Octopine- and Nopaline-Inducible Proteins in Agrobacterium tumefaciens Are Also Induced by Arginine

Octopine induced the synthesis of 83, 76, 62, 58, 44, 42, 31, and 22 kDa proteins in Agrobacterium tumefaciens strains harboring the tumor-inducing (Ti) plasmids pTiA6 and pTiAch5. Nopaline induced the synthesis of 83, 76, 62, 58, 56, 44, 42, 31, and 22 kDa proteins in A. tumefaciens strains harboring the Ti plasmids pTiC58 and pTiT37. The molecular masses of proteins induced by octopine and nopaline were very similar. In accordance with the ‘opine concept’, octopine and nopaline were found to induce protein synthesis only in strains harboring the respective Ti plasmids. Arginine, a common catabolic product of octopine and nopaline, induced the synthesis of most of the proteins induced by the two opines. Our results show that only the initial step(s) of octopine and nopaline catabolism are induced by specific opines in the respective strains. The subsequent steps are likely to be regulated by arginine in both strains. Received: 5 January 1996 / Accepted: 21 February 1996     

Characterization of conjugal transfer functions of Agrobacterium tumefaciens Ti plasmid pTiC58.

Physical characterization of 13 transposon Tn5 insertions within the agrocinopine-independent, transfer-constitutive Ti plasmid pTiC58Trac identified three separate loci essential for conjugation of this nopaline/agrocinopine A + B-type Ti plasmid. Complementation analysis with relevant subcloned DNAs indicated that the three physically separated blocks of conjugal genes constitute distinct complementation groups. Two independent Tn5 insertions within the wild-type, agrocinopine-dependent, repressed pTiC58 plasmid resulted in constitutive expression of conjugal transfer. These two insertions were physically indistinguishable and could not be complemented in trans. However, the Trac phenotype resulted when the Tn5-mutated fragment cointegrated into the wild-type Ti plasmid. While the spontaneous Trac mutant Ti plasmids were also derepressed for agrocinopine catabolism, those generated by Tn5 insertions remained inducible, indicating that this apparent cis-acting site is different from that affected in the spontaneous mutants. No chromosomal Tn5 insertion mutations were obtained that affected conjugal transfer. An octopine-type Ti plasmid, resident in different Agrobacterium tumefaciens chvB mutants, transferred at normal frequencies, demonstrating that this virulence locus affecting plant cell binding is not required for Ti plasmid conjugation. None of our conjugal mutants limited tumor development on Kalanchoe diagremontiana. Known lesions in pTiC58 vir loci had no effect on conjugal transfer of this Ti plasmid. These results show that pTiC58 Ti plasmid conjugal transfer occurs by functions independent of those required for transfer of DNA to plant cells.     

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

Summary 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.     

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.     

A functional map of the nopaline catabolism genes on the Ti plasmid of Agrobacterium tumefaciens C58

Summary The nopaline catabolism (noc) genes are located in a 14.4 kb region on the pTiC58 plasmid of A. tumefaciens C58. These genes permit the bacterium to grow on nopaline N²-(1,3-dicarboxylpropyl) arginine, a substrate produced in plant tumors initiated by strain C58. The functions of the noc genes include the use of nopaline and L-ornithine as sole carbon and nitrogen sources. Using Tn5 insertional mutants, we have identified and mapped the positions of the genes that are responsible for nopaline catabolism (NopC), ornithine catabolism (OrnC) and nopaline uptake (NopU). A polar relationship was found between these phenotypes, which extended leftward over the noc region to the T-region. The NopC mutants were also deficient in nopaline oxidase, an enzyme that liberates free arginine from nopaline.The noc region also encodes the synthesis of a periplasmic protein, n1 that was induced by nopaline. Tn5 insertional mutations and molecular cloning were used to map the n1 production locus. The recombinant plasmids, pSa4480 and pSa4481, containing the 8.9 kb right-hand end of the noc region, conferred n1 production when introduced into a pTi-free strain of A. tumefaciens. Production of n1 by the strains carrying these plasmids required nopaline induction.We have identified in toto three noc loci: nocB, nocC, and nocA, which confer n1 production, nopaline oxidase production and ornithine catabolism respectively. A model is proposed whereby the noc genes of pTiC58 are contained on a leftward reading operon in the order nocB, nocC, and nocA.     

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.     

A novel plasmid curing method using incompatibility of plant pathogenic Ti plasmids in Agrobacterium tumefaciens

Ti (Tumor inducing) plasmids in Agrobacterium tumefaciens can transfer their T-DNA region into dicotyledonous plants, in which the expression of T-DNA genes causes plant tumors and the production of bacterial nutrients, e.g., opines such as nopaline. Naturally occurring Ti plasmids (pTi) are difficult to cure by conventional curing methods because of their high stability. Here, we developed a novel curing method based on plasmid incompatibility. For this, a curing plasmid, pMGTrep1, was newly constructed and subsequently introduced into A. tumefaciens strains harboring pTi by conjugation with Escherichia coli harboring pMGTrep1. The conjugation yielded 32-99% nopaline non-utilizing agrobacterial transconjugants in which pMGTrep1 replaced pTi due to incompatibility. Then, pMGTrep1-less derivatives of the transconjugants are easily selected in the presence of sucrose because pMGTrep1 contains a sucrose-sensitive sacB gene. This efficient method is directly applicable for curing plasmids with the same incompatibility group and shoud also applicable to other types of plasmids in Agrobacterium groups, including A. rhizogenes, by replacing the rep gene region of the curing plasmid with that of the corresponding incompatibility.     

Localization and restriction maps of the replication origin regions of the plasmids of Agrobacterium rhizogenes strain A4

Summary Banks of cosmids of the plasmids of the agropine-type Agrobacterium rhizogenes strain A₄ were used to transform Agrobacterium tumefaciens strain C58C1, which lacks a Ti plasmid. Hybrid cosmids able to be maintained in this strain were subcloned to localize precisely the origin of replication regions. These regions were mapped with restriction enzymes and compared by hybridization with those of Agrobacterium tumefaciens nopaline pTiC58 and octopine pTiAch5. This led to the characterization of three new plasmids suitable as cloning vectors in Escherichia coli and A. tumefaciens. They are compatible with pTi and pAt plasmids of A. tumefaciens and are maintained stably, even without selection pressure.     

Ornithine cyclodeaminase from octopine Ti plasmid Ach5: identification, DNA sequence, enzyme properties, and comparison with gene and enzyme from nopaline Ti plasmid C58.

Octopine and nopaline are two arginine-derived opines synthesized in plant cells transformed with octopine or nopaline plasmids. Utilization in Agrobacterium tumefaciens is mediated by Ti plasmid regions called occ or noc (octopine or nopaline catabolism), and recent experiments showed that noc in pTiC58 codes for a pathway from nopaline to L-proline. The last enzyme is ornithine cyclodeaminase (OCD), an unusual protein converting L-ornithine directly into L-proline. We investigated whether octopine plasmid pTiAch5 also harbors a gene for OCD. The results revealed an ocd gene which is induced by octopine and maps in the occ region. DNA sequence analysis and comparison with the gene from pTiC58 showed that the two genes are related (69% homology in DNA and deduced amino acid sequence), and antiserum against OCD(C58) also reacted with OCD(Ach5). The enzyme activity was characterized, and a comparison with OCD(C58) showed that the properties are similar, but not identical. Differences were detected in the regulation of enzyme activity by L-arginine and L-proline and in the response to varying ratios of NAD+/NADH. It is proposed that this reflects different mechanisms for integration of opine catabolism into general metabolism.     

Genetic basis for opine secretion from crown gall tumour cells

Summary Plant cells neoplastically transformed by insertion of T-DNA from Ti plasmids of agrobacteria produce and secrete opines. Secretion of two of these opines (octopine and nopaline) is shown to require the expression of a single gene, which we designate ons.Dedicated to Professor Georg Melchers to celebrate his 50-year association with the journal     

An Agrobacterium-transformed cell culture from the monocot Asparagus officinalis

Cultured stem fragments from the monocotyledonous plant Asparagus officinalis infected by the oncogenic bacterium Agrobacterium tumefaciens developed tumorous proliferations. This tissue was propagated in vitro on hormone-free culture medium. The T-DNA-encoded markers nopaline and agrocinopine were unambiguously detected in these tissues. The data demonstrate that stable T-DNA transfer as well as expression of T-DNA genes is possible in at least some monocotyledonous plants. This opens new possibilities for plant genetic engineering using the Ti plasmid as a gene vector.     

Absolute stereochemistry of leucinopine,a crown gall opine

Crown gall tumors incited by Agrobacterium tumefaciens strain Bo542 have been reported to synthesize a tumor-specific substance identified as N-(1,3-dicarboxypropyl)-leucine (leucinopine), a compound with two centers of asymmetry. We report here evidence that leucinopine is indeed a crown gall opine, in that it is specifically catabolized by A. tumefaciens strains carrying the tumor-inducing plasmid pTi Bo542, as well as strains carrying closely related plasmids pTi AT1 and pTi AT4. We further report catabolism of leucinopine by the succinamopine-type strains A518, A519 and A532, carrying pTi EU6, pTi AT181 and pTi T10/73, respectively. Strains lacking any virulence plasmid, as well as those carrying octopine or nopaline type Ti plasmids or mannopine type Ri plasmids, did not catabolize leucinopine. On the basis of specificity of catabolism by bacteria carrying pTi Bo542, we conclude that the stereochemistry of natural leucinopine is l-threo, i.e. l^glu,l^leu. Such stereochemistry is novel in the opines known thus far: octopine, nopaline and succinamopine have d,l-stereochemistry: d^ala,l^arg (octopine), d^glu,l^arg (nopaline) and d^glu,l^asn (succinamopine).     

Succinamopine: a new crown gall opine

Agrobacterium tumefaciens strains can incite plant tumors consisting of transformed cells that synthesize novel metabolites called opines. The pattern of opine synthesis is dictated by plasmid-borne genes in the pathogen; additional plasmid genes confer on the pathogen the ability to catabolize the same pattern of opines synthesized. One group of A. tumefaciens strains, AT181, EU6, and T10/73, contains closely related tumor-inducing (Ti) plasmids that encode the ability to degrade the opine nopaline; but tumors incited by these strains do not synthesize nopaline. We demonstrated by Southern blot hybridization that AT181(pTi) has no DNA homologous to the nopaline synthase gene of pTi T37, a nopaline Ti plasmid that appears to be most closely related to this group based on fingerprint analysis. Tumors incited by these seemingly anomalous strains contain a new opine that we designate succinamopine. Its structure is analogous to that of nopaline, with asparagine replacing arginine. Evidence for the structure of succinamopine, as well as those of two related metabolites, succinamopine lactam and succinopine lactam, will be published elsewhere. Ability to catabolize succinamopine, succinamopine lactam, and succinopine lactam is encoded by pTi AT181, pTi EU6, and pTi T10/73, but not by any of 15 other Ti and root-inducing plasmids tested. Three avirulent strains tested did not catabolize succinamopine, succinamopine lactam, or succinopine lactam. We propose that pTi AT181, pTi EU6, and pTi T10/73 be designated the succinamopine Ti plasmids.     

Nucleotide sequence of the virG locus of the Agrobacterium tumefaciens plasmid pTiC58

The nucleotide sequence of the virG locus of the nopaline type plasmid pTiC58 of Agrobacterium tumefaciens has been determined. It contains an open reading frame (ORF) of 759 nucleotides and has 77% homology to the virG sequences of octopine type plasmids. Differences between the sequences of the two types of Ti plasmids in the region of virG are located predominantly outside the ORF. The amino acid sequences inferred from the two virG genes show 80% homology to each other and each shows the same moderate homologies to amino acid sequences derived from genes in a family of two-component regulatory systems. Specific differences in nucleotide and amino acid sequences as well as a structure-function model for the gene product are discussed.     

The lysopinedehydrogenase gene used as a marker for the selection of octopine crown gall cells

Plant cells transformed into octopine-synthesizing tumour cells by the bacterium Agrobacterium tumefaciens survive when cultured in the presence of homo-arginine (HA), whereas both normal plant cells and nopaline producing plant tumour cells do not. Survival of octopine crown gall cells is due to the activity of the enzyme lysopinedehydrogenase (LpDH) in these cells, which converts toxic homo-arginine into non-toxic homo-octopine. The selective toxicity of homo-arginine for normal cells can be applied for the enrichment of octopine Ti plasmid transformed plant cells vs normal plant cells in mixed cultures.     

Co-evolution of the agrocinopine opines and the agrocinopine-mediated control of TraR, the quorum-sensing activator of the Ti plasmid conjugation system

Conjugal transfer of Agrobacterium tumefaciens Ti plasmids is controlled by a hierarchical system in which opines, substrates produced by crown gall tumours, induce a quorum-sensing system. The cascade results from the control of expression of traR, the quorum-sensing activator, by a regulator responsive to the opine. In the two cases studied to date, the gene arrangements responsible for the cascade differ remarkably, suggesting that considerable diversity exists among the many Ti-like plasmids in the agrobacteria. In this study, we demonstrated that the novel Ti plasmid pTiChry5 is induced to transfer at high frequency by extracts from tumours initiated by strain Chry5. The purified inducer had the chemical and biological properties of agrocinopines C and D, a set of sugar phosphodiester opines known to induce transfer of another Ti plasmid, pTiBo542. The T-region of pTiChry5 contained a gene whose product, called Acs(Chry5), is virtually identical to the agrocinopine C+D synthase from the T-region of pTiBo542. The two genes are less closely related to acs of pTiC58, which is responsible for the production of agrocinopines A+B, a similar but not identical set of phosphodiester opines by tumours induced by strain C58. Agrocinopines A+B induce transfer of pTiC58 but did not induce transfer of pTi(Chry5). A single copy of traR was identified at the 11 o'clock region of pTi(Chry5), where it is part of a two-gene operon called arc(Chry5). Although altered by deletions, arc(Chry5) is related to the five-gene arc operon that controls the expression of traR on pTiC58. Expression of traR(Chry5) was induced by agrocinopines C+D and the opines isolated from Chry5 tumours but not by agrocinopines A+B. A mutation in traR(Chry5) abolished transfer, and transfer was restored by complementation in trans. We conclude that the agrocinopine opines and the corresponding opine-meditated conjugal regulatory regions of pTiChry5 and pTiC58 share a common origin, but that the opine signals for the two Ti plasmids have evolved divergently through changes in the opine synthase enzymes. The alterations in the opines, in turn, necessitated a co-evolutionary change in the opine recognition systems responsible for controlling expression of the traR genes on these two types of Ti plasmids.     

Gene note. Complete nucleotide sequence of the T-DNA region of the plant tumour-inducing Agrobacterium tumefaciens Ti plasmid pTiC58

The complete nucleotide sequence has been determined of the T-DNA region from the plant tumour-inducing Agrobacterium tumefaciens nopaline Ti plasmid pTiC58. The T-DNA itself consists of 24 782 bp flanked by two direct 25 bp repeats, the border sequences. In addition, 3622 bp located at the left and 1070 bp at the right of the T-DNA borders were sequenced. Twenty-two open reading frames that code for proteins larger than 125 amino acids have been identified.Key words: Agrobacterium tumefaciens, sequence, T-DNA.      

Genetic analysis of an Agrobacterium tumefaciens strain producing an agrocin active against biotype 3 pathogens

Summary The successful biocontrol agent for crown gall disease, Agrobacterium radiobacter strain K84, is unable to protect grapevines from infection. We have identified a strain of Agrobacterium tumefaciens, J73, which produces an agrocin active both in vitro and in vivo against grapevine pathogens (Webster et al. 1986). We now report on the curing of this strain of its nopaline-type Ti plasmid and the location, by transposon mutagenesis, of the genes involved in the production of the agrocin. The Ti plasmid was cured by the introduction of selectable plasmids carrying the origins of replication of either the nopaline Ti plasmid, pTiC58, or the octopine Ti plasmid, pTi15955. Tn5 mutagenesis indicated that the genes responsible for agrocin production and/or export are located both on the chromosome and on a plasmid, pAgJ73, which co-migrated in agarose gels with pTiJ73. As the two plasmids were separable after transposon mutagenesis, we postulate that during or after mutagenesis of the agrocin plasmid, DNA rearrangements occurred between it and pTiJ73, resulting in an increase in size of pAgJ73. We provide evidence that the rearrangements involved the duplication of nopaline catabolism genes from pTiJ73 and their insertion into pAgJ73, which facilitated the resolution of the two plasmids. As expected pTiJ73 has homology with the nopaline Ti plasmid, pTiC58.     

Tzs, a nopaline Ti plasmid gene from Agrobacterium tumefaciens associated with trans-zeatin biosynthesis

Summary The tzs gene, present in nopaline Ti plasmids, confers on Agrobacterium tumefaciens the ability to produce the phytohormone, trans-zeatin (Regier and Morris (1982) Biochem Biophys Res Comm 104:1560–1566). This gene has now been cloned from the nopaline Ti plasmid pTiC58. It occurs outside the T-DNA in a region close to that associated with virulence functions. Sequence studies indicate that tzs has substantial homology with the T-region gene, ipt, which is known to encode a dimethylallylpyrophosphate transferase, the first enzyme of the cytokinin biosynthetic pathway. As expected from its homology with ipt, tzs possesses significant DMA transferase activity but when expressed in Escherichia coli it causes secretion of trans-zeatin.