Localization of agropine-synthesizing functions in the TR region of the root-inducing plasmid of Agrobacterium rhizogenes 1855

Niche Construction and Exploitation by Agrobacterium: How to Survive and Face Competition in Soil and Plant Habitats

Agrobacterium populations live in different habitats (bare soil, rhizosphere, host plants), and hence face different environmental constraints. They have evolved the capacity to exploit diverse resources and to escape plant defense and competition from other microbiota. By modifying the genome of their host, Agrobacterium populations exhibit the remarkable ability to construct and exploit the ecological niche of the plant tumors that they incite. This niche is characterized by the accumulation of specific, low molecular weight compounds termed opines that play a critical role in Agrobacterium 's lifestyle. We present and discuss the functions, advantages, and costs associated with this niche construction and exploitation.

Effect of pRi T-DNA genes and elicitation on morphology and phytoecdysteroid biosynthesis in Ajuga bracteosa hairy roots

Hairy roots of A. bracteosa raised after the infection of different A. rhizogenes strains resulted in phenotype-dependent phytoecdysteroid biosynthesis due to dissimilar integration of TL- and TR-DNA genes of pRi.

Production of triterpenoid anti-cancer compound taraxerol in Agrobacterium-transformed root cultures of butterfly pea (Clitoria ternatea L.)

Independent transformed root somaclones (rhizoclones) of butterfly pea (Clitoria ternatea L.) were established using explant co-cultivation with Agrobacterium rhizogenes. Rhizoclones capable of sustained growth were maintained under low illumination in auxin-free agar-solidified MS medium through subcultures at periodic intervals. Integration of T(L)-DNA rolB gene in the transformed rhizoclone genome was verified by Southern blot hybridization, and the transcript expression of T(R)-DNA ags and man2 genes was ascertained by reverse transcription polymerase chain reaction analysis. The major compound isolated and purified from the transformed root extracts was identified as the pentacyclic triterpenoid compound taraxerol using IR, (1)H-NMR, and (13)C-NMR spectroscopy. The taraxerol yield in cultured hairy roots, as quantified by HPTLC analysis, was up to 4-fold on dry weight basis compared to that in natural roots. Scanning of bands from cultured transformed roots and natural roots gave super-imposable spectra with standard taraxerol, suggesting a remarkable homology in composition. To date, this is the first report claiming production of the cancer therapeutic phytochemical taraxerol in genetically transformed root cultures as a viable alternative to in vivo roots of naturally occurring plant species.

Hairy roots are more sensitive to auxin than normal roots

Responses to auxin of Lotus corniculatus root tips or protoplasts transformed by Agrobacterium rhizogenes strains 15834 and 8196 were compared to those of their normal counterparts. Three different types of experiments were performed, involving long-term, medium-term, or short-term responses to a synthetic auxin, 1-naphthaleneacetic acid. Root tip elongation, proton excretion by root tips, and transmembrane electrical potential difference of root protoplasts were measured as a function of exogenous auxin concentration. The sensitivity of hairy root tips or protoplasts to exogenous auxin was found to be 100-1000 times higher than that of untransformed material.

Complementation of Agrobacterium tumefaciens tumor-inducing aux mutants by genes from the T(R)-region of the Ri plasmid of Agrobacterium rhizogenes

In this paper we provide information indicating that the agropine-type root-inducing (Ri) plasmid pRi1855 of Agrobacterium rhizogenes contains functional genes for auxin production (aux) in the right transferred DNA (T-DNA) region (T(R)-region). These genes were cloned and introduced into the T-region of the tumor-inducing (Ti) plasmids of mutants of Agrobacterium tumefaciens carrying an aux mutation. Depending on the Ri aux gene present, the oncogenicity of the Ti aux-1 and/or aux-2 mutations was restored, showing that the Ri aux genes are able to complement the Ti aux genes. Agrobacterium strains with an agropine-type Ri plasmid not only cause hairy root on certain plant species, but they also induce tumors on other plant species. In this paper it is shown that a mutation in either of the aux genes in the Ri plasmid leads to a total loss of tumorigenicity and a strongly diminished rhizogenicity of the host bacterium, revealing that the aux genes are important for tumor and root induction. Agrobacterium strains containing the T(R)-region but not the T(L) (left)-region of the Ri plasmid are still tumorigenic on certain plant species but are no longer capable of hairy-root induction.

Function of the aux and rol genes of the Ri plasmid in plant cell division in vitro

Auxin-autonomous growth in vitro may be related to the integration and expression of the aux and rol genes from the root-inducing (Ri) plasmid in plant cells infected by agropine-type Agrobacterium rhizogenes. To elucidate the functions of the aux and rol genes in plant cell division, plant cell lines transformed with the aux1 and aux2 genes or with the rolABCD genes were established using tobacco (Nicotiana tabacum) Bright Yellow-2 (BY-2) cells. The introduction of the aux1 and aux2 genes enabled the auxin-autonomous growth of BY-2 cells, but the introduction of the rolABCD genes did not affect the auxin requirement of the BY-2 cells. The results clearly show that the aux genes are necessary for auxinautotrophic cell division, and that the rolABCD genes are irrelevant in auxin autotrophy.

Improved podophyllotoxin production by transformed cultures of Linum album

Various cell and hairy root cultures of L. album were developed and analyzed for podophyllotoxin content. Transformed callus and hairy root cultures developed from infection of stem portions of in vitro-germinated L. album plant with Agrobacterium rhizogenes NCIM 5140 strain were selected on the basis of high podophyllotoxin content and growth. Based on the integration of Ri T(L)-DNA and T(R)-DNA, integration of only the ags and not the rol gene in transformed cell culture indicated fragmented integration pattern. The effect of different cultivation media and carbon source on growth and podophyllotoxin production were studied in shake-flask suspension cultures. Detailed batch growth and production kinetics with sugar consumption profile were also established. Maximum volumetric productivity of 4.40 and 2.75 mg/L per day was obtained in cell suspension and hairy root cultures, respectively.

Gain of function assays identify non-rol genes from Agrobacterium rhizogenes TL-DNA that alter plant morphogenesis or hormone sensitivity

This study tested the morphogenetic potential of 15 open reading frames of the TL-DNA of Agrobacterium rhizogenes strain HRI. These open reading frames were expressed individually under the control of the 35S RNA promoter in transgenic tobacco plants (Nicotiana tabacum L.). Expression of three T-DNA loci, ORF3n, ORF8 and ORF13, alters plant morphogenesis or the response of transgenic tissues to plant hormones. ORF3n transgenic plants are characterized by retarded flowering, altered internode elongation, altered leaf shape and, in particular, leaf tip necrosis. ORF3n and ORF8 expression reduces the sensitivity to auxin and cytokinin in combination or auxin alone. Tetracycline-dependent expression of ORF13 overcomes a selection of low levels of expression during plant regeneration and reveals a strong inhibitory effect of the ORF13 gene product on cell division and cell elongation. We conclude that the A. rhizogenes TL-DNA harbors genetic information that is important for pathogenicity apart from the well studied rol genes. We propose that these genes play mainly a negative regulatory role during pathogenesis. Moreover, these loci might be relevant to successful infections in specific host plants.

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.

Different promoter regions control level and tissue specificity of expression of Agrobacterium rhizogenes rolB gene in plants

Expression of the rolB gene of A. rhizogenes T-DNA triggers root differentiation in transformed plant cells. In order to study the regulation of this morphogenetic gene, the GUS reporter gene was placed under the control of several deleted fragments of the rolB 5' non-coding region: carrot disc transformations and the analysis of transgenic tobacco plants containing these constructions identified the presence of distinct regulatory domains in the rolB promoter. Two regions (located from positions -623 to -471 and from -471 to -341, from the translation start codon) control the level but not the tissue specificity of rolB expression: progressive deletions of the rolB promoter starting from position -1185 to -341, although at different levels, maintained the same pattern of GUS expression-maximal in root meristems and less pronounced in the vascular tissue of aerial organs. Further deletion of 35 bp, from -341 to -306, drastically affected tissue specificity: GUS activity was still clearly detectable in the vascular tissue of the aerial organs while expression in the root meristem was totally suppressed. Analysis of transgenic embryos and seedlings confirmed that distinct promoter domains are responsible for meristematic (root) and differentiated (vascular) expression of rolB. Finally, we present data concerning the effects of plant hormones on the expression of rolB-GUS constructions.

Organization of the agropine synthesis region of the T-DNA of the Ri plasmid from Agrobacterium rhizogenes

The agropine/mannopine synthesis region of the TR region of the Ri plasmid of Agrobacterium rhizogenes strain A4 was localized on the basis of sequence similarity with probes from Ti plasmids of Agrobacterium tumefaciens and analysis of transposon insertions. The nucleotide sequence of the right part of the TR-DNA of pRiA4, encompassing the three genes involved in mannityl-opine synthesis, was determined and compared to the sequence of the corresponding region of the octopine-type Ti plasmid pTi15955. The organization of this region is strongly conserved between Ri and Ti plasmids, but the similarity is restricted to the coding sequences: no homology was detected in the 5' and 3' flanking sequences. The mas1' and ags proteins are the most conserved, showing more than 68% amino acid conservation, whereas the mas2' proteins are only 59% identical. Significant G/C content and codon usage differences are observed between pTi15955 and pRiA4. An open reading frame strongly similar to that of bacterial repressors is situated immediately to the right of the TR region.

Induction and growth properties of carrot roots with different complements of Agrobacterium rhizogenes T-DNA

Single and multiple infections of carrot discs were carried out with Agrobacterium strains harbouring different segments of pRi1855 TL-DNA cloned in the binary vector Bin 19 and with a strain carrying the TR-DNA from the same Ri plasmid. Roots induced by the various co-inoculations were cultured and their growth patterns were followed. Abundant roots could be induced by TL-DNA rol genes A, B and C as a single insert (rolA + B + C) and by rolB alone provided an extended segment beyond its 5' non-coding region was included in the construction. A depression of rooting capability was caused by the inclusion of rolC together with rolB (rolB + C). In all cases co-inoculation with the Agrobacterium carrying TR-DNA-borne auxin genes was necessary for root induction since none of the rol constructions was in itself capable of eliciting any response; an exceeding majority of these roots were however shown to contain rol genes but no TR-DNA. Rooting was also elicited if rol constructions were co-inoculated with a strain carrying TL-DNA genes 13 and 14 (ORF13 + 14) instead of the TR-DNA strain. These roots were shown to contain both rol genes and ORF13 + 14. Striking differences in growth properties were shown by roots containing different complements of TL-DNA genes. Typical hairy root traits, high growth rate, branching and, most noticeably, absence of geotropism, were shown by roots containing rolB alone, while roots with rolA + B + C were geotropic as normal carrot roots. Hairy root traits were conferred to rolA + B + C roots by the concomitant presence of ORF13 + 14 and by the addition of auxin to the culture medium. A model is presented which attempts to rationalize the growth patterns by assigning interplaying roles to the various TL-DNA genes involved.

Genetic transformation ofCatharanthus roseus G. Don byAgrobacterium rhizogenes

Catharanthus roseus plantlets were inoculated with differentAgrobacterium rhizogenes strains. This plant species is known to produce secondary metabolites and axenic hairy-root cultures are an alternative to extraction of plant tissue for the compounds which are synthesized in roots. Hairy root lines were established from inoculations with the agropine strain 15834 and transformed plants were obtained after spontaneous regeneration. Phenotypic alterations of both the root system and the aerial parts were observed in transformed plants. All the tissues analyzed contained agropine and mannopine. T-DNA analysis confirmed the presence of TL- and TR-DNAs either as distinct inserts, or as a single and continuous insert including the region between TL and TR on pRi 15834.

A common organization of the T-DNA genes expressed in plant hairy roots induced by different plasmids of Agrobacterium rhizogenes

The recently described pathogenic plasmid from Agrobacterium rhizogenes 2659 induces "hairy root" proliferation in infected plants which synthesize a new opine type, provisionally called cucumopine. The T-DNA restriction site map of 2659 differs from other pRi T-DNAs, i.e., mannopine and agropine. However all these three different T-DNAs have a similar organization as detected through hybridization. This, previously shown by our cross-hybridization studies between mannopine and agropine pRi T-DNAs, is here extended to the cucumopine pRi T-DNA; each of the three pRi T-DNA is composed of successive DNA regions that would find actual counterparts in the two other T-DNAs. Equivalence of DNA regions is suggested by their similar length, location and organization in the three T-DNAs and by their sequence homology substantial enough to be reproducibly cross-hybridized in all our experiments. This suggests that the three pRi T-DNAs share most of their functions. This was sought by analysing the pRi 2659 T-DNA gene expression in transformed plant tissues. The mRNA species observed in pRi 2659 carrot hairy roots of in vitro cultures give a pattern that is rather unvariable and resembles those described for some agropine type pRi transformant tissues. This transcript pattern is consistent with the preservation in the pRi 2659 T-DNA of counterparts of most of the open reading frames detected in the TL-DNA of agropine type pRis.

rolA locus of the Ri plasmid directs developmental abnormalities in transgenic tobacco plants

Plants containing the left T-DNA (TL) of Agrobacterium rhizogenes show a variety of developmental abnormalities that include severely wrinkled leaves, loss of apical dominance, reduced geotropism of roots, reduced internode distances, and floral hyperstyly. The TL-DNA also affects the morphology of tumor tissue at the site of inoculation on Kalanchoe diagremontiana leaves. Single mutations at four loci of the TL-DNA (rolA, rolB, rolC, and rolD) are known to affect tumor morphology on K. diagremontiana leaves. We regenerated plants from tissues transformed with TL-DNA containing mutations in each of the rol loci in order to determine which of the rol loci, if any, control the abnormal plant phenotype. Only plants regenerated after infection with bacteria containing a mutation in rolA locus showed loss of the wrinkled leaf phenotype. The rolA locus was cloned into the plant transformation vector pGA472 and introduced alone into plants. Transgenic plants containing rolA displayed the abnormal phenotype. These results indicate that rolA is the primary determinant of the severely wrinkled phenotype of Ri plasmid transgenic plants. Other rol loci may influence the degree of developmental abnormalities.

Genetic transformation of cauliflower (Brassica oleracea L. var. Botrytis) by Agrobacterium rhizogenes

Cauliflower plantlets were inoculated with different Agrobacterium rhizogenes strains. Numerous hairy roots were induced on cauliflower hypocotyls by agropine-type strains. Fewer roots were obtained with mannopine-type strains. In vitro cultures were established both from normal and hairy roots. Plant regeneration occured spontaneously from normal and transformed roots. Regenerated plants contained the same opines (if present) as root cultures. Some mannopine-positive regenerants displayed a modified phenotype. Relationships between phenotype, opine content, T-DNA content and/or expression are discussed.

Homology mapping of T-DNA regions on three Agrobacterium rhizogenes Ri plasmids by electron microscope heteroduplex studies

Recombinant plasmids carrying segments of the Agrobacterium rhizogenes T-DNA regions of the three Ri plasmids 1855 (TL-DNA only), 8196, and 2659 were used for establishing homology maps by electron microscope examination of heteroduplexes. Plasmid DNA was linearized by digestion with suitable restriction endonucleases in order to generate large T-DNA segments. Heteroduplexes were prepared in 50% formamide and spread under standard conditions. Measurements of double and single strands allowed the drawing of homology maps. The three T-DNAs share mainly two homologous sequences of respectively about 2.5 and 1.5 kb, bracketing a largely nonhomologous central part which is about 5.5 kb long. The T-DNAs from pRi1855 and pRi2659 appear to be more related to each other than to that of pRi8196. With reference to the published nucleotide sequence of the TL-DNA of pRiA4 (probably identical to that of pRi1855), ORFs 8 and 14 seem to be the most conserved sequences of the three T-DNAs. The significance of these conserved sequences is unclear since the genetic loci involved in rhizogenicity of agropine strains identified previously are located in nonhomologous regions.

Assessment of the efficiency of cotransformation of the T-DNA of disarmed binary vectors derived from Agrobacterium tumefaciens and the T-DNA of A. rhizogenes

Co-transfer of Agrobacterium rhizogenes T-DNA and T-DNA from the A. tumefaciens binary vector pBin19 (Bevan, 1984) was studied in detail using Nicotiana rustica. High frequencies of co-transfer of T-DNA's were observed, even when no selection pressure was exerted. Increased levels of pBin19 T-DNA were found in hairy root cultures with selection at higher levels of kanamycin sulphate (50-200 μg ml(-1)). Several other species were also transformed by A. rhizogenes carrying pBin19 and A. rhizogenes harbouring a different binary factor, pAGS125 (Van den Elzen et al., 1985), was used to transform N. rustica hairy roots to confer hygromycin B resistance.

Segregation of T-DNA copies in the progeny of a regenerant plant from a mannopine-positive hairy root line

We have analyzed opine content, T-DNA content, and developmental features of one hairy root culture line and its progeny. Opine-positive progeny still have the hairy root phenotype and have essentially the same T-DNA structure as the parental plant. Opineless progeny do not exhibit the hairy root phenotype. Some of them do not contain any T-DNA sequences, whereas others contain only the left part of T-DNA. These results are compatible with the hypothesis that, in the hairy root line analyzed, the left part of T-DNA is integrated independently from the core T-DNA and can therefore segregate during sexual reproduction.

Agrobacterium rhizogenes T-DNA genes capable of inducing hairy root phenotype

Segments of the TL-DNA of the agropine type Ri plasmid pRi 1855 encompassing single and groups of open-reading frames were cloned in the Ti plasmid-derived binary vector system Bin 19. Leaf disc infections on Nicotiana tabacum led to transformed plants, some of which showed typical hairy root phenotypes, such as the wrinkled leaf morphology, excessive and partially non geotropic root systems and the ability of leaf explants to differentiate roots in a hormone-free culture medium. Particularly interestingly, most of these traits were shown by plants transformed with a TL-DNA segment encompassing the single ORF 11, corresponding to the rolB locus. Hairy root can be induced by this latter T-DNA segment on wounded stems of tobacco plants; hairy root induction on carrot discs requires, on the contrary, a more complex complement of TL-DNA genes.

Homology studies demonstrate colinear organization of the transferred regions of plasmids pRi 1855 and pRi 8196 from Agrobacterium rhizogenes

Agrobacterium rhizogenes, a pathogenic bacterium determining for hairy-root tumors in plants, acts by insertion of a fragment (T-DNA) of its Ri plasmid into the plant nuclear DNA. Two A. rhizogenes strains, pRi 1855 and pRi 8196, responsible for similar disease symptoms, differ when compared at the structural level. However, some morphogenetic loci previously identified by insertion mutagenesis in either one of the two T-DNAs seem physiologically equivalent. The possibility that these morphogenetic loci are structurally similar was tested by cross-hybridization studies. Our data allow establishment of an unequivocal correspondence between the two T-DNA maps where apparently equivalent morphogenic loci occupy similar positions which suggests that the observed structural homologies also reflect physiological similarities between both T-DNAs.

Hairy root transformation in alfalfa (Medicago sativa L.)

The widely cultivated forage legume alfalfa (Medicago sativa L.) was transformed with the agropine type Agrobacterium rhizogenes NCPPB 1855. Sterile root and callus cultures were derived from tumorous hairy roots which were easily obtained independent of the plant variety or genotype. Plant regeneration, via somatic embryogenesis, was achieved only when a selected alfalfa line, characterized by high regenerative capability, was utilized. Genetic transformation was confirmed by the presence of agropine and T-DNA. Phenotypic alterations, mainly affecting the root system, were observed in transformed plants. The possibility that T-DNA-induced variations could be useful in the improvement of M. sativa is discussed.

Conserved regions in the T-DNA of different Agrobacterium rhizogenes root-inducing plasmids

The T-regions of the three so far identified types of Ri plasmids-corresponding to the synthesis of three different hairy root opines, agropine, mannopine and cucumopine-have been compared in detail by Southern blot cross hybridizations. Two distinct zones of very strong sequence homology, approximately 4 and 3 kilobases in length respectively, have been identified in all three T-regions. The highly conserved sequences, not present in Ti plasmid T-DNA, may encode essential rhizogenic functions common to all Agrobacterium rhizogenes T-DNAs.

T-DNA and opine synthetic loci in tumors incited by Agrobacterium tumefaciens A281 on soybean and alfalfa plants

We report here the molecular characterization of transferred DNA (T-DNA) in leguminous tumors incited by Agrobacterium tumefaciens A281 harboring the tumor-inducing plasmid pTiBo542. The T-DNA is composed of two regions named TL (left portion)-DNA and TR (right portion)-DNA, in accordance with the nomenclature for the octopine strains. TL-DNA is defined by several internal HindIII restriction fragments totaling 10.8 kilobase pairs (kbp) in uncloned soybean and alfalfa tumors. Alfalfa tumor DNA may contain one more HindIII fragment at the left end of TL-DNA than does soybean tumor DNA. TR-DNA has a 5.8-kbp BamHI-EcoRI internal fragment. All borders other than the left border of TL-DNA appear to be the same within the detection limits of Southern blot hybridization experiments. The two T-DNA regions are separated by 16 to 19 kbp of DNA not stably maintained in tumors. The distance from the left border of TL-DNA to the right border of TR-DNA is approximately 40 kbp. Loci for the mannityl opines are situated in TR-DNA, based on genetic and biochemical criteria.

Identification of hairy root loci in the T-regions of Agrobacterium rhizogenes Ri plasmids

Agrobacterium rhizogenes induces root formation at the wound site of inoculation in plants and inserts a fragment of its plasmid (Ri) into the plant nuclear DNA. Parts of the transferred region (T-region) of the Ri plasmid of A. rhizogenes strain A4 or 8196 are cloned in Escherichia coli. Insertions of the E. coli lacZ coding region into the hybrid plasmids were made in vivo using transduction by miniMu. Twenty insertions localized in the TL-DNA of pRiA4 (or pRi1855) and 2 inserts in the T-DNA of pRi8196 were obtained in E. coli. One of the TL-DNA insertions is saved up because it is linked to an internal T-DNA deletion; the others because they confer a lactose plus phenotype on E. coli; this indicates that the T-DNA harbours sequences that are expressed in E. coli. Fifteen of these T-DNA insertions were transfered to Agrobacterium where they substitute the corresponding wild-type T-DNA of the Ri plasmid by homologous recombination. These strains corresponding to insertion-directed mutagenesis were used to inoculate Daucus carota slices and stems and leaves of Kalanchoe daigremontiana. The two insertions strains obtained in the T-DNA of pRi8196 are avirulent on K. daigremontiana; but their phenotypes differ on D. carota slices, suggesting that insertions affect distinct loci on the T-DNA involved in hairy root formation. Only one insertion out of the twenty obtained in the TL-DNA of pRiA4 (or 1855) induces a loss of virulence on leaves of K. daigremontiana. However the TL-DNA deletion harbouring strain induces a loss of virulence on D. carota and K. daigremontiana (stems and leaves), confirming the importance of the TL-DNA for hairy root induction. re]19850711 rv]19851230 ac]19860114.

Secondary product formation by cultures of Beta vulgaris and Nicotiana rustica transformed with Agrobacterium rhizogenes

'Hairy root' cultures of Beta vulgaris and Nicotiana rustica were established after roots were induced on plants following infection with Agrobacterium rhizogenes. The transformed cultures of B. vulgaris and N. rustica synthesised their characteristic secondary products, the betalain pigments and nicotine alkaloids respectively, at levels comparable with those of in vivo roots from the same variety. Betalains were entirely retained inside the root tissue. In contrast, a proportion of the nicotine alkaloids was secreted into the medium. The potential of this type of 'in vitro' plant tissue culture for the production of valuable plant secondary products is identified and confirmed.

Identification of the genetic locus responsible for non-polar root induction by Agrobacterium rhizogenes 1855

Root proliferation can be induced by Agrobacterium rhizogenes on carrot discs both on the apical and basal surface (facing the root apex and base, respectively) or on the apical surface only, depending on the bacterial strain. This differential response on the two surfaces is denominated polarity. We correlate the polarity of some strains with the absence of an Ri plasmid genetic locus, present in non polar strains such as A. rhizogenes 1855, which bears sequence homology with the auxin genes of Ti plasmid T-DNA. We demonstrate that this locus is responsible for root induction on the basal surface since insertion of a transposon in this region of pRi1855 induces polarity in this strain.

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 Kalanchoë 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.