been routinely utilized in gene transfer to dicotyledonous plants, but monocotyledonous plants including important cereals were thought to be recalcitrant to this technology as they were outside the host range of crown gall. Various challenges to infect monocotyledons including rice with Agrobacterium had been made in many laboratories, but the results were not conclusive until recently. Efficient transformation protocols mediated by Agrobacterium were reported for rice in 1994 and 1996. A key point in the protocols was the fact that tissues consisting of actively dividing, embryonic cells, such as immature embryos and calli induced from scutella, were co-cultivated with Agrobacterium in the presence of acetosyringonc, which is a potent inducer of the virulence genes. It is now clear that Agrobacterium is capable of transferring DNA to monocotyledons if tissues containing 'competent' cells are infected. The studies of transformation of rice suggested that numerous factors including genotype of plants, types and ages of tissues inoculated, kind of vectors, strains of Agrobacterium, selection marker genes and selective agents, and various conditions of tissue culture, are of critical importance. Advantages of the Agrobacterium-mediated transformation in rice, like on dicotyledons, include the transfer of pieces of DNA with defined ends with minimal rearrangements, the transfer of relatively large segments of DNA, the integration of small numbers of copies of genes into plant chromosomes, and high quality and fertility of transgenic plants. Delivery of foreign DNA to rice plants via A. tumefaciens is a routine technique in a growing number of laboratories. This technique will allow the genetic improvement of diverse varieties of rice, as well as studies of many aspects of the molecular biology of rice.

Sequence and distribution of IS1312: evidence for horizontal DNA transfer from Rhizobium meliloti to Agrobacterium tumefaciens

Two novel insertion sequences, IS1312 and IS1313, were found in pTiBo542, the Ti plasmid of Agrobacterium tumefaciens strains Bo542 and A281. Nucleotide sequencing and Southern hybridization revealed that IS1312 and IS1313 are homologous to Rhizobium meliloti ISRm1 and ISRm2, respectively. IS1312, ISRm1, and another Agrobacterium insertion sequence, IS426, belong to the same IS3 family of insertion sequences; however, IS1312 is more closely related to the Rhizobium ISRm1 than it is to the Agrobacterium IS426. The distribution patterns of these insertion elements and their sequence similarities suggest that IS1312 and IS1313 were horizontally transferred from R. meliloti to A. tumefaciens.

Mapping and genetic organization of pTiChry5, a novel Ti plasmid from a highly virulent Agrobacterium tumefaciens strain

Agrobacterium tumefaciens Chry5, a wild-type strain originally isolated from chrysanthemum, is unusually tumorigenic, particularly on soybean. We have mapped the Chry5 Ti plasmid by genomic walking and restriction endonuclease analysis, and have located its virulence, T-DNA, plasmid incompatibility, and L,L-succinamopine utilization loci. Southern analysis has revealed that about 85% of the Chry5 Ti plasmid is highly homologous to another Ti plasmid, pTiBo542. Although all the functions that we have located on pTiChry5 are encoded by pTiBo542-homologous regions, the two Ti plasmids differ in their genetic organization. The overall patterns of restriction sites in the plasmids also differ, with the exception of an approximately 12 kb segment of the virulence region, where the BamHI sites appear to be conserved. Complementation analysis has shown that deletion of a DNA segment which flanks the oncogenic T-DNA results in severe attenuation of virulence. This region also contains a sequence that is repeated in the Chry5 genome outside the Ti plasmid, and that is widely distributed in the Rhizobiaceae.

Agrobacterium-mediated transformation of Citrus stem segments and regeneration of transgenic plants

A method for Agrobacterium-mediated transformation of Citrus and organogenic regeneration of transgenic plants is reported. Internodal stem segments were co-cultured with Agrobacterium harboring binary vectors that contained the genes for the scorable marker ß-glucuronidase (GUS) and the selectable marker NPT-II. A low but significant percentage (≤ 5%) of the shoots regenerated in the presence of 100 μg/ml kanamycin were GUS(+). Polymerase chain reaction (PCR) analysis confirmed that GUS(+) shoots contained T-DNA. Two plants established in soil were shown to be transgenic by Southern analysis.

Expression of the GUS-gene in the monocot tulip after introduction by particle bombardment and Agrobacterium

Gene transfer to the monocotyledon tulip (Tulipa sp. L.) was obtained both by particle bombardment and Agrobacterium transformation. Using a Particle Delivery System, transient expression of the reporter gene for ßglucuronidase was demonstrated. It was shown that the CAMV 35S as well as the TR2' promoter were active in flower stem expiants. Various wildtype and disarmed Agrobacterium strains, harbouring the 35S GUSintron gene on a binary plasmid, were used for infection of flower stem expiants of 7 cultivars and 7 botanical Tulipa species. In nine genotypes the GUSintron gene was expressed, despite the fact that tulip tissue did not produce detectable amounts of virulence-inducing substances. Agrobacterium rhizogenes appeared to be most effective in gene transfer to tulip tissue.

Characterization of the supervirulent virG gene of the Agrobacterium tumefaciens plasmid pTiBo542

The virG gene of the Agrobacterium tumefaciens Ti plasmid pTiBo542 has previously been reported to elicit stronger vir gene expression than its counterpart in the pTiA6 plasmid, a property we call the "superactivator" phenotype. The DNA sequence of the pTiBo542 virG gene was determined and compared to that of the pTiA6 gene. The DNA sequences of these genes differ at 16 positions: two differences are in the promoter regions, 12 are in the coding regions, and two are in the 3' untranslated regions. The 3' end of the pTiA6 virG gene also contains a probable insertion sequence that is not found downstream of the pTiBo542 gene. The base pair differences, in the two coding regions result in only two amino acid differences, both in the amino-terminal halves of the proteins. Five hybrid virG genes were constructed and used to activate the expression of a virB::lacZ gene fusion. Differences in the coding regions of these genes accounted for most of the superactivator phenotype, while differences at the promoter and 3' untranslated regions also contributed. These findings suggest that the properties of these VirG proteins and their quantities are important for vir gene induction, and also suggest a long-term selective pressure for mutations contributing to differences between these two genes.

Genetic transformation of Chrysanthemum using wild type Agrobacterium strains; strain and cultivar specificity

To develop an Agrobacterium mediated transformation protocol for chrysanthemum we studied the transformation efficiency of commonly used A.tumefaciens strains on 14 genotypes by comparing tumour size and frequency. One genotype was analyzed in detail using 14 strains of both A.tumefaciens and A.rhizogenes. Only a few genotype/strain combinations resulted in significant tumour formation. Especially 0-type strains were highly efficient. An 0-type strain was used to transfer genes for neomycine phosphotransferase (NPT II) and ß-glucuronidase (GUS) to a susceptible cultivar. Transfer of the GUS gene was confirmed by using the Polymerase Chain Reaction (PCR).

Transformation of cultured cells of Chenopodium quinoa by binary vectors that carry a fragment of DNA from the virulence region of pTiBo542

A 15.2-kb KpnI fragment from the virulence region of pTiBo542, the Ti plasmid harbored by Agrobacterium tumefaciens strain A281, was introduced into binary vectors. The fragment contained the virB, virC and virG genes, and it is known to have the ability to increase the virulence of strains of A. tumefaciens. The strains of A. tumefaciens that carried the resulting plasmids were able to transform cells in a suspension culture of Chenopodium quinoa Willd cells which were not transformable by common vectors. Although the sizes of the plasmids was very large, a foreign segment of DNA was introduced into one of the plasmids by homologous recombination in A. tumefaciens cells, and the segment was subsequently transferred to plant cells.

Agrobacterium plasmids encode structurally and functionally different loci for catabolism of agrocinopine-type opines

Agrobacterium tumefaciens strains C58, T37, K827 and J73, A. rhizogenes strains A4 and 15834, and A. radiobacter strain K299 were all susceptible to agrocin 84 and this sensitivity was enhanced in each case by addition of agrocinopines A and B. Analysis of transconjugants showed that sensitivity of strain A4 to agrocin 84 was encoded by pArA4a and not by the rhizogenic plasmid, pRiA4. The acc region of the A. tumefaciens nopaline-type Ti plasmid pTiC58, contained on the recombinant plasmid pTHH206, hybridized strongly to restriction fragments of plasmids from strains T37, K827, J73 and K299. Hybridizing fragment patterns generated with BamHI and EcoRI were identical among the four Ti plasmids while pAtK299 showed restriction fragment length polymorphisms at acc with the two enzymes. At moderate stringency, the pTiC58 acc region hybridized weakly to a single restriction fragment from the Ar plasmid of A. rhizogenes strain A4, but not to pTiBo542, which encodes catabolism of the closely related opines agrocinopines C and D. Plasmid pAtK84b of A. radiobacter strain K84 is induced for conjugal transfer by agrocinopines A and B. However, no hybridization was detected between this plasmid and acc from pTiC58 under conditions of moderate stringency. Like pTiC58, pAtK84b conferred transport of agrocinopines A and B on its host bacteria despite the absence of detectable sequence homology with the pTiC58-derived acc probe. However, unlike pTiC58, pAtK84b failed to confer sensitivity to or uptake of agrocin 84 on its bacterial host. These results indicate that at least four distinguishable systems exist for catabolism of the two agrocinopine opine families with the prototype locus, exemplified by acc from pTiC58, being strongly conserved among nopaline-type Ti plasmids.

Genetic characterization of a double-flowered tobacco plant obtained in a transformation experiment

A leaf-disk transformation experiment was performed with tobacco (Nicotiana tabacum L.) using a binary vector and a strain of Agrobacterium tumefaciens that carried a wild-type Ti-plasmid, pTiBo542. Although the majority of kanamycin-resistant, transgenic plants was morphologically normal, one of the plants was double-flowered and had a slightly wavy stem and leaves whose edges were bent slightly upwards. The abnormal morphology was controlled by a single, dominant Mendelian gene. Young plants that carried this gene were distinguishable from normal plants at the stage of cotyledons. The homozygotes, with respect to this gene, were more seriously deformed than the heterozygotes. DNA segments derived from the binary vector and from the TL-and TR-DNA of pTiBo542 were detected in the double-flowered plant, but the T-DNA genes involved in biosynthesis of phytohormones were absent from the plant. The abnormal morphology, the resistance to kanamycin, and the segments of foreign DNA were genetically linked, and the linkage was very tight, at least between the abnormal morphology and the resistance to kanamycin; the meiotic recombination frequency was less than 0.02%, if recombination occurred at all.

Agrobacterium-mediated DNA transfer in sugar pine

DNA transfer using Agrobacterium tumefaciens has been demonstrated in sugar pine, Pinus lambertiana Dougl. Shoots derived from cytokinin-treated cotyledons formed galls after inoculation with A. tumefaciens strains containing the plasmid pTiBo542. A selectable marker, neomycin phosphotransferase II, conferring resistance to kanamycin, was transferred into sugar pine using a binary armed vector system. Callus proliferated from the galls grew without hormones and in some cases, kanamycin-resistant callus could be cultured. Southern blots provided evidence of physical transfer of T-DNA and the nptII gene. Expression of the nptII gene under control of the nos promoter was demonstrated by neomycin phosphotransferase assays. Several aspects of DNA transfer were similar to those previously observed in angiosperms transformed by A. tumefaciens. This is the first evidence for DNA transfer by Agrobacterium in this species and the first physical evidence for transfer in any pine. These results bring us closer to genetic engineering in this commercially important genus of forest trees.

Isolation of the replication DNA region from a Rhizobium plasmid and examination of its potential as a replicon for Rhizobiaceae cloning vectors

The DNA region essential for replication and stability of a native plasmid (pTM5) from Rhizobium sp. (Hedysarum) has been identified and isolated within a 5.4-kb PstI restriction fragment. The isolation of this region was accomplished by cloning endonuclease-restricted pTM5 DNA into a ColE1-type replicon and selecting the recombinant plasmids containing the pTM5 replicator (pTM5 derivative plasmids) by their ability to replicate in Rhizobium. DNA homology studies revealed that pTM5-like replicons are present in cryptic plasmids from some Rhizobium sp. (Hedysarum) strains but not in plasmids from strains of other Rhizobium species or Agrobacterium tumefaciens. The pTM5 derivative plasmids were able to replicate in Escherichia coli and A. tumefaciens and in a wide range of Rhizobium species. On the basis of stability assays in the absence of antibiotic selective pressure, the pTM5 derivative plasmids were shown to be highly stable in both free-living and symbiotic cells of Rhizobium sp. (Hedysarum). The stability of these plasmids in other species of Rhizobium and in A. tumefaciens varied depending on the host and on the plasmid. Most pTM5 derivative plasmids tested showed significantly higher symbiotic stability than RK2 derivative plasmids pRK290 and pAL618 in Rhizobium sp. (Hedysarum), R. meliloti, and R. leguminosarum by. phaseoli. Consequently, we consider that the constructed pTM5 derivative plasmids are potentially useful as cloning vectors for Rhizobiaceae.

Specificity of strain and genotype in the susceptibility of pea to Agrobacterium tumefaciens

To determine the best combination for potential use in transformation of Pisum sativum L., 13 genotypes were inoculated with wild-type Agrobacterium tumefaciens strains A281, C58 and Ach5. A281 appeared to be the most virulent strain, as determined by size and number of tumours, followed by C58 and Ach5. Genotypes differed considerably in their response to inoculation and genotype x strain interaction was evident. Genotypes also responded differently to in vivo or in vitro inoculation. Axenic calli from tumours could be grown on hormone-free medium and the presence of the specific opines for each strain in the callus indicated successful transfer and expression of T-DNA. Southern blot analysis of DNA from callus of A281-inoculated material showed that both TR and TL T-DNA had been incorporated into the pea genome.

Transformation of white spruce and other conifer species byAgrobacterium tumefaciens

Studies of the ability ofAgrobacterium to transform white spruce (Picea glauca), Engelmann spruce (P. engelmanni), Sitka spruce (P. sitchensis) and Douglas-fir (Pseudotsuga menziesii) showed frequencies of gall formation from 0-80% depending upon the strain ofAgrobacterium, and the conifer species. Thirty sixA. tumefaciens strains and oneA. rhizogenes strain were tested on 6 month old white spruce seedlings. NineA. tumefaciens strains induced gall formation on more than 50% of the inoculated trees and at greater than 10% of the inoculated sites. One strain, B2/74 gave rise to galls at 28% of the inoculated sites on white spruce and induced the highest overall frequency of gall formation on all the conifer species tested. Relative frequency of gall formation was consistent among species, although the overall frequency was much higher on Douglas-fir. Of the well characterized strains for which disarmed derivatives are available only A281 (carrying the supervirulent tumor inducing plasmid, pTiBo542) gave efficient transformation. Stable integration of T-DNA encoded genes has been confirmed by the expression of opine synthesis and hormone autonomous growth. The transfer and long-term stable expression of kanamycin resistance and firefly luciferase activity using binary vector systems was also achieved.

Isolation and characterization of an ipt gene from the Ti plasmid Bo542

A 1.9 kb clone of the T-DNA region of the Agrobacterium tumefaciens Ti plasmid Bo542 which exhibited homology to the isopentenyl transferase (ipt) locus of pTiA6 was identified by low stringency DNA hybridization. Introduction of this segment of pTiBo542 DNA into cells of Nicotiana tabacum or N. glauca caused tumor formation in vivo, and allowed hormone independent growth in vitro. Furthermore, this DNA segment complemented ipt mutant strains of A. tumefaciens, restoring their ability to cause tumors on Kalanchöe leaves and tomato stems. The complete DNA sequence of this segment has been determined, revealing an open reading frame homologous to other known Agrobacterium ipt genes.

Sequence determination and characterization of the replicator region in the tumor-inducing plasmid pTiB6S3

The replicator region of the 195-kilobase-pair (kb) tumor-inducing plasmid pTiB6S3 was previously identified by isolation of a 6.8-kb miniplasmid (B.P. Koekman, P.J.J. Hooykaas, and R.A. Schilperoort, Plasmid 7:119-132, 1982). This miniplasmid was joined to ColE1-based vectors and subjected to mutagenesis. The resulting mutant plasmids were examined for their ability to replicate autonomously in Agrobacterium tumefaciens. It was found that a 4.2-kb region was sufficient for displaying replication characteristics similar to those of the parental pTiB6S3. Nucleotide sequence analysis of this 4.2-kb region revealed the presence of three possible reading frames in the same direction (repA, repB, and repC). Proteins coded for by these frames were identified by in vitro synthesis in a coupled transcription-translation system. The replicating ability became attenuated by repA and repB mutations but was completely abolished by repC mutations. The size, arrangement, and mutational effects of the three rep genes were quite similar to those of the rep genes that were previously identified in the hairy root-inducing plasmid pRiA4b. However, defects caused by rep mutations in one plasmid were unable to be complemented by corresponding functions in the other plasmid.

Transformation of Soybean Cells Using Mixed Strains of Agrobacterium tumefaciens and Phenolic Compounds

Cotyledon explants from germinated 1-day-old soybean seedling were inoculated with single or mixed strains of Agrobacterium tumefaciens. Mixed-strain infections with the supervirulent L,L-succinamopine type strain A281 (pTiBo542) and strain LBA4404 carrying an octopine type virulence (vir) region and a binary vector (pBin6) with a chimeric gene for kanamycin detoxification gave rise to tumors of which 25% were both kanamycin resistant and capable of hormone-independent growth. Singlestrain inoculations with LBA4404 (pBin6) failed to give rise to kanamycin-resistant callus. Syringaldehyde, a compound which induces vir genes carried on the Ti plasmid, increased the number of galls incited on excised cotyledons by the weakly virulent octopine type strain A348 (pTiA6). Similar results were obtained with whole plants treated with this strain in the presence of the vir-inducing compound acetosyringone. Our results indicate that the recovery of transformed soybean cells can be enabled in some instances by coinfecting with a supervirulent strain or in other instances promoted by adding a phenolic compound to the inoculum.

Characterization of Agrobacterium tumefaciens virulence proteins induced by the plant factor acetosyringone

The Ti plasmid virulence (vir) loci encode functions essential for the transfer of the T-DNA element from Agrobacterium tumefaciens to plant cells. The expression of these loci is specifically signaled by plant phenolics such as acetosyringone. Here, we characterize the protein products that are induced in Agrobacterium grown in the presence of acetosyringone. More than 10 to 15 proteins are induced in strains harboring different Ti plasmids. Two general classes of acetosyringone-induced proteins are observed, encoded either within or outside the vir region. Synthesis of both classes of proteins requires acetosyringone and the products of the vir regulatory genes A and G. Those proteins encoded outside the vir region define a novel category of proteins, the virulence-related proteins, which are both chromosomally and Ti plasmid-encoded. The molecular weight and subcellular localization of several pTiA6 vir-induced proteins are identified. The most abundant induced protein has a molecular weight of 65,000, and is the single product of the virE locus; this protein distributes into both cell envelope and soluble fractions. Three proteins with molecular weights of approximately 33,000, 80,000 and 25,000 fractionate with the cell envelope and are encoded by genes within the 5' half of the virB locus. The envelope localization of the virB proteins suggests that they play a role in directing T-DNA transfer events that occur at the bacterial surface.

Genes responsible for the supervirulence phenotype of Agrobacterium tumefaciens A281

Agrobacterium tumefaciens A281 induces large, rapidly appearing tumors on a variety of plants and has a wider host range than other strains of A. tumefaciens. By using Tn3HoHo1 transposon mutagenesis and complementation analysis, a 2.5-kilobase DNA fragment which is responsible for the supervirulence phenotype was identified in the virulence (vir) region of the Ti plasmid. This fragment contains the virG locus, as well as the 3' end of the virB operon. A clone of this fragment conferred the supervirulence phenotype on A348, a nonsupervirulent strain. The increased virulence was correlated with an increased expression of vir genes, which could be achieved by introducing an extra copy of the transcriptional activator virG or the supervirulence region for maximum virulence. The virulence of the supervirulent strain A281 could be increased even further if the entire virB operon was added in addition to the virG operon. A plasmid, pToK47, containing virB and virG increased the virulence of all A. tumefaciens strains into which the plasmid was introduced. These data suggest that a highly virulent binary vector system can be constructed which might prove especially useful in the transformation of certain higher plants.

Virulence of Agrobacterium tumefaciens Strain A281 on Legumes

This study addresses the basis of host range on legumes of Agrobacterium tumefaciens strain A281, an l,l-succinamopine strain. We tested virulence of T-DNA and vir region constructs from this tumor-inducing (Ti) plasmid with complementary Ti plasmid regions from heterologous nopaline and octopine strains.

The hypervirulence of Agrobacterium tumefaciens A281 is encoded in a region of pTiBo542 outside of T-DNA

We used a binary-vector strategy to study the hypervirulence of Agrobacterium tumefaciens A281, an L,L-succinamopine strain. Strain A281 is hypervirulent on several solanaceous plants. We constructed plasmids (pCS65 and pCS277) carrying either the transferred DNA (T-DNA) or the remainder of the tumor-inducing (Ti) plasmid (pEHA101) from this strain and tested each of these constructs in trans with complementary regions from heterologous Ti plasmids. Hypervirulence on tobacco could be reconstructed in a bipartite strain with the L,L-succinamopine T-DNA and the vir region on separate plasmids. pEHA101 was able to complement octopine T-DNA to hypervirulence on tobacco and tomato plants. Nopaline T-DNA was complemented better on tomato plants by pEHA101 than it was by its own nopaline vir region, but not to hypervirulence. L,L-Succinamopine T-DNA could not be complemented to hypervirulence on tobacco and tomato plants with either heterologous vir region. From these results we suggest that the hypervirulence of strain A281 is due to non-T-DNA sequences on the Ti plasmid.