35S-β-glucuronidase gene blocks biological effects of cotransferred iaa genes

The iaaM and iaaH genes of Agrobacterium tumefaciens and Agrobacterium rhizogenes play an important role in crown gall and hairy root disease. The iaaM gene codes for tryptophan monooxygenase which converts tryptophan into indole-3-acetamide (IAM). IAM is converted into the auxin indole-3-acetic acid (IAA) by indoleacetamide hydrolase, encoded by the iaaH gene. In functional studies on the activity of the iaa genes of the TB region of the A. tumefaciens biotype III strain Tm4, the frequently used 35S--glucuronidase (35S-UidA or GUS) marker gene was found to inhibit IAA synthesis and root induction encoded by the TB iaa genes. To exert this inhibition, the 35S-UidA gene must be cotransferred with the iaaH gene. The 35S promoter alone is sufficient to cause the inhibitory effect.     

The Effect of Mutations in the T-DNA Encoded Auxin Pathway on the Endogenous Phytohormone Content in Cloned Nicotiana tabacum Crown Gall Tissues

We analyzed the endogenous auxin and cytokinin levels of clonedNicotiana tabacum SR 1-lines induced either by the wild-typeAgrobacterium tumefaciens C58 strain or by mutants affectedin the T-DNA-encoded IAA biosynthesis pathway. The wild-typeSR1-C58 line contained up to 20 times more IAA than a nontransformedSRI-callus line. The mutant lines affected in gene 1 (iaaM^–)or gene 2 (iaaH^–) contained intermediate levels of IAA. Analysis of the endogenous levels of indole-3-acetamide (IAM)in the nontransformed SR 1 callus line, the wild-type SR1-C58and the two mutant lines confirmed the T-DNA-induced IAA biosynthesispathway in the transformed tumor cells. Supplementing auxinto the mutant lines resulted in complete suppression of theshoot-forming ability, but no changes in the endogenous IAAlevels. There was no marked difference in the cytokinin level betweenthe nontransformed callus line and the wild type tumor line.The two mutant lines, however, showed a 20- to 30-fold highercytokinin level which was not affected by the addition of NAA.The T-DNA encoded hormone biosynthetic pathways are discussedin relation to pathways of the host plant. (Received July 29, 1986; Accepted February 14, 1987)     

The Pseudomonas savastanoi tryptophan-2-mono-oxygenase is biologically active in Nicotiana tabacum

It has been proposed that the eukaryotic T-DNA-encoded indole-3-acetic acid (IAA) biosynthesis genes of Agrobacterium tumefaciens and their prokaryotic counterpart in Pseudomonas savastanoi originated from common ancestor genes. This paper provides additional evidence for the functional similarity between the gene products. We have demonstrated that a chimeric gene consisting of the coding sequence of the P. savastanoi tryptophan-2-mono-oxygenase (iaaM gene) and a plant promoter encodes an active enzyme in Nicotiana tabacum. Transformants obtained with this chimeric gene grew as a callus on hormone-free media. No stably transformed plantlets could be isolated. The callus tissues contained extremely high levels of indole-3-acetamide and slightly elevated levels of IAA. Either indole-3-acetamide by itself has a low auxin activity or, alternatively, it is converted aspecifically and at low rates into IAA. The P. savastanoi tryptophan-2-mono-oxygenase activity in plants is also able to detoxify the amino-acid analogue 5-methyltryptophan. This property can be used for positive selection of transformed calli.Abbreviations BAP 6-benzylaminopurine - IAA indole-3-acetic acid - IAM indole-3-acetamide - NAA naphthalene-1-acetic acid - NPT-II neomycin phosphotransferase II - T-DNA transferred DNA     

Presence of indole-3-acetic acid in chloroplasts ofNicotiana tabacum andPinus sylvestris

The compartmentation and metabolism of indole-3-acetic acid (IAA) was examined in protoplasts derived from needles ofPinus sylvestris L., leaves of normal plants ofNicotiana tabacum L., leaves ofN. tabacum plants carrying the T-DNA gene 1 (rG1 plants) and leaves ofN. tabacum plants carrying the T-DNA gene 2 (rG2 plants) by using a rapid cell-fractionation method. In all tissues, 30%–40% of the IAA pool was located in the chloroplast, while the remainder was found in the cytosol. Quantitative analysis of indole-3-ethanol (IEt) showed that in bothPinus andNicotiana the IEt pool was located exclusively in the cytosol. The only plant that contained endogenous indoleacetamide (IAAm) was therG1-mutant ofN. tabacum, expressing theAgrobacterium tumefaciens T-DNA gene 1. Cellular fractionation of protoplasts from this transgenic plant showed that the entire IAAm pool was located in the cytosol. Feeding experiments utilizing [5-³H]tryptophan, [5-³H]IEt, [1′-¹⁴C] and [2′-¹⁴C]IAA demonstrated that the biosynthesis and catabolism of IAA occurred in the cytosol in bothPinus and in the wild type and the different mutants ofNicotiana. Furthermore, the biosynthesis of IAAm in therG1 plants was also shown to be localized in the cytosol.     

Petunia plants escape from negative selection against a transgene by silencing the foreign DNA via methylation

Summary TransgenicPetunia hybrida clones harbouring the T-DNA gene2 ofAgrobacterium tumefaciens were used to test a strategy for the trapping of plant transposable elements. In thePetunia line used, floral variegation is due to the presence of the non-autonomous transposable elementdTph1 at theAn1 locus. The gene2 product converts the auxin precursor indole-3-acetamide and its analogue 1-naphthalene acetamide into the active auxins indole-3-acetic acid and 1-naphthalene acetic acid. Plant cells that express gene2 can use a low concentration of the precursors as auxins and become sensitive to the toxicity of high concentrations of these compounds. By selecting protoplast-derived microcalli or seedlings able to grow on medium with high precursor concentrations, variant plants were obtained in which gene2 was no longer expressed. Southern analysis, using gene2-specific probes, revealed that in one variant the T-DNA was deleted. For 30 other variants no alteration in gene2 structure was observed, indicating that transposable element insertion was not responsible for the inactivation of gene2. Analysis with restriction enzymes allowing discrimination between methylated or non-methylated DNA sequences showed that the inactivated gene2 sequences were methylated. Addition of the in vivo methylation inhibitor 5-azacytidine to the medium led to reactivation of gene2 expression in some of the variants. These observations demonstrated that reversible DNA methylation was the main cause of silencing of gene2 in this system.     

Indole-3-lactic acid is a weak auxin analogue but not an anti-auxin

Indole-3-lactic acid (ILA) is a naturally occurring indole derivative, preferably detected in soil bacteria and fungi and only in low amounts in plants. T-DNA gene 5 of Agrobacterium tumefaciens was found to be involved in the synthesis of ILA in transformed plant tissues, but the physiologic relevance for ILA production in plants is unclear. The related molecular structure of ILA to the natural auxin indole-3-acetic acid (IAA) makes ILA a good candidate for an auxin analogue. We examined the possible auxin activity of ILA on elongation, proliferation, and differentiation in Pisum sativum L. Results presented in this paper indicate that there are no or only weak effects of ILA toward the activity of auxins when used in the physiologic concentration range. Furthermore, no antagonistic effects of ILA were found. Biochemical analysis using the equilibrium dialysis binding system resulted in no high affinity ILA binding to an enriched protein fraction containing auxin-binding protein (ABP₄₄), whereas 1-naphthaleneacetic acid exhibited high affinity auxin binding.Abbreviations IAA indoleacetic acid - ILA indole-3-lactic acid - T-DNA transferred DNA - ABP auxin-binding protein - NAA naphthaleneacetic acid - MS Murashige and Skoog - MES 2-(N-morpholino)ethanesulfonic acid - BAP 6-benzylaminopurine     

The Initiation of Auxin Autonomy in Tissue from Tobacco Plants Carrying the Auxin Biosynthesizing Genes from the T-DNA of Agrobacterium tumefaciens

Tobacco (Nicotiana tabacum cv Havana 425) plants containing the indole-3-acetic acid biosynthesizing genes (1 and 2) from the T-DNA of Agrobacterium tumefaciens strain T37-ADH₂ (mutated at the cytokinin biosynthesis gene 4) were used to study the physiological basis of the suppression and reinitiation of the auxin autonomous phenotype. The plants, though normal in appearance and cross-fertile with nontransformed, wild type tobacco, are shown to contain multiple copies of genes 1 and 2. Plants carrying these genes respond to inoculation by Agrobacterium strains mutated at genes 1 and 2 in a virulent fashion. Despite the presence and potential in planta activity of these genes, pith explants from such plants require auxin or tryptophan for growth in vitro, as does wild type tobacco. In both cases the indole-3-acetic acid levels increase rapidly in pith explants cultured on tryptophan-containing medium. However, only the tissues containing genes 1 and 2 grow subsequently on auxin-free medium and accumulate indole-3-acetic acid to levels that support growth. The capacity of such tissues to utilize naphthalene acetamide as an auxin suggests that gene 2 is rapidly activated during the reinitiation process.     

T-DNA-encoded auxin formation in crown-gall cells

The T-region of Ti plasmids expresses two genes (No. 1 and 2) in crown-gall cells which are essential for auxin effects. It has been shown that gene 2 (=IaaH) codes for an amidohydrolase which converts indole-3-acetamide into indole-3-acetic acid and which is functional in bacteria and in crown-gall cells (Schröder et al. (1984), Eur. J. Biochem. 138, 387–391). In this report we describe a quantitative assay for the enzyme and its application to analyze the properties of the enzyme as expressed in plant cells and in Escherichia coli. The enzyme requires no cofactors, and the temperature optimum (30–37°C), pH optimum (8.5–9.5), and K_m (about 1 M) were very similar in both systems. Besides indole-3-acetamide, the enzyme also hydrolyzed indole-3-acetonitrile, esters of indole-3-acetic acid with glucose and myo-inositol, a-naphthaleneacetamide, and phenylacetamide, indicating that it may have a general function in converting substances of low auxin activity into those with high auxin activity. The results are discussed in relation to the possible function of T-DNA gene 1 which cooperates with gene 2 in evoking auxin effects in crown-gall cells.Abbreviations HPLC high-pressure liquid chromatography - T-DNA transferred DNA     

Transgenic Tobacco plants with T-DNA Phytohormone synthesis genes

Agrobacterium tumefaciens binary vectors carrying kanamycin resistance gene and either C58 T-DNA gene 4 for cytokinin synthesis or genes 1 and 2 for auxin synthesis were constructed and used for transformation of a short-day tobacco Maryland Mammoth. Kanamycin resistant plants were regenerated from a small fraction of transformed tissue and the presence of T-DNA in their genome was verified by Southern blotting. The level of endogenous cytokinin in plants transgenic for gene 4 and the level of endogenous IAA in those transgenic for genes 1 and 2 increased by more than 100 %. A number of morphological characteristics distinguish them from untransformed controls.     

Chromosomal localization of foreign genes in Petunia hybrida

Summary A F1 hybrid of Petunia hybrida, heterozygous for at least one marker on each of the seven chromosomes, was transformed with a modified strain of Agrobacterium tumefaciens in which the phytohormone biosynthetic genes in the transferred DNA (T-DNA) were replaced with a NOS/NPTII/NOS chimeric gene and a wildtype nopaline synthase (NOS) gene. The chimeric gene, which confers kanamycin resistance, was used as selectable marker during the transformation process and the NOS gene was used as a scorable marker in the genetic studies. After plants had been regenerated from the transformed tissues, the transgenic plants that expressed both of these markers were backcrossed to the parental lines. The offspring were examined for the segregation of the NOS gene and the Petunia markers. Genetic mapping was thus accomplished in a single generation.By Southern hybridization analysis we confirmed the presence of the expected T-DNA fragments in the transformed plants. Four out of the six plants presented here, had just one monomeric T-DNA insertion. The sizes of the plant/T-DNA junction fragments suggest that the integration occurred in different sites of the Petunia genome. One transformant gave a more complicated hybridization pattern and possibly has two T-DNA inserts. Another transgenic plant was earlier reported (Fraley et al. 1985) to have two, possibly tandemly repeated T-DNAs.Data is presented on the genetic localization of the T-DNA inserts in six independently obtained transgenic plants. The T-DNA inserts in three plants were mapped to chromosome I. However, the distances between the NOS gene and the marker gene on this chromosome were significantly different. In another transgenic plant the NOS gene was coinherited with the marker on chromosome IV. Two other transgenic plants have the T-DNA insert on chromosome III. A three point cross enabled us to determine that both plants have the NOS gene distally located from the peroxidaseA (prxA) marker and both plants showed about 18% recombination. However, Southern hybridization analysis shows that the sizes of the plant/T-DNA junction fragments in these transgenic plants are different, thus suggesting that the integrations occurred in different sites.     

Genetic analysis of the individual T-DNA genes of Agrobacterium tumefaciens; further evidence that two genes are involved in indole-3-acetic acid synthesis

Summary The T-DNA genes of Ti plasmids of Agrobacterium tumefaciens can induce tumorous growth on a wide range of dicotyledonous plants. We subcloned the individual onc genes of the pTiC58 T-DNA and reintroduced them in the T-region of the Ti plasmid gene vector pGV3850 (from which the onc genes had been removed (Zambryski et al. 1983)). These experiments were designed to analyze the contribution of each onc gene to the development of a tumor and have fulfilled two purposes. First, it was found that only the strains carrying gene 4 produced tumors without the aid of other T-DNA genes; in cell culture these tumors sprout shoots. Second, the shoot-forming phenotype of tumors induced by agrobacteria carrying Ti plasmids defective in either gene 1 or gene 2 can be restored to wildtype phenotype by simple coinfection with Agrobacterium strains whose Ti plasmids contain respectively only gene 2, or only gene 1 in their T-region. A parallel experiment demonstrated that the combined action of genes 1 and 2 is sufficient to induce tumor formation on tobacco plantlets.The external addition of -naphthalene acetic acid (NAA) restores to wild-type the phenotype of tumors induced by mutants in gene 1 or in gene 2. However, -naphthalene acetamide can only restore to wild-type the phenotype of mutants in gene 1. These data indicate that the product of the T-DNA gene 2 participates in the conversion of -naphthalene acetamide to a biologically active auxin, presumably NAA, and suggest that gene 1 codes for an enzyme involved in the synthesis of an indole-3-acetyl derivative.     

Free and Conjugated Indoleacetic Acid (IAA) Contents in Transgenic Tobacco Plants Expressing the iaaM and iaaH IAA Biosynthesis Genes from Agrobacterium tumefaciens

The Agrobacterium tumefaciens T-DNA gene iaaM was introduced by leaf-disc transformation into transgenic tobacco (Nicotiana tabacum) plants expressing the iaaH gene. Regenerated calli were screened for the presence of indole-3-acetamide (IAM), by gas chromatography-multiple ion monitoring-mass spectrometry, and IAM-containing calli were further analyzed for free and conjugated indoleacetic acid (IAA). It was found that transgenic calli on average contained twice as much free IAA and three times more conjugated IAA than calli from wild-type plants. About 40% of the transformed calli could be regenerated to plants. The distribution of free and conjugated IAA was measured in transformed plants with a normal phenotype and compared with equivalent wild-type plants. The IAA content of transgenic plants was only slightly increased, whereas IAA-conjugate levels were enhanced significantly. These data suggest that conjugation of IAA may serve as a regulatory mechanism, contributing to maintenance of steady-state IAA pool sizes during tobacco growth and development.     

Identification of T-DNA tagged Arabidopsis mutants that are resistant to transformation by Agrobacterium

We have identified T-DNA tagged Arabidopsis mutants that are resistant to transformation by Agrobacterium tumefaciens (rat mutants). These mutants are highly recalcitrant to the induction of both crown gall tumors and phosphinothricin-resistant calli. The results of transient GUS (β-glucuronidase) assays suggest that some of these mutants are blocked at an early step in the Agrobacterium-mediated transformation process, whereas others are blocked at a step subsequent to translocation of T-DNA into the nucleus. Attachment of Agrobacterium to roots of the mutants rat1 and rat3 was decreased under various incubation conditions. In most mutants, the transformation-deficient phenotype co-segregated with the kanamycin resistance encoded by the mutagenizing T-DNA. In crosses with susceptible wild-type plants, the resistance phenotype of many of these mutants segregated either as a semi-dominant or dominant trait. Received: 26 October 1998 / Accepted: 8 January 1999     

Transgenic tomato (Lycopersicon esculentum L.) transformed with a binary vector in Agrobacterium rhizogenes: Non-chimeric origin of callus clone and low copy numbers of integrated vector T-DNA

Summary We transformed tomato (Lycopersicon esculentum L.) by using Agrobacterium rhizogenes containing two independent plasmids: the wild-type Ri-plasmid, and the vector plasmid, pARC8. The T-DNA of the vector plasmid contained a marker gene (Nos/Kan) encoding neomycin phosphotransferase which conferred resistance to kanamycin in transformed plant cells. Transgenic plants (R ₀) with normal phenotype were regenerated from transformed organogenic calli by the punctured cotyledon transformation method. Southern blot analysis of the DNA from these transgenic plants showed that one or two copies of the vector plasmid T-DNA, but none of the Ri-plamid T-DNA, were integrated into the plant genome. Different transgenic plants derived from the same callus clone showed an identical DNA banding pattern, indicating the non-chimeric origin of these plants. We also transformed tomato by using A. tumefaciens strain LBA4404 containing a disarmed Ti-plasmid (pAL4404), and a vector plasmid (pARC8). Transgenic plants derived via A. tumefaciens transformation, like those via A. rhizogenes, contained one to two copies of the integrated vector T-DNA. The kanamycin resistance trait in the progeny (R ₁) of most transgenic plants segregated at a ratio of 3:1, suggesting that the vector T-DNAs were integrated at a single site on a tomato chromosome. In some cases, the expression of the marker gene (Nos/Kan) seemed to be suppressed or lost in the progeny.     

T-DNA gene 5 of Agrobacterium modulates auxin response by autoregulated synthesis of a growth hormone antagonist in plants.

Oncogenes carried by the transferred DNA (T-DNA) of Agrobacterium Ti plasmids encode the synthesis of plant growth factors, auxin and cytokinin, and induce tumour development in plants. Other T-DNA genes regulate the tumorous growth in ways that are not yet understood. To determine the function of T-DNA gene 5, its coding region was expressed in Escherichia coli. Synthesis of the gene 5 encoded protein (26 kDa) correlated with a 28-fold increase in conversion of tryptophan to indole-3-lactate (ILA), an auxin analogue. Expression of chimeric gene 5 constructs in transgenic tobacco resulted in overproduction of ILA that enhanced shoot formation in undifferentiated tissues and increased the tolerance of germinating seedlings to the inhibitory effect of externally supplied auxin. Promoter analysis of gene 5 in plants revealed that its expression was inducible by auxin and confined to the vascular phloem cells. cis-regulatory elements required for auxin regulation and phloem specific expression of gene 5 were mapped to a 90 bp promoter region that carried DNA sequence motifs common to several auxin induced plant promoters, as well as a binding site for a nuclear factor, Ax-1. ILA was found to inhibit the auxin induction of the gene 5 promoter and to compete with indole-3-acetic acid (IAA) for in vitro binding to purified cellular auxin binding proteins. It is suggested therefore that ILA autoregulates its own synthesis and thereby modulates a number of auxin responses in plants.     

Crown gall disease and hairy root disease : a sledgehammer and a tackhammer

The neoplastic diseases crown gall and hairy root are incited by the phytopathogenic bacteria Agrobacterium tumefaciens and Agrobacterium rhizogenes, respectively. Although the molecular mechanism of T-DNA transfer to the plant most likely is the same for both species, the physiological basis of tumorigenesis is fundamentally different. Crown gall tumors result from the over-production of the phytohormones auxin and cytokinin specified by A. tumefaciens T-DNA genes. Although the T-DNA of some Riplasmids of A. rhizogenes contains auxin biosynthetic genes, these loci are not always necessary for hairy root formation. Recent experiments suggest that hairy root tumors result from the increased sensitivity of transformed cells to endogenous auxin levels. An understanding of hairy root tumorigenesis will likely result in an increased knowledge of plant developmental processes.     

IAA synthesis and root induction with iaa genes under heat shock promoter control

We have devised a heat shock-inducible indole-3-acetic acid (IAA) synthesis system for plant cells, which is based on the iaa genes of the Agrobacterium tumefaciens T-DNA and the heat shock promoter hsp70 of Drosophila melanogaster.Two DNA constructs were tested: one contains the iaaM gene linked to the hsp70 promoter (hsp 70-iaaM) and encodes the production of indoleacetamide (IAM), the other contains hsp 70-iaaM and the wild-type iaaH gene which codes for the conversion of IAM into IAA (hsp 70-iaaM/iaaH). Heat shock-controlled IAM and IAA synthesis was tested on two levels: biochemically by measuring IAM and IAA levels in Kalanchoe stem segments infected with the two constructs, and morphologically by IAA-dependent root formation on Kalanchoe plants, on carrot discs and on tobacco leaf fragments. At both levels the responses were found to be controlled by the heat shock promoter. IAM levels of segments infected with hsp 70-iaaM increased 6-fold upon heat shock induction to 240 pmol IAM per stem segment. The accumulation of IAA in segments infected with hsp 70-iaaM/iaaH and heat-shocked was found to be more variable, possibly due to IAA transport and metabolism. Heat shock treatment of Kalanchoe plants and tobacco leaf fragments infected with hsp 70-iaaM/iaaH led to a strong increase in root formation. On carrot discs, heat shock-specific root induction was also demonstrated, but the responses differed between individual carrots.     

Agrobacterium T‐DNA‐encoded protein Atu6002 interferes with the host auxin response

Several genes in the Agrobacterium tumefaciens transferred (T)‐DNA encode proteins that are involved in developmental alterations, leading to the formation of tumours in infected plants. We investigated the role of the protein encoded by the Atu6002 gene, the function of which is completely unknown. Atu6002 expression occurs in Agrobacterium‐induced tumours, and is also activated on activation of plant cell division by growth hormones. Within the expressing plant cells, the Atu6002 protein is targeted to the plasma membrane. Interestingly, constitutive ectopic expression of Atu6002 in transgenic tobacco plants leads to a severe developmental phenotype characterized by stunted growth, shorter internodes, lanceolate leaves, increased branching and modified flower morphology. These Atu6002‐expressing plants also display impaired response to auxin. However, auxin cellular uptake and polar transport are not significantly inhibited in these plants, suggesting that Atu6002 interferes with auxin perception or signalling pathways.     

Endogenous indoles and the biosynthesis and metabolism of indole-3-acetic acid in cultures of Rhizobium phaseoli

Gas chromatography-mass spectrometric analyses of purified extracts from cultures of Rhizobium phaseoli wild-type strain 8002, grown in a non-tryptophan-supplemented liquid medium, demonstrated the presence of indole-3-acetic acid (IAA), indole-3-ethanol (IEt), indole-3-aldehyde and indole-3-methanol (IM). In metabolism studies with ³H-, ¹⁴C- and ²H-labelled substrates the bacterium was shown to convert tryptophan to IEt, IAA and IM; IEt to IAA and IM; and IAA to IM. Indole-3-acetamide (IAAm) could not be detected as either an endogenous constituent or a metabolite of [³H]tryptophan nor did cultures convert [¹⁴C]IAAm to IAA. Biosynthesis of IAA in R. phaseoli, thus, involves a different pathway from that operating in Pseudomonas savastanio and Agrobacterium tumefaciens-induced crown-gall tumours.Abbreviations IAA indole-3-acetic acid - IAld indole-3-aldehyde - IAAm indole-3-acetamide - IEt indole-3-ethanol - IM indole-3-methanol - HPLC-RC high-performance liquid chromatography-radio counting - GC-MS gas chromatography-mass spectrometry     

The NtAMI1 gene functions in cell division of tobacco BY-2 cells in the presence of indole-3-acetamide

Tobacco (Nicotiana tabacum) Bright Yellow-2 (BY-2) cells can be grown in medium containing indole-3-acetamide (IAM). Based on this finding, the NtAMI1 gene, whose product is functionally equivalent to the AtAMI1 gene of Arabidopsis thaliana and the aux2 gene of Agrobacterium rhizogenes, was isolated from BY-2 cells. Overexpression of the NtAMI1 gene allowed BY-2 cells to proliferate at lower concentrations of IAM, whereas suppression of the NtAMI1 gene by RNA interference (RNAi) caused severe growth inhibition in the medium containing IAM. These results suggest that IAM is incorporated into plant cells and converted to the auxin, indole-3-acetic acid, by NtAMI1.