The opine synthase genes carried by Ti plasmids contain all signals necessary for expression in plants

Signals necessary for in vivo expression of Ti plasmid T-DNA-encoded octopine and nopaline synthase genes were studied in crown gall tumors by constructing mutated genes carrying various lengths of sequences upstream of the 5' initiation site of their mRNAs. Deletions upstream of position -294 did not interfere with expression of the octopine synthase gene while those extending upstream of position -170 greatly reduced the gene expression. The estimated size of the octopine synthase promoter is therefore 295 bp. The maximal length of 5' upstream sequences involved in the in vivo expression of the nopaline synthase gene is 261 bp. Our results also demonstrated that Ti plasmid-derived sequences contain all signals essential for expression of opine synthase genes in plants. Expression of these genes, therefore, is independent of the direct vicinity of the plant DNA sequences and is not activated by formation of plant DNA and T-DNA border junction.     

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.     

Fingerprints of Agrobacterium Ti plasmids

Many crown gall-inducing Agrobacterium tumefaciens strains have multiple plasmids, only one of which, the tumor-inducing (Ti) plasmid, is essential for oncogenicity. For comparison of Ti plasmids, single-plasmid-containing transconjugant or transformant derivatives were used as sources of pure Ti-plasmid DNA. Fingerprinting was undertaken using the restriction endonuclease SmaI because it produced a relatively simple cleavage pattern. Three groups of Ti plasmids are discernible based upon both their genetic characteristics and their SmaI fingerprints: (1) Octopine-type Ti plasmids, which confer oncogenicity and octopine utilization on the bacterium. Tumors incited produce octopine. This group of plasmids is highly conservative; fingerprints of all members were identical except for two minor variations. (2) Nopaline-type Ti plasmids, which confer oncogenicity and nopaline utilization on the bacterium. Tumors incited may or may not produce nopaline; these plasmids have fingerprints that suggest variable degrees of relationship, including one that appears unrelated to the rest (3) Null-type plasmids, which confer oncogenicity but neither utilization trait on the bacterium. Tumors incited by this class of strains produce neither octopine nor nopaline. Only one member of this group has been examined thus far. Fingerprints of plasmids from several nononcogenic strains examined bore no resemblance to fingerprints of any of the Ti plasmids.     

Opine transport genes in the octopine (occ) and nopaline (noc) catabolic regions in Ti plasmids of Agrobacterium tumefaciens.

The occ and noc regions of octopine and nopaline Ti plasmids in Agrobacterium tumefaciens are responsible for the catabolic utilization of octopine and nopaline, respectively. Opine-inducible promoters, genes for regulatory proteins and for catabolic enzymes, had been identified in previous work. However, both regions contained additional DNA stretches which were under the control of opine-inducible promoters, but the functions were unknown. We investigated these stretches by DNA sequence and functional analyses. The sequences showed that both of the catabolic regions contain a set of four genes which are transcribed in the same direction. The occ and noc region genes are related, but the arrangement of the genes is different. The deduced polypeptides are related to those of binding protein-dependent transport systems of basic amino acids in other bacteria. The comparison suggested that three of the polypeptides are located in the membrane and that one is a periplasmic protein. We constructed cassettes which contained either the putative transport genes only or the complete occ or noc region; all constructs, however, included the elements necessary for opine-induced expression of the genes (the regulatory gene and the inducible promoters). Uptake studies with 3H-labelled octopine showed that the putative transport genes in the occ region code for octopine uptake proteins. The corresponding studies with 3H-labelled nopaline and the noc region cassettes indicated that the uptake of nopaline requires the putative transport genes and additional functions from the left part of the noc region.     

Octopine and nopaline oxidases from Ti plasmids of Agrobacterium tumefaciens: molecular analysis, relationship, and functional characterization.

The occ and noc regions of pTiAch5 (octopine) and pTiC58 (nopaline) Ti plasmids are responsible for the catabolic utilization of octopine and nopaline in Agrobacterium spp. The first enzymatic step is the oxidative cleavage into L-arginine and pyruvate or 2-ketoglutarate, respectively, by membrane-bound opine oxidases requiring two polypeptides (subunits B and A) for function. The DNA sequences showed that the subunits of pTiAch5 and pTiC58 are related, but none of the proteins revealed significant similarities to the biosynthetic enzymes expressed in transformed plant cells. The four proteins had no extensive overall similarity to other proteins, but the 35 N-terminal amino acids contained motifs found in many enzymes utilizing flavin adenine dinucleotide, flavin mononucleotide, or NAD(P)+ as cofactors. However, the activities were completely independent of added cofactors, and the nature of the electron acceptor remained unclear. Membrane solubilization led to complete loss of enzyme activity. The nopaline oxidase accepted nopaline and octopine (Vmax ratio, 5:1) with similar Km values (1.1 mM). The octopine oxidase had high activity with octopine (Km = 1 mM) and barely detectable activity with nopaline. The subunits from the occ and the noc regions were exchangeable. The combinations ooxB-noxA and noxB-ooxA both produced active enzymes which oxidized octopine and nopaline at similar rates, suggesting that both subunits contributed to the substrate specificity. These experiments also showed that the formation of functional enzyme required close proximity of the subunit genes on the same plasmid and that even a reversal of the gene order (A-B instead of B-A) led to reduced activity.     

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.     

Detection of opines by colorimetric assay

A colorimetric procedure for confirming the presence of arginine-derived opines (nopaline and octopine) in plant tissue extracts is described. Those materials are widely used as markers of plant cell transformation and tumorigenesis mediated by the tumor-inducing plasmids of Agrobacterium tumefaciens. Nopaline and octopine are generally detected, following resolution by paper electrophoresis, by observation of the uv-fluorescent products formed upon reaction with phenanthrenequinone. We found that a further heat treatment step, compatible with paper electrophoresis, results in rapid production of a red-purple pigment. Our colorimetric assay is sensitive to 1.25-micrograms quantities of opine and eliminates problems of background fluorescence encountered with crude plant extract in the usual assay.     

Multiple genes coding for octopine-degrading enzymes in Agrobacterium.

Most biotype 2 strains of Agrobacterium tumefaciens and A. radiobacter which utilize nopaline also degrade octopine. In all such strains studied, the ability to degrade octopine did not appear to be transferred to plasmidless recipient cells under conditions of plasmid transfer in which the ability to utilize nopaline was transferred. An octopine-degrading mutant was isolated in a strain cured of its plasmid, suggesting that genes of octopine degradation may have a chromosomal location in some strains. In strains in which octopine utilization is coded by plasmid genes, octopine degradation was always inducible, whereas in strains which degrade both octopine and nopaline, octopine utilization was constitutive although nopaline degradation was inducible. When plasmids coding for octopine-utilizing ability were transformed into a strain containing either a nopaline- or null-type plasmid, transformants able to degrade octopine were either not observed or were unstable upon purification. All of these data suggest that plasmids associated with virulence are incompatible with one another, and therefore imply that the major groups of plasmids associated with virulence have a common origin.     

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.     

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.     

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.     

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.     

Chimeric genes as dominant selectable markers in plant cells

Opine synthases are enzymes produced in dicotyledonous plants as the result of a natural gene transfer phenomenon. Agrobacteria contain Ti plasmids that direct the transfer, stable integration and expression of a number of genes in plants, including the genes coding for octopine or nopaline synthase. This fact was used as the basis for the construction of a number of chimeric genes combining the 5' upstream promoter sequences and most of the untranslated leader sequence of the nopaline synthase (nos) gene with the coding sequence of two bacterial genes: the aminoglycoside phosphotransferase (APH(3')II) gene of Tn5 and the methotrexate-insensitive dihydrofolate reductase (DHFR Mtx^R) of the R67 plasmid. The APH(3')II enzyme inactivates a number of aminoglycoside antibiotics such as kanamycin, neomycin and G418. Kanamycin, G418 and methotrexate are very toxic to plants. The chimeric NOS-APH(3')II gene, when transferred to tobacco cells using the Ti plasmid as a gene vector, was expressed and conferred resistance to kanamycin to the plant cells. Kanamycin-resistant tobacco cells were shown to contain a typical APH(3')II phosphorylase activity. This chimeric gene can be used as a potent dominant selectable marker in plants. Similar results were also obtained with a NOS-DHFR Mtx^R gene. Our results demonstrate that foreign genes are not only transferred but are also functionally expressed when the appropriate constructions are made using promoters known to be active in plant cells.     

Efficient functioning of plant promoters and poly(A) sites in Xenopus oocytes.

Mature Xenopus oocytes were challenged with DNA constructs including plant regulatory elements, namely, the Cauliflower mosaic virus (CaMV) 35S promoter as well as the nopaline synthase (NOS) promoter and polyadenylation signal. The bacterial chloramphenicol acetyl transferase (CAT) was used as a reporter gene. When microinjected into these cells, the plant-derived DNA constructs effectively promoted CAT synthesis in a manner dependent on the presence of the plant promoters and probably also on the polyadenylation signals. Structural studies revealed that the supercoiled structures of the above DNA plasmids were much more active in supporting CAT synthesis in microinjected oocytes than their linear forms, with clear correlation between efficient gene expression and DNA topology. In contrast, the linear forms of these plasmids were considerably more active than the supercoiled ones in transfected plant protoplasts. These findings demonstrate, for the first time, the activity of regulatory elements from plant genes in Xenopus oocytes and shed new light on the specific rules applicable for gene expression in plant and animal cells.     

Comparison of Ti plasmids from three different biotypes of Agrobacterium tumefaciens isolated from grapevines.

Twenty-six plasmids from grapevine isolates of Agrobacterium tumefaciens were analyzed by SmaI fingerprinting and by hybridization of nick-translated DNA to DNA of another plasmid. These experiments established that octopine Ti plasmids are not highly conserved, although octopine Ti plasmids from biotype 1 A. tumefaciens strains appeared to be very similar. Octopine Ti plasmids from biotype 3 strains are more variable in terms of host range and SmaI fingerprints, but share extensive DNA homology. Fingerprints of nopaline Ti plasmids from strains of a given biotype resemble each other but not fingerprints of Ti plasmids from strains of the other two biotypes. The wide host range octopine Ti plasmid from the biotype 3 strain Ag86 shares more DNA homology with narrow host range Ti plasmids, nopaline Ti plasmids, and octopine catabolism plasmids than with the wide host range octopine Ti plasmid from biotype 1 strain 20/1. pTiAg86 does share homology with the portion of pTi20/1 integrated and expressed in plant tumor cells. Since all wide host range Ti plasmids studied contain these sequences, we suggest that natural selection for a wide host range resulted in the presence of the common sequences in distantly related plasmids. The lack of homology between this "common DNA" and limited host range Ti plasmids shows that the DNA sequences per se are not required for tumorigenesis.     

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.     

Multiple domains exist within the upstream activator sequence of the octopine synthase gene.

It is known that a 16-base pair palindrome (ACGTAAGCGCTTACGT) located upstream of the ocs gene can activate a maize adh1 promoter in a transient expression system [Ellis et al. (1987). EMBO J. 6, 11-16; Ellis et al. (1987). EMBO J. 6, 3203-3208]. We have determined that this palindrome is also essential for ocs promoter activity in tobacco calli. In addition, sequences immediately adjacent to this palindrome, both 5' and 3', modulate its activity. The palindrome is sensitive to the differentiated state of the plant cells in which it resides; it is active in calli and the leaves of small shoots but is inactive in the leaves of rooted plants. We have tested upstream sequences from two other T-DNA genes that have homology to this palindrome for their ability to activate the octopine synthase promoter in tobacco calli. The upstream region from the mannopine synthase gene can activate the octopine synthase promoter, but an upstream region from the gene implicated in octopine and nopaline secretion cannot activate the promoter.