A comparison of virulence determinants in an octopine Ti plasmid, a nopaline Ti plasmid, and an Ri plasmid by complementation analysis of Agrobacterium tumefaciens mutants

Transposon-insertion mutants with vir^? Ti plasmids were characterized and then used in complementation experiments. One of the mutants (LBA 1517) had a mutation in a newly discovered vir locus called virF. The virF mutation led to a strongly diminished virulence on tomato and tobacco, but not on certain other plant species. Also a mutant (LBA 1505) was isolated with a mutation somewhere in the bacterial genome but outside the octopine Ti plasmid that caused a restriction in host range for tumor induction. Introduction of a nopaline Ti plasmid or an Ri plasmid into LBA 1505 did not restore normal virulence, showing that the vir gene affected in LBA 1505 determines a factor which is essential for normal tumor induction both by different types of Ti plasmids and by the Ri plasmid. The introduction of R primes containing part or all of the octopine Ti plasmid virulence region led to a restoration of virulence in strains with a vir^? nopaline Ti plasmid. Also the transfer of an Ri plasmid to a large number of different vir^? octopine or nopaline Ti plasmid mutants rendered these strains virulent. These results indicate that the octopine Ti plasmid, the nopaline Ti plasmid, and the Ri plasmid each have a similar virulence system which can mediate the transfer of T-DNA to plant cells from different types of Ti or Ri plasmids. In complementation experiments between vir^? octopine Ti plasmid mutations and vir^? nopaline Ti plasmid mutations it was found that equivalent functions are determined by the areas of DNA homology in the virulence regions of these two types of Ti plasmids. The previously defined octopine Ti plasmid virC locus appeared to consist of two different loci. One of these loci was found to be in a region of the octopine Ti plasmid which does not share DNA homology with the nopaline Ti plasmid, and was therefore called virO (octopine Ti plasmid specific). For the other locus the name virC was retained. Whereas mutations in the virC locus were avirulent on all plant species tested, mutations in virO were avirulent on tomato and pea, but virulent on sunflower and Nicotiana rustica. VirO^? mutants produced rooty tumors on Kalanchoë tubiflora.     

Molecular and genetic analysis of the transferred DNA regions of the root-inducing plasmid of Agrobacterium rhizogenes.

The T-DNA regions of the root-inducing (Ri) plasmid pRiA4b of Agrobacterium rhizogenes were characterized. Two regions, designated TL-DNA and TR-DNA, were found to be integrated and stably maintained in the plant genome. The TL-DNA spanned a 15- to 20-kilobase region of pRiA4b and was separated from the TR-DNA region by at least 15 kilobases of nonintegrated plasmid DNA. The TR-DNA region also spanned a 15- to 20-kilobase region of pRiA4b and included a region of homology to the tms morphogenic loci of the tumor-inducing (Ti) plasmid of Agrobacterium tumefaciens. Eighteen deletions and 95 transposon insertions were generated in the T-DNA regions and tested for alterations in virulence. Insertions into four loci in the TL-DNA affected the morphology of root formation of Kalancho? diagremontiana leaves and stems, but had no visible effects on other host plants. Insertions into two loci (tms-1 and tms-2) in the TR-DNA eliminated virulence symptoms on all plants tested, with the exception of K. diagremontiana stems, where sparse root formation occurred. Complementation experiments with Ri and Ti plasmid T-DNA mutations indicate that the tms genes of the two plasmids serve similar functions and suggest a functional relationship between one or more genes of the TL-DNA and the cytokinin synthesis locus tmr of the Ti plasmid.     

A plasmid rescue technique for the recovery of plant DNA disrupted by T-DNA insertion

Arabidopsis mutants generated by insertion of the T-DNA from Ti plasmid 3850∶1003 serve as a starting point for the isolation of novel genes. The disrupted plant DNA can be recovered using a plasmid rescue technique utilizing high efficiency electroporation. Rescued plasmids are resistant to ampicillin and contain an origin of replication from pBR322. Plasmids generated from either the left or right border of the T-DNA that carry flanking DNA sequences can be identified by analyzing the products of restriction enzyme digests on agarose gels. The plasmids with flanking sequences can then serve as a starting point for cloning plant sequences that share homology to the DNA at the point of T-DNA insertion.     

Binary plant vector based on Ri plasmid and part of T-DNA of the Ti plasmid

A binary vector system inA. tumefaciens for the introduction of foreign genes into the plant genome was developed. The first component is the Ri plasmid and the second component is a small vector plasmid, replicating inAgrobacterium, which carries the 25 bp terminal sequence of the Ti plasmid, theNos gene as the selectable marker and neighbouring sequences of the Ti plasmid. Functions necessary for integration are providedin trans by the virulence region of the Ri plasmid. Transformed cells are selected on the basis of hairy root tumor proliferation and agropine synthesis. They also showNos activity coded by the gene on the small part of Ti T-DNA.     

Ti plasmid type affects T-DNA processing in Agrobacterium tumefaciens

Agrobacterium tumefaciens can transfer the T-DNA region of a Ti plasmid to a recipient plant cell. An accepted model that describes the T-DNA transfer mechanism proposes that single-stranded T-complexes are transferred to a recipient plant via a conjugation-like mechanism. This model has been based on examination of a limited number of Ti plasmids. In this study, the type of processed T-DNA molecule created from multiple Ti plasmids was determined. The form of the processed T-DNA was found to vary and was correlated with whether the T-DNA region was organized as a single continuous region or two adjacent regions.     

Isolation and identification of TL-DNA/plant junctions in Convolvulus arvensis transformed by Agrobacterium rhizogenes strain A4

We have constructed a Charon 4A phage library containing insert DNA isolated from a morning glory (Convolvulus arvensis) plant (clone 7) regenerated from a root organ culture incited by Agrobacterium rhizogenes, strain A4. Using a subcloned region of the Ri plasmid as ³²P-labeled probe, two lambda clones containing most of the 'left' T-DNA (TL) region were isolated. One of these lambda clones contains the left TL-DNA/plant junction, which was located by comparing nucleotide sequences from the appropriate regions of the Ri plasmid and this lambda clone. A 25-bp sequence found near this left TL-DNA/plant junction matches the 25-bp terminal sequence found at or near T-DNA/plant junctions of both nopaline- and octopine-type A. tumefaciens Ti plasmids. A possible location for the right Ri TL-DNA/plant junction in C. arvensis clone 7 was found by obtaining the nucleotide sequence surrounding its mapped location. Hybridization of plant DNA found adjacent to the left TL-DNA/plant junction against total C. arvensis DNA shows that this T-DNA integration occurred in a plant DNA region that does not contain highly repetitive DNA sequences. Nucleotide sequence analysis of 1004 bp of this plant DNA revealed no complete or partial open reading frames, but this plant DNA does have the potential to form various secondary structures which might play a role in the T-DNA integration event.     

Transfer of the octopine T-DNA segment to plant cells mediated by different types of Agrobacterium tumor- or root-inducing plasmids: generality of virulence systems.

Genetic complementation studies demonstrated that the transfer to plant cells of the octopine T-DNA, entirely present as the only part of the tumor-inducing (Ti) plasmid on the plasmid pAL1050, was effected by the virulence systems from related plasmids, viz. the nopaline Ti plasmid pTiC58, the limited host range plasmid pTiAg57, and the root-inducing (Ri) plasmid pRi1855. Rhizobium symbiosis plasmids were not capable of effecting the introduction of pAL1050 into plant cells.     

A T-DNA gene required for agropine biosynthesis by transformed plants is functionally and evolutionarily related to a Ti plasmid gene required for catabolism of agropine by Agrobacterium strains.

The mechanisms that ensure that Ti plasmid T-DNA genes encoding proteins involved in the biosynthesis of opines in crown gall tumors are always matched by Ti plasmid genes conferring the ability to catabolize that set of opines on the inducing Agrobacterium strains are unknown. The pathway for the biosynthesis of the opine agropine is thought to require an enzyme, mannopine cyclase, coded for by the ags gene located in the T(R) region of octopine-type Ti plasmids. Extracts prepared from agropine-type tumors contained an activity that cyclized mannopine to agropine. Tumor cells containing a T region in which ags was mutated lacked this activity and did not contain agropine. Expression of ags from the lac promoter conferred mannopine-lactonizing activity on Escherichia coli. Agrobacterium tumefaciens strains harboring an octopine-type Ti plasmid exhibit a similar activity which is not coded for by ags. Analysis of the DNA sequence of the gene encoding this activity, called agcA, showed it to be about 60% identical to T-DNA ags genes. Relatedness decreased abruptly in the 5' and 3' untranslated regions of the genes. ags is preceded by a promoter that functions only in the plant. Expression analysis showed that agcA also is preceded by its own promoter, which is active in the bacterium. Translation of agcA yielded a protein of about 45 kDa, consistent with the size predicted from the DNA sequence. Antibodies raised against the agcA product cross-reacted with the anabolic enzyme. These results indicate that the agropine system arose by a duplication of a progenitor gene, one copy of which became associated with the T-DNA and the other copy of which remained associated with the bacterium.     

Independent induction of transformed roots by the TL and TR regions of the Ri plasmid of agropine type Agrobacterium rhizogenes

Summary To analyse the respective role of TL- and TR-DNA in root induction by agropine-type Agrobacterium rhizogenes Ri plasmids, deletions covering the TL- or the TR-regions were constructed in vitro and introduced into pRiA4 by marker exchange. Each T-region of pRiHRI was also cloned separately on an independent replicon and used in a binary system with the virulence functions of either an Ri or a Ti plasmid provided in trans. Transformed roots were induced on tobacco and tomato explants by TL-DNA as well as by TR-DNA, suggesting that agropine type Ri plasmids from strains A4 and HRI can induce root proliferation by two independent transformation mechanisms. The root induction by the TR-DNA is probably due to auxin biosynthesis by gene products of aux loci homologous to the tms genes of Ti plasmid T-DNA. The molecular mechanism of root proliferation induced by the TL-DNA is probably equivalent to that of mannopine type Ri plasmid T-DNA.     

Genetic analysis of integration mediated by single T-DNA borders.

Transformation of plant cells by the T-DNA of the Ti plasmid of Agrobacterium tumefaciens depends in part upon a sequence adjacent to the right T-DNA end. When this sequence is absent, the T-DNA is almost avirulent; when it is present, DNA between it and the left T-DNA border region becomes integrated in plants. To investigate further this process of DNA transfer and integration, we introduced the right border region and the nopaline synthase (nos) gene of plasmid pTiC58 into a variety of new positions around Ti plasmids. The border region functioned when separated from the remainder of the T-DNA by almost 50 kilobases. It also worked when placed outside of the T-DNA region where there were no known left-border sequences with which to interact. Indeed, the nos gene could be transferred to plants even when no other Ti plasmid sequences were present on the same plasmid. These results may indicate that the sequence requirements for the left borders are not as stringent as those for the right borders. In addition, mutants with an extra copy of the right border region within their T-DNA were found to transfer or integrate only parts of the bacterial T-DNA region. It is possible that abnormally placed T-DNA borders interfere with the normal process of DNA transfer, integration, or both.     

The functional organization of the nopaline A. tumefaciens plasmid pTiC58

We have employed the P type plasmid RP4 and the transposons Tn1 and Tn7 to isolate insertion and deletion mutations in the nopaline Ti-plasmid pTiC58. Mutations that inactivate all known Ti phenotypes have been located on the physical map. Most importantly, we have positioned several regions involved in the determination of oncogenicity. They correspond to regions of homology between octopine and nopaline plasmids. One of these regions is part of the T-DNA, the Ti-plasmid DNA present in transformed plant cells. There are also segments of the T-DNA that are not essential for oncogenicity. One of these determines the biosynthesis of nopaline in tumors. The latter regions might allow insertion of foreign DNA that can then be introduced into plant cells.     

Site-specific mutagenesis of the Ti plasmid by transformation of Agrobacterium tumefaciens with mutagenized T-DNA fragments cloned in E. coli plasmids

Summary A DNA fragment covering the complete T-region of the Ti plasmid from Agrobacterium tumefaciens strain C58 was cloned in the Escherichia coli cosmid pHC79. This fragment was mutagenized by insertion of transposon Tn5. The isolated DNA from hybrid plasmids was used to transform cells of A. tumefaciens strain C58 applying the freeze-thaw method. Although the E. coli plasmids with the mutagenized Ti plasmid fragment cannot replicate in these cells, they can be rescued by recombination with the homologous region of the Ti plasmid. The cointegrates formed were resolved in a second recobination event, which was detected by loss of the drug resistance marker of the E. coli plasmid. Subcloning of the Ti plasmid fragments labeled with Tn5 showed that the frequency of rescue of the hybrid plasmid as a cointegrate and its segregation in agrobacteria depend on the degree of homology with the Ti plasmid. We also applied the strategy for site-directed Tn5 mutagenesis to insert specifically the replication origin of bacteriophage fd and the thymidine kinase gene from Herpes virus into the T-DNA of Ti plasmid-C58.     

Identification of T-DNA in the root-inducing plasmid of the agropine type Agrobacterium rhizogenes 1855

The region of the virulence plasmid of the agropine type Agrobacterium rhizogenes 1855 (pRi-1855) which is transferred to plant cells upon infection (T-DNA) has been identified by means of Southern blot hybridizations with the T-DNA of the mannopine type A. rhizogenes 8196. The presence in the plant genome of the pRi-1855 sequences thus identified is demonstrated in carrot roots derived from infection with strain 1855. The T-DNA of pRi-1855 has been mapped by means of cloned Eco RI partial digests. Although strongly homologous with each other, the cores of the T-regions of the mannopine and agropine Ri plasmids are not colinear since the latter contains a central segment of DNA which is absent from the T-region of pRi-8196. Unexpected homologies between the T-region of pRi-1855 and normal carrot DNA have been observed and are discussed here.Abbreviations YMB yeast mannitol broth - LS Linsmaier and Skoog - BSA bovine serum albumin - SSC 0.15 M NaCl, 0.015 M Na-citrate - MD megadalton     

Genetic studies on the role of octopine T-DNA border regions in crown gall tumor formation

Summary Crown gall tumors result from transfer and integration of the T-DNA from the Ti plasmid of Agrobacterium tumefaciens into plant nuclear DNA. In the present study, recombinant plasmids containing deletion and rearrangement deriviatives of the T-DNA region of the octopine Ti plasmid pTiA6 were tested in a binary tumorigenesis system (Hoekema et al. 1983) to determine the requirements for T-DNA border regions in tumor formation. Since two defined segments of the T-DNA region of octopine Ti plasmids can be detected in tumor DNA (the left (T_L-) and right (T_R-) DNA), four border regions exist in this Ti plasmid. Agrobacteria harboring plasmid constructs which contain a T-DNA gene capable of inciting tumors (gene 4, the tmr gene, which is involved in cytokinin biosynthesis) and various T-DNA border regions were tested for ability to cause tumors on Nicotiana glauca and other host plants. Such tmr constructs containing as their only border region the right border of either the T_L-DNA or the T_R-DNA are fully tumorigenic. Analogous tmr constructs containing only the T_L-DNa left border region are not tumorigenic. These results do not depend on the orientation or position of the single border with respect to the tmr gene; furthermore, the T_R-DNA right border can confer tumor-forming ability despite the presence of an intervening copy of the T_L-DNA left border.These results for relatively small plasmids are contrasted with previously determined requirements for border regions in tumorigenesis by intact Ti plasmids. A model previously proposed by Wang et al. (1984) for the role of border regions in DNA transfer to plant cells is extended in order to explain the tumor-forming ability of plasmid constructs containing a single border region. The results of this study interpreted according to the model suggest that the octopine T_L-DNA left border is defective in this DNA-transfer process.     

Genetic analysis of transfer and stabilization of Agrobacterium DNA in plant cells

In an attempt to elucidate the transfer and integration mechanism of Agrobacterium DNA upon crown gall induction, we translocated a borderless T-DNA to different sites of the C58 Ti plasmid. As a result of the physical linkage of the T-DNA onc genes with other Ti plasmid functions, the concerned strain retained tumor-inducing capacity. However, when the borderless T-DNA is separated on an independent replicon while all other pTi functions are provided in trans, the strain can no longer induce tumors on plants. We provide evidence that the right T-DNA border region harbors one or more in cis active functions essential in the transfer and/or stabilization of the T-DNA into plant cells. The strains used in these experiments allowed us to conclude that some function(s) of the Ti plasmid can induce plant cell proliferations independently of the T-DNA transformation event. The results described here indicate that other Ti plasmid sequences than solely the T-region can be transferred to plant cells.     

Wide host range cloning vectors: a cosmid clone bank of an Agrobacterium Ti plasmid

Plasmids from two virulent strains of Agrobacterium rhizogenes belonging to biotypes 1 and 2 are compared for DNA homology with the nopaline Ti plasmid from Agrobacterium tumefaciens C58 by means of Southern blot hybridizations. We find that both A. rhizogenes plasmids share strong sequence homology with regions of the Ti plasmid that affect oncogenicity of A. tumefaciens C58. The biotype 1 plasmid shows an additional region of homology at approximately the position of the genes responsible for conjugative transfer of pTiC58. Neither A. rhizogenes plasmid shows any detectable homology with the T-DNA of A. tumefaciens C58. Possible analogies between hairy root and crown gall induction are discussed on the basis of the results presented.