Isolation and properties of transfer regulatory mutants of the nopaline Ti-plasmid pTiC58

Summary Conjugal transfer of the nopaline Ti-plasmid pTiC58 is inducible by the phosphorylated opines, agrocinopines A and B. Although the uninduced level of transfer is negligible (< 10^–7 per donor), some transconjugants have been isolated from crosses performed in the absence of agrocinopine. These transconjugants harbour mutant Ti-plasmids that transfer constitutively (>10^–3 per donor). These mutants have several other correlated phenotypes including constitutive uptake of agrocinopine A, supersensitivity to agrocin 84 and the ability to prevent the excretion of agrocin 84 when they are present in the same cell as the agrocin 84 biosynthetic plasmid pAt-84a.     

Studies on the structure of cointegrates between octopine and nopaline Ti-plasmids and their tumour-inducing properties

Stable cointegrates between incRh-1 octopine (Ach5) and nopaline (C58) Ti-plasmids, present in ten independently isolated Agrobacterium tumefaciens strains, showed identical restriction endonuclease patterns. Each cointegration event had taken place in the common sequence between the T-regions of both Ti-plasmids. This illustrates a high preference for this region when used in the formation of cointegrates. Four crown gall tissues, obtained after transformation of Nicotiana tabacum cells by one of the mutants, were analysed by using Southern blot analysis for their T-DNA structure. The borders of T-DNA frequently appeared to differ from T-DNA borders previously detected in tumour tissues that had been induced by Agrobacterium strain C58 or Ach5. Therefore, it was concluded that possibly a less stringent mechanism exists for the integration into plant DNA of T-DNA, derived from a composite (octopine/nopaline) T-region than for integration of T-DNA from a normal (octopine or nopaline) T-region.Abbreviations Agr sensitivity to agrocin 84 - Ape phage Apl exclusion - Cb resistance to carbenicillin - Occ octopine catabolism - Ocs octopine synthesis - Noc nopaline catabolism - Nos nopaline synthesis - Rec recombination - Tra transfer - Vir virulence     

Secretion of trans-zeatin by Agrobacterium tumefaciens: A function determined by the nopaline Ti plasmid

Production of the plant cytokinin, trans-zeatin, by a number of strains of Agrobacterium tumefaciens was measured by a combination of traceenrichment, HPLC and radioimmunoassay and confirmed by mass spectrometry. Secretion of trans-zeatin into a culture medium is a constitutive function of those strains which harbor a nopaline Ti plasmid. Strains cured of the nopaline Ti plasmid and those which harbor octopine or agropine plasmids are non-producers. Reacquisition of nopaline plasmids by cured strains restores production.     

The interaction of Agrobacterium Ti-plasmid DNA and plant cells

The tumour-inducing plasmids of Agrobacterium tumefaciens (Ti-plasmids) reveal several interesting properties. They are catabolic plasmids, which, instead of rendering Agrobacterium strains capable of catabolizing compounds found in Nature, force a plant to synthesize these catabolites (denoted 'opines'). This situation is obtained by insertion of a segment of the Ti-plasmid (the T-DNA) into the plant nucleus, where T-DNA genes become expressed and intervene in the biosynthesis of these opines. Cells containing the T-DNA behave as neoplasms (crown gall cells). Southern blotting shows that the insertion process responsible for T-DNA transfer probably recognizes special sequences on the T-DNA since the length of the T-DNA segment observed in different, independently isolated tumour lines was found to be similar. For the nopaline Ti-plasmids both left-hand and right-hand borders were found to be constant. For the octopine plasmid the left border was constant and at least two classes of right-hand borders were found. Upon redifferentiation of the transformed plant cells, the T-DNA was found to be conserved in all somatic cells examined. However, small deletions at the border fragments of the T-DNA have been observed. The exact arrangement and copy number of the T-DNA in a nucleus is still under study, but genomic cloning has already revealed that an interspersed tandem arrangement is dominant in nopaline tumours. Clones containing both the right border of one T-DNA and the left border of the neighbouring tandem T-DNA were isolated. In order to identify the different T-plasmid encoded functions an extensive use was made of transposon insertion mutagenesis. When an antibiotic resistance transposon was inserted into the non-essential regions of the T-DNA, a linked transfer to the plant DNA of the transposon together with the T-DNA was observed. This indicates that Ti-plasmids are possible vectors for genetic engineering in plants. A strategy is described for insertion of any cloned DNA segment into the T-DNA.     

Arginine catabolism: a new function of both octopine and nopaline Ti-plasmids of Agrobacterium.

Summary The oncogenic plasmids of Agrobacterium, the Ti-plasmids, carry genes that enable their bacterial host to catabolize opines. Opines are unusual amino acid derivatives that are only produced in crown gall tumours incited by oncogenic strains of Agrobacterium. The 2 opines, octopine and nopaline, are degraded by Agrobacterium strains carrying the octopine or the nopoline Ti-plasmid, respectively, to arginine and pyruvic acid, and to arginine and -ketoglutaric acid. In this paper it is shown that the Ti-plasmids carry gene(s) involved in the utilisation of arginine as a carbon source. Strains harbouring wild type octopine or nopaline Ti-plasmids in the chromosomal context of strain C58C1 do not grow on arginine as a carbon source. However, they are able to grow on arginine provided that they are induced, or constitutive for opine catabolism. The features of ornithine utilisation are identical. The gene(s) involved in arginine and ornithine utilization in C58C1 (pTi-oct) or C58C1 (pTi-nop) are under the control of the regulator gene that controls octopine or nopaline catabolism. A tentative pathway of octopine utilization is proposed, in which at least two steps are Ti-plasmid coded, and probably belong to the same operon: 1-scission of octopine into arginine and pyruvic acid 2-transformation of an arginine derivative (GSA?) to glutamic acid.Arginine utilization as a carbon source is therefore a new function of the Ti-plasmid. As this function is not inducible by arginine but by opines, it provides a method for selecting regulatory mutants of opine catabolism in the genetic background of strain C58.     

Broad-Host-Range Agrocin of Agrobacterium tumefaciens

Eighteen strains of Agrobacterium tumefaciens isolated from crown galls were tested for agrocin production. Of six agrocin-producing strains, one (D286) produced a broad-host-range agrocin active against strains carrying nopaline, octopine, and agropine type Ti plasmids. Sensitivity to agrocin D286 was found to map in the 11- to 18-megadalton region of the nopaline Ti plasmid pTiC58. The agrocin was partially purified, and its physical characteristics were consistent with its being a nucleotide, as is agrocin 84. Agrocin D286 was shown to inhibit DNA, RNA, and protein syntheses. Strain D286 spontaneously lost its pathogenicity, and its potential for use in the biological control of crown gall is discussed.     

Physical map of the vitopine Ti plasmid pTiS4.

Within the Agrobacterium vitis group the vitopine strains represent a special subclass. Vitopine bacteria carry Ti plasmids with little or no homology with the well-characterized T-DNAs of Agrobacterium tumefaciens or Agrobacterium rhizogenes. The 262-kb Ti plasmid of the vitopine strain S4 was cloned and mapped. Homology studies with the octopine Ti plasmid pTiAch5, the nopaline Ti plasmid pTiC58, and the agropine/mannopine Ri plasmid pRiHRI identified several regions of homology. The origin of replication was localized to within 2.5 kb.     

virA and virG are the Ti-plasmid functions required for chemotaxis of Agrobacterium tumefaciens towards acetosyringone

Octopine and nopaline Ti-plasmids confer upon Agrobacterium tumefaciens C58C1 the ability to respond chemotactically to the vir-inducing phenolic wound exudate, acetosyringone. A. tumefaciens C58C1 containing Ti-plasmids with Tn5 insertions in virB, C, D or E exhibited marked chemotaxis towards acetosyringone. However, Ti-plasmids with mutations in virA or virG were unable to confer the responsive phenotype. Of the cosmid clones pVK219 (virAB) pVK221 (virBGC) pVK225 (virGCDE) and pVK257 (virABGC) mobilized to cured A. tumefaciens C58C1, only pVK257 bestowed acetosyringone chemotaxis. virA and virG are thus required for chemotaxis of A. tumefaciens towards acetosyringone. This suggests a multifunctional role for virA and virG: at low concentrations of acetosyringone they mediate chemotaxis and at higher concentrations they effect vir-induction.     

Strain and cultivar specificity in the Agrobacterium-soybean interaction

The response of Glycine max., G. soja and G. canescens genotypes to inoculation with different Agrobacterium strains was assessed. Percent visual tumor formation and tumor size varied widely among species and genotypes. Susceptible genotypes displayed a heightened response to nopaline strains of A. tumefaciens, relative to octopine, agropine, and A. rhizogenes strains. A nopaline strain engineered to contain a chimeric neomycin phosphotransferase II gene conferred kanamycin resistance to soybean tissue at kanamycine levels as high as 300 g/ml.     

Environmental conditions differentially affect vir gene induction in different Agrobacterium strains. Role of the VirA sensor protein

The induction of vir gene expression in different types of Agrobacterium strains shows different pH sensitivity profiles. The pH sensitivity pattern demonstrated by octopine Ti strains was similar to that of a supervirulent leucinopine Ti strain, whereas this was different from that shown by nopaline Ti strains and agropine Ri strains. Data are given which indicate that these differences are due to different properties of the virA genes of these wild types. An exceptional case was formed by strains with the limited-host-range plasmid pTiAG57 which showed AS-dependent vir induction only if reduced inoculum sizes were used and the temperature was 28°C or below.     

Diversity of Opines and Opine-Catabolizing Bacteria Isolated from Naturally Occurring Crown Gall Tumors

The diversity of opines from 43 naturally occurring crown gall tumors on several plant species was analyzed for the presence of agropine, chrysopine, iminodiacid, an unidentified leucinopine-like iminodiacid (IDA-B), mannopine, octopine, nopaline, DL- and LL-succinamopine, leucinopine and heliopine. Opine utilization patterns of agrobacteria and fluorescent pseudomonads resident in a tumor were then analyzed and compared for agreement with the opine isolated from that tumor. Nopaline was the most common opine found and was detected in tumors from cherry, blackberry, grape, and plum. Octopine was not found, although octopine-catabolizing bacteria were isolated from several tumors. A new, previously undescribed iminodiacid of the succinamopine-leucinopine type (provisionally designated IDA-B) was isolated from tumors of wild blackberry. Field tumors from apple, blueberry and grape yielded no detectable opines, even though opine-utilizing bacteria were present. Bacterial isolates from plum and cherry showed the best correspondence between the opine in tumors (nopaline) and the presence of bacteria that catabolized that opine. However, several unusual opine catabolic combinations were identified, including isolates that catabolized a variety of opines but were nonpathogenic. More variability was observed among isolates from field tumors on the remaining plant species. We isolated novel mannopine-nopaline type agrobacteria from field tumors of cherry, plum and blackberry that induced tumors containing either mannopine (plus agropine) or nopaline, but not both. Epidemiologically, the galled plants from an area were not of clonal origin (same Ti plasmid), indicating that the field tumors from a small area were incited by more than one type of Ti plasmid.     

Agrocinopine A, a tumor-inducing plasmid-coded enzyme product, is a phosphodiester of sucrose and L-arabinose

Opines are unusual compounds found specifically in plant crown gall tumors. Genes for their synthesis and catabolism reside in agrobacteria as tumor-inducing (Ti) plasmid DNA. Only a small Ti-plasmid segment (24 kilobase pairs), the T-DNA, is transferred to the plant cell where it commonly codes for enzymes involved in the biosynthesis of nitrogenous opines such as nopaline (N2-(1,3-D-dicarboxypropyl)-L-arginine) as well as the tumor phenotype. Ellis and Murphy, (Ellis, J.G., and Murphy, P.J. (1981) Mol. Gen. Genet. 181, 36-43) reported the existence of the phosphorylated opines, agrocinopines A and B in tumors containing nopaline. Pure agrocinopine A has now been isolated in a yield of 0.05-0.06 g/100 g, fresh weight, from such tumors. Physical, chemical, and biological data establish the structure of agrocinopine A as an unusual non-nitrogenous opine of sucrose and L-arabinose with a phosphodiester linkage from the 2-hydroxyl of the arabinose to the 4-hydroxyl of the fructose moiety in sucrose. Agrocinopine B is the corresponding phosphodiester, in which the glucose has been hydrolyzed from the sucrose portion of agrocinopine A. Borohydride reduction of the free L-arabinose anomeric carbon of agrocinopine A, to the corresponding arabinitol derivative eliminates the characteristic inhibition zone enhancement produced by both agrocinopines A and B in the agrocin 84 (a fraudulent adenine nucleotide) bioassay. Because of the limited number of genes in the T-DNA, a generalization is proposed, whereby all opines will be found to comprise two common plant cell constituents linked in an uncommon manner by the minimum number of enzymes.     

Agrobacterium Ti and Ri plasmids specify enzymic lactonization of mannopine to agropine

A novel enzymic activity, responsible for the conversion of mannopine to agropine by lactonization, has been identified in Agrobacterium strains. This activity is encoded by octopine-type and agropine-type Ti or Ri plasmids, and is inducible by mannopine and agropine. In crude extracts it is stable for long periods and can be used for preparative synthesis of agropine from mannopine. The physiological role of this activity is not understood. However, it is probably involved in degradation of opines of the agropine family since it is always associated with agropine utilization in wild-type strains.     

Function of heterologous and pseudo border repeats in T region transfer via the octopine virulence system of Agrobacterium tumefaciens

The successful transfer of the Ti plasmid T region to the plant cell is mediated by its 24 bp border repeats. Processing of the T-region prior to transfer to the plant cell is started at the right border repeat and is stimulated by a transfer enhancer sequence called overdrive. Left and right border repeats differ somewhat in nucleotide sequence; moreover, the repeats of different Ti and Ri plasmids are slightly different. Our data indicate that these differences do not have a significant influence on border activity. However, the overdrive sequence is essential for the efficient transfer of a T region via an octopine transfer system. Our data suggest that an overdrive sequence must also be present next to the right border repeats of the nopaline Ti plasmid and the agropine of octopine and nopaline Ti plasmids express some differences in T-DNA processing activities. of cotopine and nopaline Ti plasmids express some differences in T-DNA processing activities.Furthermore, we demonstrate that certain pseudo border repeats, sequences that resemble the native 24 bp border repeat and naturally occur within the octopine Ti plasmid T-region, are able to mediate T region transfer to the plant cell, albeit with much reduced efficiency as compared to wild-type border repeats.     

Agrobacterium tumefaciens TR-DNA encodes a pathway for agropine biosynthesis

Summary A pathway for biosynthesis of the crown-gall opine, agropine is proposed and three potential new precursors characterised. The location of genes involved in the three steps of this pathway was determined by site directed insertions and deletions in the T_R region of the octopine Ti plasmid, pTiB6Tra^c. The proposed biosynthetic pathway for agropine which involves three T-DNA genes is in contrast to the biosynthesis of octopine and nopaline where single T-DNA genes are involved.     

Interactions between octopine and nopaline plasmids in Agrobacterium tumefaciens.

Transfer of octopine Ti plasmids to strains already carrying an octopine Ti plasmid was found to occur at the same (high) frequency as transfer to Ti plasmid lacking recipients, showing that resident Ti plasmids do not exhibit entry exclusion towards incoming Ti plasmids. The resident octopine Ti plasmid was lost by the recipient after the entrance of the incoming Ti plasmid, which is indicative of the incompatibility between the Ti plasmids. Octopine Ti plasmids were found to become established only infrequently in recipients with a nopaline Ti plasmid and, vice versa, nopaline Ti plasmids were only rarely established in recipients with an octopine Ti plasmid. Rare clones in which the incoming octopine (nopaline) Ti plasmid had been established despite the presence of a nopaline (octopine) Ti plasmid appeared to harbor cointegrates consisting of the entire incoming Ti plasmid and the entire resident Ti plasmid. The integration event invariably had occurred in a region of the plasmids that is highly conserved in evolution and that is essential for oncogenicity. These results show that octopine and nopaline Ti plasmids cannot be maintained as separate replicons by one and the same cell. Therefore, be definition, these plasmids belong to the same incompatibility group, which has been names inc Rh-1. Agrobacterial non-Ti octopine and nopaline plasmids were found to belong to another incompatibility group. The tumorigenic properties of strains harboring two different Ti plasmids, in a cointegrate structure, were indicative of the virulence genes of both of them being expressed. The agrobacterial non-Ti octopine and nopaline plasmids did not influence the virulence properties encoded by the Ti plasmid.