Organization and regulation of the mannopine cyclase-associated opine catabolism genes in Agrobacterium tumefaciens 15955.

We have isolated and characterized Tn3HoHo1- and Tn5-induced mutants of a cosmid clone, pYDH208, which encodes the mannopine (MOP) cyclase-associated catabolism of MOP and agropine (AGR). Characterization of the transposon-induced lacZ fusion mutants by beta-galactosidase activity and mannityl opine utilization patterns identified at least 6 genetic units associated with the catabolism of these opines. Functions for the catabolism of MOP and mannopinic acid are encoded by a 16.4-kb region, whereas those for AGR are encoded by a 9.4-kb region located within the MOP catabolic locus. The induction pattern of catabolism shown by transposon insertion derivatives suggests that the catabolism of MOP, AGR, and mannopinic acid encoded by pYDH208 is regulated by at least two independent control elements. Kinetic uptake assays indicate that the clone encodes two transport systems for MOP and AGR, one constitutive and slow and the other inducible and rapid. Analysis of beta-galactosidase activities from lacZ reporter gene fusions indicated that expression of mannityl opine catabolic genes is not strongly repressed by sugars but is repressed by succinate when ammonium is the nitrogen source. The repression exerted by succinate was relieved when MOP was supplied as the sole source of nitrogen. This suggests that genes for opine catabolism encoded by pYDH208 are regulated, in part, by nitrogen availability.     

Genes for utilization of deoxyfructosyl glutamine (DFG), an amadori compound, are widely dispersed in the family Rhizobiaceae

Amadori compounds form spontaneously in decomposing plant material and can be found in the rhizosphere. As such, these compounds could influence microbial populations by serving as sources of carbon, nitrogen and energy to microorganisms expressing suitable catabolic pathways. Two distinct sets of genes for utilization of deoxyfructosyl glutamine (DFG), an Amadori compound, have been identified in isolates of Agrobacterium spp. One, the soc gene set, is encoded by pAtC58, a 543 kb plasmid in A. tumefaciens strain C58. The second, mocD dissimilates DFG formed in the pathway for catabolism of mannopine (MOP) a non-Amadori, imine-type member of the mannityl opine family characteristic of certain Ti and Ri plasmids. To assess the level of dispersal of these two Amadori-utilizing systems, isolates of Agrobacterium spp. and related bacteria in the family Rhizobiaceae were examined by Southern analysis for homologs of socD and mocD. Homologs of mocD were associated only with Ti plasmid-encoded pathways for catabolism of MOP. Homologs of socD were more widely distributed, being detectable in many but not all of the isolates of Agrobacterium, Sinorhizobium, and Rhizobium spp. tested. However, this gene was never associated with the virulence elements, such as the Ti and Ri plasmids, in these strains. Regardless of genus most of the isolates containing socD homologs could utilize DFG as sole source of carbon, nitrogen and energy. Correlation studies suggested that mocD has evolved uniquely as part of the mannityl opine catabolic pathway while socD has evolved for the general utilization of Amadori compounds. Certain isolates of Agrobacterium and Rhizobium that lacked detectable homologs of socD and mocD also could utilize DFG suggesting the existence of additional, unrelated pathways for the catabolism of this Amadori compound. These results suggest that Amadori compounds constitute a source of nutrition that is important to microflora in the rhizosphere.     

A Ti plasmid-encoded enzyme required for degradation of mannopine is functionally homologous to the T-region-encoded enzyme required for synthesis of this opine in crown gall tumors.

The mocC gene encoded by the octopine/mannityl opine-type Ti plasmid pTi15955 is related at the nucleotide sequence level to mas1' encoded by the T region of this plasmid. While Mas1 is required for the synthesis of mannopine (MOP) by crown gall tumor cells, MocC is essential for the utilization of MOP by Agrobacterium spp. A cosmid clone of pTi15955, pYDH208, encodes mocC and confers the utilization of MOP on strain NT1 and on strain UIA5, a derivative of NT1 lacking the 450-kb cryptic plasmid pAtC58. NT1 or UIA5 harboring pYDH208 with an insertion mutation in mocC failed to utilize MOP as the sole carbon source. Plasmid pSa-C, which encodes only mocC, complemented this mutation in both strains. This plasmid also was sufficient to confer utilization of MOP on NT1 but not on UIA5. Computer analysis showed that MocC is related at the amino acid sequence level to members of the short-chain alcohol dehydrogenase family of oxidoreductases. Lysates prepared from Escherichia coli cells expressing mocC contained an enzymatic activity that oxidizes MOP to deoxyfructosyl glutamine (santhopine [SOP]) in the presence of NAD+. The reaction catalyzed by the MOP oxidoreductase is reversible; in the presence of NADH, the enzyme reduced SOP to MOP. The apparent Km values of the enzyme for MOP and SOP were 6.3 and 1.2 mM, respectively. Among analogs of MOP tested, only N-1-(1-deoxy-D-lyxityl)-L-glutamine and N-1-(1-deoxy-D-mannityl)-L-asparagine served as substrates for MOP oxidoreductase. These results indicate that mocC encodes an oxidoreductase that, as an oxidase, is essential for the catabolism of MOP. The reductase activity of this enzyme is precisely the reaction ascribed to its T-region-encoded homolog, Mas1, which is responsible for biosynthesis of mannopine in crown gall tumors.     

A novel gene tag for identifying microorganisms released into the environment.

A novel method using a moc (mannityl opine catabolism) region from the Agrobacterium tumefaciens Ti plasmid pTi15955 was developed as a tag to identify genetically modified microorganisms released into the environment. Pseudomonas fluorescens 1855.344, a plant-growth-promoting rhizosphere bacterium, was chosen as the organism in which to develop and test the system. moc genes carried by pYDH208, a cosmid clone containing a 20-kb segment of the octopine-mannityl opine-type Ti plasmid, conferred on P. fluorescens strains the capacity to utilize mannopine and agropine (AGR) as a sole source of carbon and energy. Modified P. fluorescens strains containing moc or moc::nptII inserted into a chromosomal site were constructed by marker exchange. One such modified strain, PF5MT12, utilized AGR as a sole carbon source and contained detectable levels of mannopine cyclase, an easily assayable enzyme encoded by the moc region. Catabolism of AGR could be used to recover selectively the marked strain from mixed populations containing a large excess of closely related bacteria. Nucleic acid-based detection strategies were developed on the basis of the unique fusion region between Agrobacterium DNA and Pseudomonas DNA in strain PF5MT12. The specificity and sensitivity of detection of PF5MT12 were enhanced by amplifying the fused DNA region by using PCR. The target fragment could be detected at levels of sensitivity comparable to those of other described PCR-based gene tags, even in the presence of high levels of Agrobacterium, Pseudomonas, or Escherichia coli DNA. This gene tag strategy gives a method for direct selection and enumeration of the marked strain from mixtures containing a large excess of closely related bacteria and a sensitive and highly specific system for detection by PCR amplification of the target fragment even in the presence of large amounts of DNA from related or unrelated organisms.     

Functional role of the Ti plasmid-encoded catabolic mannopine cyclase in mannityl opine catabolism by Agrobacterium spp.

Catabolic mannopine (MOP) cyclase encoded by Ti or Ri plasmids lactonizes MOP to agropine (AGR). The gene of the octopine-type Ti plasmid pTi15955 encoding the catabolic MOP cyclase enzyme previously was localized to a 1.6-kb segment within a cosmid clone, pYDH208. A subclone containing only this region complemented the AGR catabolism-negative phenotype conferred by a derivative of the octopine-type plasmid pTiB6S3 containing a Tn7 insertion in the region encoding the MOP cyclase enzyme. Uptake assays of strains harboring pRiA4 or pArA4a, along with complementation analyses, indicate that MOP cyclase is not sufficient for catabolism of AGR but that the strains must also express an AGR transport system. To determine the requirement for MOP cyclase in opine catabolism unequivocally, a site-specific, nonpolar deletion mutation abolishing only MOP cyclase activity was introduced into pYDH208, a cosmid clone that confers utilization of MOP, AGR, and mannopinic acid (MOA). Strains harboring this MOP cyclase-negative mutant clone, pYDPH208, did not utilize AGR but continued to utilize MOP. Growth on AGR was restored in this strain upon introduction of clones encoding the pTi15955-derived catabolic or anabolic MOP cyclase genes. The induction pattern of MOA catabolism shown by strain NT1 harboring the MOP cyclase-deficient pYDPH208 suggests that AGR is converted into MOP by MOP cyclase and that MOP, but not AGR, induces catabolism of MOA. Genetic and biochemical analyses of MOP and AGR metabolism suggest that only the conversion of AGR to MOP is directly involved in catabolism of AGR, even though the reaction catalyzed by MOP cyclase predominantly lies in the lactonization of MOP to AGR.     

Intracellular accumulation of mannopine, an opine produced by crown gall tumors, transiently inhibits growth of Agrobacterium tumefaciens

pYDH208, a cosmid clone from the octopine-mannityl opine-type tumor-inducing (Ti) plasmid pTi15955 confers utilization of mannopine (MOP) and agropine (AGR) on Agrobacterium tumefaciens strain NT1. NT1 harboring pYDH208 with an insertion mutation in mocC, which codes for MOP oxidoreductase, not only fails to utilize MOP as a sole carbon source, but also was inhibited in its growth by MOP and AGR. In contrast, the growth of mutants with insertions in other tested moc genes was not inhibited by either opine. Growth of strains NT1 or UIA5, a derivative of C58 that lacks pAtC58, was not inhibited by MOP, but growth of NT1 or UIA5 harboring pRE10, which codes for the MOP transport system, was inhibited by the opine. When a clone expressing mocC was introduced, the growth of strain NT1(pRE10) was not inhibited by MOP, although UIA5(pRE10) was still weakly inhibited. In strain NT1(pRE10, mocC), santhopine (SOP), produced by the oxidation of MOP by MocC, was further degraded by functions encoded by pAtC58. These results suggest that MOP and, to a lesser extent, SOP are inhibitory when accumulated intracellularly. The growth of NT1(pRE10), as measured by turbidity and viable cell counts, ceased upon the addition of MOP but restarted in a few hours. Regrowth was partly the result of the outgrowth of spontaneous MOP-resistant mutants and partly the adaptation of cells to MOP in the medium. Chrysopine, isochrysopine, and analogs of MOP in which the glutamine residue is substituted with other amino acids were barely taken up by NT1(pRE10) and were not inhibitory to growth of the strain. Sugar analogs of MOP were inhibitory, and those containing sugars in the D form were more inhibitory than those containing sugars in the L form. MOP analogs containing hexose sugars were more inhibitory than those containing sugars with three, four, or five carbon atoms. Mutants of NT1(pRE10) that are resistant to MOP arose in the zone of growth inhibition. Genetic and physiological analyses indicate that the mutations are located on pRE10 and abolish uptake of the opine.     

Detection and Enumeration of a Tagged Pseudomonas fluorescens Strain by Using Soil with Markers Associated with an Engineered Catabolic Pathway

Previously we described a novel gene tagging method, using the moc (mannityl opine catabolism) region from the Agrobacterium tumefaciens Ti plasmid pTi15955, to identify microorganisms destined for release into the environment. Here, we used the engineered strain Pseudomonas fluorescens PF5MT12 carrying the moc region integrated into the bacterial chromosome to demonstrate the usefulness of the markers for detection and direct selection of marked organisms present in soil samples. Using this system, we routinely detected population levels as low as 10(sup2) CFU per g of soil sampled. In addition to direct selection, we developed an immunologically based assay using MOP cyclase, a unique enzyme associated with moc, as the epitope for detecting the tagged organism. The colony immunoblot assay proved to be highly specific and without any false-positive signals when used to identify organisms cultured from soil on nonselective medium. The numbers of colonies that were immunoreactive with the anti-MOP cyclase antibody were essentially equal to those that grew out on selection plates. This indicates that MOP cyclase can be used as a marker and that we can use nonselective medium to retrieve the marked genetically engineered microorganisms and then identify them by using colony immunoblot assays. These direct selection and colony immunoblot methods provide a sensitive and accurate strategy for identifying and enumerating marked organisms recovered from soil samples. We also developed a rapid assay for MOP cyclase that does not require cell permeabilization with toluene. This assay can be used to verify tagged organisms isolated by other methods or to screen large numbers of colonies for the tag following nonselective isolation.     

Genetic analysis of mannityl opine catabolism in octopine-type Agrobacterium tumefaciens strain 15955

Summary The genetic organization of functions responsible for mannityl opine catabolism of the Ti plasmid of Agrobacterium tumefaciens strain 15955 was investigated. A partial HindIII digest of pTi15955 was cloned into a broad host range cosmid and the clones obtained were tested for ability to confer mannityl opine degradation upon Agrobacterium. Inserts containing genes for catabolism of mannopinic acid, mannopine, agropine, and agropinic acid were obtained, spanning a segment of 43 kb on the Ti plasmid. Two clones conferring upon Agrobacterium the ability to catabolize the mannityl opines were mobilized to several Rhizobium sp., to Pseudomonas putida and P. fluorescens and to Escherichia coli. The catabolic functions were phenotypically expressed in all Rhizobium sp. tested, and in P. fluorescens, but not in P. putida or in E. coli.     

Localization and characterization of the region encoding catabolism of mannopinic acid from the octopine-type Ti plasmid pTi15955

The region of the octopine-type tumor-inducing (Ti) plasmid pTi15955 encoding catabolism of mannopinic acid was localized to an 18-kilobase (kb) segment mapping between Ti plasmid coordinates 70 and 88. A subclone containing only this region normally did not allow utilization of any other mannityl opine. However, spontaneous mutants of the plasmid were isolated that conferred catabolism of agropinic acid. While the mutants remained regulated for mannopinic acid utilization, induction by this opine resulted in increased activity associated with agropinic acid catabolism. Respirometric studies and results from growth assays on mannopinic acid analogues indicated that the genes encoded on the 18-kb subclone were regulated in a wild-type fashion. By means of these analogues, spontaneous constitutive mutants were isolated. In several cases, the mutant phenotype was associated with an insertion event mapping within a 300-base pair region of the subclone insert. Although constitutive for catabolism of mannopinic acid, these mutants remained unable to catabolize any of the other mannityl opines. Segregation studies and genetic reconstitution experiments showed that one of the subclones isolated directly in Agrobacterium was actually composed of two complementing recombinant plasmids contained in the same cell. This indicated that the genes encoding mannopinic acid catabolism were organized into at least two complementation groups. These results point to a high degree of complexity in the organization and regulation of Ti plasmid genes encoding catabolism of a relatively simple carbon source.     

L,L-Succinamopine: an epimeric crown gall opine

Alfalfa tumour incited by Agrobacterium tumefaciens strain A281, carrying the tumour inducing plasmid pTi Bo542, synthesizes agropine and related mannityl opines. In addition it contains a small amount of leucinopine and large quantities of a new opine here identified as N-[(1S)-1-carboxy 2-carbamoylethyl]-(S)-glutamic acid. This new opine, L,L-succinamopine, is the L^glu epimer of the succinamopine previously isolated from tumours incited by pTi AT181 and related strains. The latter opine should now be designated D,L-succinamopine. This is the first example of the natural occurrence of epimeric opine structures.     

Purification and characterization of catabolic mannopine cyclase encoded by the Agrobacterium tumefaciens Ti plasmid pTi15955.

Catabolic mannopine (MOP) cyclase encoded by certain Agrobacterium Ti and Ri plasmids lactonizes MOP to agropine (AGR). The enzyme, purified to homogeneity from a recombinant clone, has a molecular mass of 45 kDa as measured by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and size exclusion chromatography. The enzyme catalyzed the lactonization of MOP to AGR without the need for any cofactors. The enzyme also converted AGR to MOP with the lactonizing activity being predominant over the reverse reaction. MOP cyclase is specific for imine conjugates of D-hexose and L-glutamine and was not inhibited by sugars or amino acids. The enzyme lactonized deoxyfructosyl glutamine, a natural intermediate of MOP synthesis and catabolism, to a product indistinguishable from chrysopine, a newly discovered crown gall opine. The enzyme also lactonized N-l-(1,2-dideoxy-D-mannityl)-L-glutamine, indicating that a hydroxyl group at carbon atom 2 of the sugar moiety is not required for the enzymatic reaction.     

Mannityl opine analogs allow isolation of catabolic pathway regulatory mutants

Five virulent Agrobacterium spp. strains that can catabolize the mannityl opines mannopine (MOP), mannopinic acid ( MOA ), and agropinic acid (AGA) were tested for their ability to grow on analogs of these compounds. Analogs containing alternative amino acids replacing glutamic acid or glutamine were generally refused by these bacteria, but mutants were obtained that catabolized the entire family of analogs. In the case of strain C58C1 (pRi 8196), we demonstrated that typical mutants were constitutive for MOP uptake, whereas the wild-type parent was inducible by MOP. Analogs of MOA prepared from a variety of sugars instead of mannose were generally refused, except for a strain carrying pTi B6-806, which grew well on all such analogs. The analogs allowed selection of mutants of all strains. Although most wild-type strains were inducible for AGA uptake, typical mutants selected from strain C58C1 (pRi 8196) were found to be constitutive for uptake of AGA, as was the wild-type strain carrying pTi B6-806. Such constitutive mutants grew on all sugar analogs of MOP, MOA , and AGA tested. The pTi B6-806-containing strain was tested for growth on a more extended series of analogs, including tetrose , triose, diose , and disaccharide analogs, all of which were accepted. Only ketose analogs were refused. Selection of promiscuous regulatory mutants by the two types of opine analogs suggests that the repressor proteins of MOP and AGA permease/ catabolase systems are chiefly responsible for the specificity of the pathways.     

Putative evolutionary origin of plasmids carrying the genes involved in leucine biosynthesis in Buchnera aphidicola (endosymbiont of aphids).

An 8.5-kb plasmid encoding genes (leuABCD) involved in leucine biosynthesis and a small plasmid of 1.74 kb of yet unknown function were found in the intracellular symbiont, Buchnera aphidicola, of two divergent aphid species, Thelaxes suberi and Tetraneura caerulescens, respectively. The leuABCD-carrying plasmid (pBTs1) was amplified from total aphid DNA by inverse long PCR, using outwardly oriented oligonucleotide primers specific to leuA. The resulting 8.2-kb PCR fragment as well as the 1.74-kb plasmid (pBTc1) were cloned and sequenced. pBTs1 differed from a previously described B. aphidicola plasmid (pRPE) of the aphid Rhopalosiphum padi by the presence of a small heat shock gene (ibp) and in the order of the leuABCD and repA genes. Comparison of both leucine plasmids to the small plasmid pBTc1 revealed extensive similarity with respect to putative replication functions as well as in the presence of a highly conserved open reading frame that was found to be homologous to Escherichia coli YqhA and Haemophilus influenzae HI0507 and which may encode an integral membrane protein. The three B. aphidicola plasmids most likely evolved from a common ancestral replicon, which in turn may be distantly related to IncFII plasmids. Phylogenetic affiliations of the B. aphidicola strains of the two aphid species were assessed by sequencing of their 16S rRNA genes. Evaluation of the distribution of the leuABCD-encoding plasmids within a phylogenetic framework suggests independent origins for pBTs1 and pRPE from an ancestral replicon resembling pBTc1. The implications for symbiotic essential amino acid biosynthesis and provisioning are discussed.     

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.     

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.     

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.     

Spontaneous mutation conferring the ability to catabolize mannopine in Agrobacterium tumefaciens.

Two nopaline-type strains of Agrobacterium tumefaciens, C58 and T37, as well as strain A136, which is a Ti plasmid-cured derivative of strain C58, gave rise to spontaneous mutants that were able to grow on mannopine. The observation of mutagenesis with strain A136 demonstrated that the ability to acquire this new catabolic potential was independent of the presence of a Ti plasmid. The mutants were isolated after 4 weeks of incubation on minimal medium containing mannopine as the sole carbon source. They also utilized mannopinic acid, but not agropine or agropinic acid. In addition, the spontaneous mutant LM136, but not its parent strain A136, degraded many mannityl opine analogs. [14C]mannopine disappeared in the presence of LM136 cells which had been pregrown on opine or nonopine substrates. These results suggested that the catabolic system of this mutant was not subject to a stringent regulation. A clone conferring the ability to utilize mannopine on a recipient pseudomonad was selected from a genomic library from both the mutant LM136 and its parent strain. Only the LM136 clone was expressed in the parent Agrobacterium strain A136. Southern analysis showed that the genes for mannopine catabolism in the spontaneous mutants differed from the corresponding Ti plasmid-encoded genes of octopine-type or agropine-type Agrobacterium strains. Cells of LM136 utilized [14C]mannopine without generating detectable amounts of intracellular agropine. In contrast, a major fraction of the radioactivity recovered from cells of the octopine-type strain Ach5, after incubation on [14C]mannopine, was in the form of agropine.     

Diversity among Opine-Utilizing Bacteria: Identification of Coryneform Isolates

Bacteria were isolated from soil and crown gall tumors by selection in minimal medium with an opine, such as succinamopine or mannopine, as the sole carbon source. The isolates were characterized for the pattern of opine utilization and identified. They were classified as mannityl opine or imino diacid utilizers and exhibited specificity of utilization similar to that described previously for Agrobacterium species. A minority of isolates were gram negative and were identified as Agrobacterium or Pseudomonas species; most were gram positive and belonged to the coryneform group. These results indicate that any specific effect of opines on the ecology of Agrobacterium tumefaciens is modulated by activities of other types of soil- and plant-associated bacteria.