Elaboration of cellulose fibrils by Agrobacterium tumefaciens during attachment to carrot cells.

The attachment of virulent strains of Agrobacterium tumefaciens to plant cells is the first step in the bacterial induction of tumors. Binding of A. tumefaciens to carrot tissue culture cells occurred as a two-step process. The initial step was the attachment of the bacteria to the plant cell wall. Living plant cells were not required. Bacterial attachment to heat-killed or glutaraldehyde-fixed carrot cells proceeded with only slightly altered kinetics and unaltered bacterial strain specificity. After the bacteria bound to the carrot cell surface, scanning electron microscopy showed that fibrils developed, surrounded the bacteria, and anchored them to the plant cell surface. These fibrils were synthesized by the bacteria and not by the plant cell since they were also made after the attachment of A. tumefaciens to dead carrot cells and since under some conditions the bacteria synthesized fibrils in the absence of plant cells. Calcofluor staining, acid hydrolysis, enzymatic digestion studies, and infrared spectroscopy showed that the fibrils were composed of cellulose. The formation of these cellulose fibrils occurred during the attachment of virulent strains of A. tumefaciens to plant cells in vitro. The fibrils anchored the bacteria to the plant cell surface and entrapped additional bacteria. The multiplication of entrapped and attached bacteria resulted in the formation of large clusters of bacteria held close to the plant cell wall and plasma membrane by cellulose fibrils. This high concentration of bacteria may facilitate transfer of Ti plasmid deoxyribonucleic acid to the plant cell resulting in the formation of tumors.     

Tumor Induction by Agrobacterium tumefaciens: Specific Transfer of Bacterial Deoxyribonucleic Acid to Plant Tissue

When Agrobacterium tumefaciens cells grown in the presence of tritiated thymidine to label specifically the bacterial deoxyribonucleic acid (DNA) are incubated with carrot root tissue for short periods of time, an appreciable fraction of the label becomes firmly associated with the root tissue. Such association is not observed in identical experiments when A. tumefaciens cell ribonucleic acid or protein are labeled. The extent of the retention of thymidine-derived label from bacterial cells by the root tissue in experiments with A. radiobacter and poorly tumorigenic strains of A. tumefaciens is significantly less than that afforded by tumorigenic strains of A. tumefaciens but greater than the level afforded by Escherichia coli. Transfer of DNA-specific label from A. tumefaciens to carrot root discs is not enhanced by treatments designed to provoke lysis of the bacterial cells, nor is it decreased by addition of deoxyribonuclease or excess unlabeled thymidine to the incubation medium. Bacterial cell-to-plant cell contact is necessary for transfer. Unlabeled A. radiobacter cells decrease in a competitive manner transfer of label when mixed with labeled A. tumefaciens cells. These findings suggest that transfer of DNA from A. tumefaciens to plant tissue after binding of the bacterial cells to specific plant tissue site(s) is a necessary feature of the mechanism by which A. tumefaciens provokes tumors in plants and provides an experimental technique of potentially great value in study of the early steps in the process of tumor induction by A. tumefaciens.     

The in vitro effects of opines and other compounds on DNAs originating from bacteria, and from healthy and tumorous plant tissues

Purified total DNAs were isolated from oncogenic or nononcogenic Agrobacterium tumefaciens cells as well as from normal and crown gall tissues. Opines (octopine, nopaline, lysopine), plant hormone (auxin IAA) and some carcinogenic compounds were used in order to correlate their effects on in vitro strand separation and synthesis of DNAs with in vivo tumorous cell multiplication. Octopine (or nopaline) induced chain opening of DNAs originating from octopine (or nopaline)-metabolizing bacteria and from same bacteria strain-induced tumorous cells. This phenomenon was measured by the increase in DNA hyperchromicity which is concentration dependent. The tested compounds stimulated the in vitro synthesis of the same DNAs. Under the same conditions, in vitro strand separation and synthesis of healthy plant DNA was not (or only slightly) enhanced, except in the case of particular hormone-connected healthy cell DNA. IAA and carcinogens stimulated in vitro synthesis and induced in vitro strand separation (dose-dependent effect) of DNAs isolated from crown gall cells and inducing bacteria. Compared to healthy cell DNAs, these DNAs were thus susceptible to structurally very diversified molecules and in this way behave as do mammalian tissue DNAs. The opine and IAA actions observed here were specific for plant tissue DNA; cancerous human or animal tissue DNAs were insensitive. By their presence in the crown gall cells, opines possibly maintain destabilized areas (required for rapid growth and division) on tumor cell DNA. The cooperative actions of IAA and opines as well as small RNA and RNA fragments on gene activation, might explain the autonomy of plant tumor cells.     

Stimulation of Agrobacterium tumefaciens virulence with indole-3-acetic acid

The phytopathogen Agrobacterium tumefaciens incites the production of crown-gall on a wide range of dicotyledonous plants. Gall formation is dependent upon indole-3-acetic acid (IAA) and cytokinin production by the transformed plant cells. Upon incubation of Agrobacterium tumefaciens C58 with the plant hormone indole-3-acetic acid (IAA), bacterial virulence on cucumber plants was stimulated up to tenfold. Stimulation was maximized after exposure of bacteria to 50 or 100 μg ml^-1 IAA for 3 h. This was shown to be at the early log phase of bacterial growth.
The authors suggest that the excretion of IAA by the transformed plant cells stimulates bacterial virulence mechanism(s) encoded by the Ti plasmid, the chromosome, or both.     

Inhibition by Agrobacterium tumefaciens and Pseudomonas savastanoi of development of the hypersensitive response elicited by Pseudomonas syringae pv. phaseolicola.

Injection into tobacco leaves of biotype 1 Agrobacterium tumefaciens or of Pseudomonas savastanoi inhibited the development of a visible hypersensitive response to the subsequent injection at the same site of Pseudomonas syringae pv. phaseolicola. This interference with the hypersensitive response was not seen with injection of bacterial growth medium or Escherichia coli cells. Live A. tumefaciens cells were required for the inhibitory effect. Various mutants and strains of A. tumefaciens were examined to determine the genes involved. Known chromosomal mutations generally had no effect on the ability of A. tumefaciens to inhibit the hypersensitive response, except for chvB mutants which showed a reduced (but still significant) inhibition of the hypersensitive response. Ti plasmid genes appeared to be required for the inhibition of the hypersensitive response. The bacteria did not need to be virulent in order to inhibit the hypersensitive response. Deletion of the vir region from pTi had no effect on the inhibition. However, the T region of the Ti plasmid was required for inhibition. Studies of transposon mutants suggested that the tms but not tmr or ocs genes were required. These genes were not acting after transfer to plant cells since they were effective in strains lacking vir genes and thus unable to transfer DNA to plant cells. The results suggest that the expression of the tms genes in the bacteria may inhibit the development of the hypersensitive response by the plant. An examination of the genes required in P. savastanoi for the inhibition of the hypersensitive response suggested that bacterial production of auxin was also required for the inhibition of the hypersensitive response by these bacteria.     

Analysis of transfer of tumor-inducing plasmids from Agrobacterium tumefaciens to Petunia protoplasts.

Petunia protoplasts were infected with the virulent Agrobacterium tumefaciens strain A348 or the avirulent strain A136 (lacking a Ti plasmid). The infection process was stopped at various time intervals up to 24 h after inoculation, and the DNA from the plant cells was isolated. Southern blot analysis indicated that the DNA isolated from infected Petunia cells was not detectably contaminated by bacterial DNA from lysed Agrobacterium cells. Analysis of the DNA from the virulent infections suggested that the transferred DNA (T-DNA) may be transferred to the plant cell rapidly (within 2 to 6 h) after the bacteria bind to the cell wall and that the T-DNA may exist in a rearranged state which is stable over the time period investigated. Dot blot analysis indicated that regions far outside the T-DNA may be transferred to the plant cell. Most of the DNA transferred to the plant cell during the initial hours of infection is rapidly degraded.     

Role of bacterial cellulose fibrils in Agrobacterium tumefaciens infection.

During the attachment of Agrobacterium tumefaciens to carrot tissue culture cells, the bacteria synthesize cellulose fibrils. We examined the role of these cellulose fibrils in the attachment process by determining the properties of bacterial mutants unable to synthesize cellulose. Such cellulose-minus bacteria attached to the carrot cell surface, but, in contrast to the parent strain, with which larger clusters of bacteria were seen on the plant cell, cellulose-minus mutant bacteria were attached individually to the plant cell surface. The wild-type bacteria became surrounded by fibrils within 2 h after attachment. No fibrils were seen with the cellulose-minus mutants. Prolonged incubation of wild-type A. tumefaciens with carrot cells resulted in the formation of large aggregates of bacteria, bacterial fibrils, and carrot cells. No such aggregates were formed after the incubation of carrot cells with cellulose-minus A. tumefaciens. The absence of cellulose fibrils also caused an alteration in the kinetics of bacterial attachment to carrot cells. Cellulose synthesis was not required for bacterial virulence; the cellulose-minus mutants were all virulent. However, the ability of the parent bacterial strain to produce tumors was unaffected by washing the inoculation site with water, whereas the ability of the cellulose-minus mutants to form tumors was much reduced by washing the inoculation site with water. Thus, a major role of the cellulose fibrils synthesized by A. tumefaciens appears to be anchoring the bacteria to the host cells, thereby aiding the production of tumors.     

Bacterial nucleic acid synthesis in plants following bacterial contact

Summary After plants have been in contact with a suspension of bacteria one finds in plant cells self replicating bacterial DNA and replicating molecules formed of bacterial DNA combined with plant DNA. Moreover newly synthesized bacterial RNA appears in the host cell. These phenomena seem to be due to a transfer of bacterial DNA into plant cells.     

Interactions and DNA transfer between Agrobacterium tumefaciens, the Ti-plasmid and the plant host.

Agrobacterium tumefaciens is a gram-negative bacterium with the unique capacity to induce neoplasmic transformations in dicotyledonous plants. Recently, both the mechanism and the biological significance of this transformation have been elucidated. Agrobacterium tumefaciens strains contain a large extrachromosomal DNA plasmid (the Ti-plasmid). This Ti-plasmid is responsible for the oncogenic properties of Agrobacterium strains. A particular segment of the Ti-plasmid, containing information determining the tumorous growth pattern and the synthesis of so-called 'opines', e.g. octopine (N-alpha-(D-1-carboxyethyl)-L-arginine) and nopaline (N-alpha-(1,3-dicarboxypropyl)-L-argine), is transferred and stably maintained and expressed in the transformed plant cells. This phenomenon can be understood as a 'genetic colonization' of the plant cells by bacterial plasmid DNA so that the transformed plant cells will produce and secrete into the medium amino acid derivatives (the opines) that Ti-plasmid carrying agrobacteria can selectively use as carbon and nitrogen sources.     

Agrobacterium rhizogenes GALLS protein contains domains for ATP binding, nuclear localization, and type IV secretion

Agrobacterium tumefaciens and Agrobacterium rhizogenes are closely related plant pathogens that cause different diseases, crown gall and hairy root. Both diseases result from transfer, integration, and expression of plasmid-encoded bacterial genes located on the transferred DNA (T-DNA) in the plant genome. Bacterial virulence (Vir) proteins necessary for infection are also translocated into plant cells. Transfer of single-stranded DNA (ssDNA) and Vir proteins requires a type IV secretion system, a protein complex spanning the bacterial envelope. A. tumefaciens translocates the ssDNA-binding protein VirE2 into plant cells, where it binds single-stranded T-DNA and helps target it to the nucleus. Although some strains of A. rhizogenes lack VirE2, they are pathogenic and transfer T-DNA efficiently. Instead, these bacteria express the GALLS protein, which is essential for their virulence. The GALLS protein can complement an A. tumefaciens virE2 mutant for tumor formation, indicating that GALLS can substitute for VirE2. Unlike VirE2, GALLS contains ATP-binding and helicase motifs similar to those in TraA, a strand transferase involved in conjugation. Both GALLS and VirE2 contain nuclear localization sequences and a C-terminal type IV secretion signal. Here we show that mutations in any of these domains abolished the ability of GALLS to substitute for VirE2.     

Attempts to Detect Deoxyribonucleic Acid from Agrobacterium tumefaciens and Bacteriophage PS8 in Crown Gall Tumors by Complementary Ribonucleic Acid/Deoxyribonucleic Acid-Filter Hybridization

Labeled ribonucleic acid (RNA) complementary to Agrobacterium tumefaciens DNA and PS8 bacteriophage DNA (cRNA) were used in a systematic study of the sensitivity of cRNA/deoxyribonucleic acid (DNA)-filter hybridization for detection of small amounts of phage or bacterial DNA immobilized on filters. A. tumefaciens cRNA of specific activity 10(6) to 2 x 10(6) counts per min per mug reacted to a significant extent when the DNA-filter contained 1% A. tumefaciens DNA in a salmon DNA background, but 0.1% A. tumefaciens DNA was not detectable. PS8 phage cRNA of the same specific activity reacted to a significant extent when the DNA-filter contained as little as 0.01% PS8 DNA in a salmon DNA background. Both kinds of cRNA were found to bind to tobacco crown gall tumor DNA-filters. Similar reaction was found with control normal callus DNA-filters but not with tobacco seedling DNA-filters. The "hybrids" formed by cRNA with normal callus and tumor DNA-filters had low thermal stability. Attempts to purify the tumor and normal callus DNA prior to immobilization on the filter resulted in elimination of this spurious binding. No evidence was found for bacterial or phage DNA in crown gall tumor DNA.     

On the question of integration of Agrobacterium tumefaciens deoxyribonucleic acid by tomato plants.

Treatment of tomato plants with Agrobacterium tumefaciens causes subsequently administered [3H]thymidine to be preferentially incorporated into a satellite deoxyribonucleic acid (DNA) whose buoyant density is between that of bacterial DNA (rho = 1.718 g/cm3) and plant main band DNA (rho = 1.692 g/cm3). Satellite DNA upon shearing or sonic treatment releases fragments of higher and lower buoyant density, as reported by earlier investigators. The satellite has no significant base sequence homology with A. tumefaciens DNA, for its rate of reassociation is not accelerated by the addition of high concentrations of the latter. Tomato DNA isolated from shoots or from leaf nuclei accelerates renaturation of labeled satellite DNA. We conclude that the intermediate density labeled DNA is a plant satellite and not the product of covalent joining of bacterial and plant DNA as suggested by earlier investigators.     

Agrobacterium tumefaciens can obtain sulphur from an opine that is synthesized by octopine synthase using S-methylmethionine as a substrate

Agrobacterium tumefaciens incites plant tumours that produce nutrients called opines, which are utilized by the bacteria during host colonization. Various opines provide sources of carbon, nitrogen and phosphorous, but virtually nothing was previously known about how A. tumefaciens acquires sulphur during colonization. Some strains encode an operon required for the catabolism of the opine octopine. This operon contains a gene, msh, that is predicted to direct the conversion of S-methylmethionine (SMM) and homocysteine (HCys) to two equivalents of methionine. Purified Msh carried out this reaction, suggesting that SMM could be an intermediate in opine catabolism. Purified octopine synthase (Ocs, normally expressed in plant tumours) utilized SMM and pyruvate to produce a novel opine, designated sulfonopine, whose catabolism by the bacteria would regenerate SMM. Sulfonopine was produced by tobacco and Arabidopsis when colonized by A. tumefaciens and was utilized as sole source of sulphur by A. tumefaciens. Purified Ocs also used 13 other proteogenic and non-proteogenic amino acids as substrates, including three that contain sulphur. Sulfonopine and 11 other opines were tested for induction of octopine catabolic operon and all were able to do so. This is the first study of the acquisition of sulphur, an essential element, by this pathogen.     

A model of Agrobacterium tumefaciens vacuum infiltration into harvested leaf tissue and subsequent in planta transgene transient expression

Agrobacterium-mediated gene transfer, or agroinfiltration, can be a highly efficient method for transforming and inducing transient transgene expression in plant tissue. The technique uses the innate DNA secretion pathway of Agrobacterium tumefaciens to vector a particular plasmid-encoded segment of DNA from the bacteria to plant cells. Vacuum is often applied to plant tissue submerged in a suspension of A. tumefaciens to improve agroinfiltration. However, the effects of vacuum application on agroinfiltration and in planta transient transgene expression have not been well quantified. Here we show that vacuum application and release act to drive A. tumefaciens suspension into the interior of leaf tissue. Moreover, the amount of suspension that enters leaves can be predicted based on the vacuum intensity and duration. Furthermore, we show that transient expression levels of an agroinfiltrated reporter gene vary in response to the amount of A. tumefaciens vacuum infiltrated into leaf tissue, suggesting that vacuum infiltration conditions can be tailored to achieve optimal transient transgene expression levels after agroinfiltration.     

Amino Acid Control over Deoxyribonucleic Acid Synthesis in Escherichia coli Infected With T-Even Bacteriophage

Starvation for a required amino acid of normal or RC(str)Escherichia coli infected with T-even phages arrests further synthesis of phage deoxyribonucleic acid (DNA). This amino acid control over phage DNA synthesis does not occur in RC(rel)E. coli mutants. Heat inactivation of a temperature-sensitive aminoacyl-transfer ribonucleic acid (RNA) synthetase similarly causes an arrest of phage DNA synthesis in infected cells of RC(str) phenotype but not in cells of RC(rel) phenotype. Inhibition of phage DNA synthesis in amino acid-starved RC(str) host cells can be reversed by addition of chloramphenicol to the culture. Thus, the general features of amino acid control over T-even phage DNA synthesis are entirely analogous to those known for amino acid control over net RNA synthesis of uninfected bacteria. This analogy shows that the bacterial rel locus controls a wider range of macromolecular syntheses than had been previously thought.     

The nucleoside triphosphate–ribonucleic acid nucleotidyltransferase (EC 2.7.7.6) of Agrobacterium tumefaciens (Smith and Townsend) Conn. Purification and properties of the enzyme from the tumorigenic strain B6806

The RNA nucleotidyltransferase (RNA polymerase) of the plant-tumorigenic bacterium Agrobacterium tumefaciens was purified. The method involves the disruption of the bacterial cells with glass beads in a Waring Blendor, treatment with DEAE-cellulose, fractionation with (NH(4))(2)SO(4), protamine sulphate precipitation, DEAE-cellulose column chromatography and either glycerol-gradient centrifugation or phosphocellulose chromatography. The subunit structure of the highly purified enzyme is similar to, although not identical with, the RNA nucleotidyltransferase of Escherichia coli. It can be described as beta', beta, chi(1) and alpha (mol.wts. 160000, 150000, 98000, and 41000+/-10% respectively). chi(1) is the temporary designation for a protein subunit, which might have the same functions as the sigma subunit in E. coli. The enzyme of A. tumefaciens is rifampicin-sensitive, has a temperature optimum in vitro of 41+/-1 degrees C and a pH optimum of 8.2+/-0.1. Mg(2+) and Mn(2+) are activators. The enzyme transcribes with different efficiencies artificial, viral, bacterial, plant and animal templates.     

Localization of the plasmid-encoded proteins TraI and MobA in eukaryotic cells

Conjugation mediates gene transfer not only between bacterial species but also from bacteria to yeast, plant, and animal cells. DNA transferred by conjugative plasmids from bacteria to eukaryotes must traverse subcellular membranes in the recipient before the transferred genes can be expressed and inherited. This process is most likely facilitated by putative DNA pilot proteins such as VirD2 of the Agrobacterium tumefaciens Ti plasmid. Here, we test this model as a general feature of trans-kingdom conjugation using the DNA-relaxases TraI and MobA of the IncP and IncQ groups. TraI localized unambiguously and uniformly to the nuclei of both yeast and human cells, whereas MobA displayed a range of subcellular localization patterns. The tendency to localize to the nucleus was not correlated with predicted nuclear localization sequence motifs in either protein, suggesting a lack of stringent requirements for nuclear localizing potential in pilot proteins mediating conjugative DNA transfer to eukaryotes. Further, our results indicate that nuclear localization ability may be more commonly associated with conjugative pilot proteins than previously recognized.     

Inhibition of lipopolysaccharide synthesis in Agrobacterium tumefaciens and Aeromonas salmonicida.

Lipopolysaccharide (LPS) synthesis was inhibited, new lipid A metabolites accumulated, and growth ceased, when the plant pathogen Agrobacterium tumefaciens and the fish pathogen Aeromonas salmonicida were treated with an antibacterial agent which specifically inhibits CTP:CMP-3-deoxy-manno-octulosonate cytidylyltransferase (CMP-KDO synthase). The new lipid A metabolites were purified by chromatography on DEAE-cellulose and chemically analysed. Metabolites isolated from both bacterial species contained glucosamine and phosphate in a 1:1 molar ratio, and 3-OH-C14:0 was the major fatty acid present (1 mol and 1.4 mol per mol glucosamine for A. tumefaciens and A. salmonicida, respectively). Inhibition of LPS synthesis by CMP-KDO synthase inhibitor had no effect on the initial kinetics of A. tumefaciens attachment to cultured carrot cells, but did inhibit cell aggregation normally induced by bacterial cellulose synthesis. Bacteria treated with inhibitor remained viable and able to synthesize protein at 15% the rate of control cells, indicating that the lack of cellulose-induced aggregation was not due to the inability of bacteria to make protein, but rather the inability to respond normally to the bacterial-plant cell interaction.