Characterization of the acc operon from the nopaline-type Ti plasmid pTiC58, which encodes utilization of agrocinopines A and B and susceptibility to agrocin 84.

The acc locus from the Ti plasmid pTiC58 confers utilization of and chemotaxis toward agrocinopines A and B (A+B), as well as susceptibility to a highly specific antiagrobacterial antibiotic, agrocin 84. DNA sequence analyses revealed that acc is composed of eight open reading frames, accR and accA through accG. Previous work showed that accR encodes the repressor which regulates this locus, and accA codes for the periplasmic binding protein of the agrocinopine transport system (S. Beck Von Bodman, G. T. Hayman, and S. K. Farrand, Proc. Natl. Acad. Sci. USA 89:643-647, 1992; G. T. Hayman, S. Beck Von Bodman, H. Kim, P. Jiang, and S. K. Farrand, J. Bacteriol. 175:5575-5584, 1993). The predicted proteins from accA through accE, as a group, have homology to proteins that belong to the ABC-type transport system superfamily. The predicted product of accF is related to UgpQ of Escherichia coli, which is a glycerophosphoryl diester phosphodiesterase, and also to agrocinopine synthase coded for by acs located on the T-DNA. The translated product of accG is related to myoinositol 1 (or 4) monophosphatases from various eucaryotes. Analyses of insertion mutations showed that accA through accE are required for transport of both agrocin 84 and agrocinopines A+B, while accF and accG are required for utilization of the opines as the sole source of carbon. Mutations in accF or accG did not abolish transport of agrocin 84, although we observed slower removal of the antibiotic from the medium by the accF mutant compared to the wild type. However, the insertion mutation in accF abolished detectable uptake of agrocinopines A+B. A mutation in accG had no effect on transport of the opines. The accF mutant was not susceptible to agrocin 84 although it took up the antibiotic. This finding suggests that agrocin 84 is activated by AccF after being transported into the bacterial cell.     

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.     

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.     

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.     

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.     

Deletion derivatives of pAgK84 and their use in the analysis of Agrobacterium plasmid functions.

The 47.7-kb plasmid pAgK84, present in Agrobacterium radiobacter strain K84, confers production of a novel, highly specific, antiagrobacterial antibiotic called agrocin 84. Strain K84 is used commercially to biocontrol crown gall caused by agrocin 84-susceptible strains of Agrobacterium tumefaciens. Efficient biocontrol is dependent upon production of agrocin 84 by strain K84. Starting with a derivative of pAgK84 containing a Tn5 insertion, a series of deletion derivatives of the plasmid were isolated. The smallest of these, pJS500, contains about 8 kb of the original agrocin plasmid and localized the replication functions to between 4 and 6 o'clock on the physical map. A smaller derivative, produced by clonal rescue of a Tn5 insertion in the 4 o'clock region, further localized the minimal replication functions to a 1.5-kb region mapping between coordinates 18.1 and 19.6. Analysis of plasmid stability indicated that functions required for maintenance of the plasmid under nonselective conditions are tightly linked to the minimal replication region. This region also encodes incompatibility functions; the deletion derivatives were all incompatible with the wild-type pAgK84. The stability/replication locus of pAgK84 maps just anticlockwise from the Tra region. This region is retained fully in pAgK1026, the directed Tra- derivative of pAgK84 which is now in use as the primary crown gall biocontrol agent in Australia. One of the deletion derivatives, the 15-kb pJS400, was used as a vector to clone the KpnI fragments of an octopine-type Ti plasmid. Traits known to be encoded on these fragments were expressed and properly regulated in Agrobacterium hosts. One clone, encoding the Ti plasmid replication/incompatibility region, was used to cure IncRh1 Ti plasmids from their hosts. This clone also was found to be incompatible with pAtK84b, a large plasmid encoding opine catabolism present in A. radiobacter strain K84. This indicates that the opine catabolic plasmid is closely related to the IncRh1 Ti plasmids.     

Deletion derivatives of pAgK84 and their use in the analysis of Agrobacterium plasmid functions

The 47.7-kb plasmid pAgK84, present in Agrobacterium radiobacter strain K84, confers production of a novel, highly specific, antiagrobacterial antibiotic called agrocin 84. Strain K84 is used commercially to biocontrol crown gall caused by agrocin 84-susceptible strains of Agrobacterium tumefaciens. Efficient biocontrol is dependent upon production of agrocin 84 by strain K84. Starting with a derivative of pAgK84 containing a Tn5 insertion, a series of deletion derivatives of the plasmid were isolated. The smallest of these, pJS500, contains about 8 kb of the original agrocin plasmid and localized the replication functions to between 4 and 6 o'clock on the physical map. A smaller derivative, produced by clonal rescue of a Tn5 insertion in the 4 o'clock region, further localized the minimal replication functions to a 1.5-kb region mapping between coordinates 18.1 and 19.6. Analysis of plasmid stability indicated that functions required for maintenance of the plasmid under nonselective conditions are tightly linked to the minimal replication region. This region also encodes incompatibility functions; the deletion derivatives were all incompatible with the wild-type pAgK84. The stability/replication locus of pAgK84 maps just anticlockwise from the Tra region. This region is retained fully in pAgK1026, the directed Tra⁻ derivative of pAgK84 which is now in use as the primary crown gall biocontrol agent in Australia. One of the deletion derivatives, the 15-kb pJS400, was used as a vector to clone the KpnI fragments of an octopine-type Ti plasmid. Traits known to be encoded on these fragments were expressed and properly regulated in Agrobacterium hosts. One clone, encoding the Ti plasmid replication/incompatibility region, was used to cure IncRh1 Ti plasmids from their hosts. This clone also was found to be incompatible with pAtK84b, a large plasmid encoding opine catabolism present in A. radiobacter strain K84. This indicates that the opine catabolic plasmid is closely related to the IncRh1 Ti plasmids.     

Agrocin 84 sensitivity: a plasmid determined property in Agrobacterium tumefaciens.

It was shown for some oncogenic Agrobacterium tumefaciens strains that agrocin 84 sensitivity is determined by the presence of a large closed circular DNA plasmid, called the Ti-plasmid. Whereas wild-type strain C58 is agrocin 84 sensitive, all Ti-plasmid cured derivatives were found to be fully resistant. Moreover all independently isolated agrocin 84 resistant colonies were stably non-oncogenic and plasmid negative. In a growth experiment carried out at 37 degrees C it was shown that the kinetics of appearance of non-oncogenic cells on the one hand and of agrocin 84 resistant cells on the other were identical. The fact that not all oncogenic, plasmid harbouring, Agrobacterium tumefaciens strains are sensitive to agrocin 84, points to the possibility that the genes determining agrocin 84 sensitivity are not essential for tumor-inducing ability.     

Tn5 insertions in the agrocin 84 plasmid: the conjugal nature of pAgK84 and the locations of determinants for transfer and agrocin 84 production

The kanamycin-resistance transposon Tn5 was randomly introduced into pAgK84, a 47.7-kb plasmid coding for agrocin 84 production in Agrobacterium. Using such marked plasmids, pAgK84 was found to be conjugal. It could be transferred to several Agrobacterium strains including those harboring octopine- or nopaline-type Ti plasmids. Its presence has no effect on Ti plasmid functions such as opine utilization and tumorigenicity, but it does confer agrocin 84 immunity upon previously sensitive strains. The plasmid could also be conjugally transferred to a Nod+ Fix+ strain of Rhizobium meliloti. The production of agrocin 84 is expressed in all Agrobacterium and Rhizobium transconjugants tested. The agrocin plasmid could not be introduced into restrictionless Escherichia coli or Pseudomonas aeruginosa recipients by conjugation or transformation. The sites of 92 independent Tn5 insertions were mapped on pAgK84. These insertions are dispersed over the entire length of the plasmid. Analysis of the sites and effects of the Tn5 insertions has allowed us to construct a functional map of pAgK84. Forty-three of these insertions, spanning a 20-kb segment of the plasmid, abolished or greatly reduced the production of agrocin 84. The presence of two insertions within this segment having an effect on agrocin production suggests that at least three regions of the plasmid are involved in agrocin 84 biosynthesis. Fourteen of the Tn5 insertion derivatives are no longer conjugally transferable. These insertions all map to a single region of the plasmid and define about 3.5-kb as being associated with transfer functions.     

Construction of a Tra? deletion mutant of pAgK84 to safeguard the biological control of crown gall

Summary Agrobacterium radiobacter strain K84 is used commercially for the biological control of crown gall. It contains the conjugative plasmid pAgK84, which encodes the synthesis of agrocin 84, an antibiotic that inhibits many pathogenic agrobacteria. A breakdown of control is threatened by the transfer of pAgK84 to pathogens, which then become resistant to agrocin 84. A mutant of pAgK84 with a 5.9-kb deletion overlapping the transfer (Tra) region was constructed using recombinant DNA techniques. The BamHI fragment B1 which covers most of the Tra region was cloned in pBR325 and its internal EcoRI fragments D1 and H, which overlap the Tra region, were removed, leaving 3.7 kb and 0.5 kb of pAgK84 on either side of the deletion. The latter was increased to 3.3 kb by adding EcoRI fragment D2 from a BamHI fragment C clone. The modified pBR325 clone was mobilized into Agrobacterium strain NT1 harbouring pAgK84 with a Tn5 insertion just outside the Tra region but covered by the deletion. A Tra⁺ cointegrate was formed between the Tn5-insertion derivative and the pBR325-based deletion construct by homologous recombination. The cointegrate was transferred by conjugation to a derivative of strain K84 lacking pAgK84, in which a second recombination event generated a stable deletion-mutant by deletion-marker exchange. The resultant new strain of A. radiobacter, designated K1026, shows normal agrocin 84 production. Mating experiments show that the mutant plasmid, designated pAgK1026, is incapable of conjugal transfer at a detectable frequency.     

The oriT region of the Agrobacterium tumefaciens Ti plasmid pTiC58 shares DNA sequence identity with the transfer origins of RSF1010 and RK2/RP4 and with T-region borders.

Ti plasmids of Agrobacterium tumefaciens are conjugal elements whose transfer is induced by certain opines secreted from crown galls. On transmissible plasmids, DNA transfer initiates within a cis-acting site, the origin of conjugal transfer, or oriT. We have localized an oriT on the A. tumefaciens plasmid pTiC58 to a region containing the conjugal transfer loci traI and traII and acc, which is the locus encoding catabolism of the two conjugal opines, agrocinopines A and B. The smallest functional oriT clone, a 65-bp BamHI-ApaI fragment in the recombinant plasmid pDCBA60-11, mapped within the traII locus. The nucleotide sequence for a 665-bp KpnI-EcoRI fragment with oriT activity was determined. DNA sequence alignments showed identities between the pTiC58 oriT and the transfer origins of RSF1010, pTF1, and RK2/RP4 and with the pTiC58 T-region borders. The RSF1010-like sequence on pTiC58 is located in the smallest active oriT clone of pTiC58, while the sequence showing identities with the oriT regions of RK2/RP4 and with T-region borders maps outside this region. Despite their sequence similarities, pTiC58 oriT clones were not mobilized by RP4; nor could vectors containing the RK2/RP4 oriT region or the oriT-mob region from RSF1010 be mobilized by pTiC58. In contrast, other Ti plasmids and a conjugally active Agrobacterium opine catabolic plasmid, pAtK84b, efficiently mobilized pTiC58 oriT clones. In addition, the RSF1010 derivative, pDSK519, was mobilized at moderate frequencies by an Agrobacterium strain harboring only the cryptic plasmid pAtC58 and at very low frequencies by an Agrobacterium host that does not contain any detectable plasmids.     

Bacteriocin production inAgrobacterium tumefaciens

Agrobacterium tumefaciens C58 forms “plaques” during layer cultivation. The “plaques” were shown not to be caused by the presence of a temperate bacteriophage or by random contamination. The “plaques” and their central microcolonies were used to repeatedly isolate cultures producing an antibiotic substance against the original strainA. tumefaciens C58, other nopaline strains, some octopine strains ofA. tumefaciens and some strains of the related genusRhizobium. The substance is thus a bacteriocin; in analogy to agrocins 84 and D286 it was named agrocin C58. The agrocin is not inactivated by trypsin. Its production by strain C58 was found only on cultivation on solid but not liquid media. The producing isolate ofA. tumefaciens C58 (strain C58i2) contains neither plasmid pTiC58 nor the plasmid analogous to pAgK84 which controls the production of agrocin 84 inA. radiobacter K84.     

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.     

Sensitivity of differentAgrobacterium strains to agrocin 84

Sensitivity of fourteenA. tumefaciens andA. rhizogenes strains to agrocin 84 was followed. A new agrocin 84 sensitivity of mannopine strains ofA. rhizogenes 8196 and TR101 was described. Agropine strains ofA. rhizogenes andA. tumefaciens were sensitive to agrocin 84, too. Agrocin 84 sensitivity of succinamopine and mannopine strains ofA. tumefaciena was also confirmed.     

Agrobacterium radiobacter strains K84, K1026 and K84 Agr‐ produce an antibiotic‐like substance,active in vitro against A. tumefaciens and phytopathogenic Erwinia and Pseudomonas spp.

Agrobacterium radiobacter strains K84, K1026 and K84 Agr^‐ produced in vitro an antibiotic‐like substance (ALS 84), different from agrocin 84 and observed in mannitol‐glutamate medium. Twenty five out of 39 A. tumefaciens strains of biovars 1, 2 and 3 were sensitive to ALS 84 regardless of their sensitivity to agrocin 84. Sensitivity in A. tumefaciens strain C58 was not encoded by the Ti‐plasmid. Most isolates tested of Erwinia carotovora subsp. carotovora E. carotovora subsp. atroseptica, Pseudomonas corrugata P. cichorii and unidentified isolates from galls were also sensitive to this substance. ALS 84 was not affected by the proteases studied, nor by treatment at 62°C for 30 min and had a bacteriostatic effect. The production of ALS 84 might play a role in the complex mechanism of biological control of crown gall, especially in strains resistant to agrocin 84 and sensitive to ALS 84, and by the creation of an ecological niche favourable to A. radiobacter strains K84, K1026 or K84 Agr^‐.