Metabolic factors capable of inducing Agrobacterium vir gene expression are present in rice (Oryza sativa L.)

Summary The effects of exudates and extracts from suspension cultures or various parts of rice (Oryza sativa L.) plants on induction of vir (virulence) gene expression in Agrobacterium tumefaciens were examined. Only leaf extracts from panicle-differentiating plants to flowering plants were able to strongly induce activation and expression of vir genes. This induction was similar to that observed with 2 M acetosyringone (AS), yet there was no synergy between AS and rice extracts. Responses to vir-inducing metabolites and signal molecules were different among various vir loci. These results demonstrate that one or more inducing factors for vir gene expression are also present in rice, but only in specific parts and developmental stages.     

The effect of additional virulence genes on transformation efficiency,transgene integration and expression in rice plants using the pGreen/pSoup dual binary vector system

We assessed the effect of four different virulence (vir) gene combinations on plant transformation efficiency and transgene behaviour in rice using the pGreen/pSoup dual binary vector system. Transformation experiments were conducted using a pGreen vector containing the bar and gusA expression units with, or without, the virG542, virGN54D, virGwt or the virG/B/C genes added to the backbone. Additonal vir gene(s) significantly altered plant transformation efficiency and the integration of vector backbone sequences. However, no differences in transgene copy number, percentage of expressing lines and expression levels could be detected. Addition of virGwt was the most beneficial, doubling the overall performance of the pGreen/pSoup vector system based on transformation frequency, absence of backbone sequence integration and expression of unselected transgenes. In 39 of the plant lines, the additional vir genes were integrated into the rice genome. The contribution of super dual binary pGreen/pSoup vectors to the development of efficient rice transformation systems and to the production of plants free of selectable marker genes are discussed.     

Studies on lambda virulent mutants

Summary The clearish plaque mutants virC which were isolated from true-virulent, virLvirCvirR (virLCR), do not complement CI mutants but CII, CIII and mutant (c ₄₂) for lysogenization. No complementation for lysogenization was observed between virCR and any CI, CII, CIII or y mutants. No lysogen was obtained when virC or virC carrying susN, susO or susP was infected to -sensitive sup ^- host. This was also true for virCR. Infection of ind ^- lysogen with virCRsusNO(P) or virCsusNO(P) results in marked prophage induction. Effect of virCRsusNO(P) on prophage induction is stronger than that of virCsusNO(P). These results suggest the existence of gene(s) for anti-repressor. When virCsusNO(P) or virCRsusNO(P) was infected to W3350 sup ^- at high m.o.i., lysogen in anti-immune state and that in weak-immune state was obtained, respetively. Wild type phage forms clear plaque on virCsusNO(P) lysogen with e.o.p. of one and no plaque on virCRsusNO(P) lysogen. T4rII can plate on both lysogens. This weak-immunity caused by virCRsusNO(P) prophage is different from CI immunity and not abolished by irradiation of ultraviolet light (hereafter this is referred to as the vir-immunity). Action of anti-immunity and vir-immunity are almost specific. Possible functional sites for anti-and vir-immunity substances are suggested to be virL and virR regions. A hypothesis was presented that the vir-immunity may caused by the overproduced anti-immunity substance coded from x region.This material has been published as an abstract in Jap. J. Genetics 45, 479 (1970).     

Molecular characterization of the virulence gene virA of the Agrobacterium tumefaciens octopine Ti plasmid

The virulence loci play an essential role in tumor formation by Agrobacterium tumefaciens. Induction of vir gene expression by plant signal molecules is solely dependent on the virulence loci virA and virG. This study focused on the virA locus of the octopine type Ti plasmid pTi15955. The nucleic acid sequence of a 5.7-kilobase fragment encompassing virA was determined. Genetic analysis of this region revealed that virA contains one open reading frame coding for a protein of 91 639 daltons. Immunodetection with antibodies raised against a 35-kDa VirA fusion protein produced in E. coli identified the VirA product in wild-type Agrobacterium cells. Moreover, it is shown that the VirA protein is located in the cytoplasmic membrane fraction of Agrobacterium. These data confirm the proposed regulatory function of VirA whereby VirA acts as a membrane sensor protein to identify plant signal molecules in the environment. The proposed sensory function of VirA strikingly resembles the function of the chemotaxis receptor proteins of E. coli.     

Molecular and genetic analysis of factors controlling host range in Agrobacterium tumefaciens

Summary We have investigated the factors which contribute to the host specificity of a tumor inducing plasmid of Agrobacterium, pTiAg162, which confers a narrow host range. Determinants both within the T-DNA and virulence regions contribute to host specificity. Within the T-DNA a defective cytokinin biosynthetic gene limits host range. Nucleotide sequence analysis revealed a large deletion in the 5 coding region of this gene when compared with the homologous gene from the wide host range tumor inducing plasmid, pTiA6. Introduction of the wide host range cytokinin biosynthesis gene into the T-DNA of the limited host range strain expanded the host range and suppressed the rooty morphology of tumors incited by the limited host range strain. Two genes from the virulence region of the wide host range plasmid, designated virA and virC, must also be introduced into the limited host range strain in order to restore a wide host range phenotype. The wide host range strain is avirulent on some cultivars of Vitis plants on which the limited host range strain induces tumors. This avirulence is apparently due to a hypersensitive response in which infected plant cells are killed at the site of inoculation. Mutations within the virC locus of the wide host range plasmid prevented the hypersensitive response and allowed the formation of tumors by the wide host range strain.     

Molecular characterization of the virulence gene virA of the Agrobacterium tumefaciens octopine Ti plasmid

The virulence loci play an essential role in tumor formation by Agrobacterium tumefaciens. Induction of vir gene expression by plant signal molecules is solely dependent on the virulence loci virA and virG. This study focused on the virA locus of the octopine type Ti plasmid pTi15955. The nucleic acid sequence of a 5.7-kilobase fragment encompassing virA was determined. Genetic analysis of this region revealed that virA contains one open reading frame coding for a protein of 91 639 daltons. Immunodetection with antibodies raised against a 35-kDa VirA fusion protein produced in E. coli identified by the VirA product in wild-type Agrobacterium cells. Moreover, it is shown that the VirA protein is located in the cytoplasmic membrane fraction of Agrobacterium. These data confirm the proposed regulatory function of VirA whereby VirA acts as a membrane sensor protein to identify plant signal molecules in the environment. The proposed sensory function of VirA strikingly resembles the function of the chemotaxis receptor proteins of E. coli.     

Analysis of conditions forAgrobacterium-mediated transformation of tobacco cells in suspension

We have developed anAgrobacterium-mediated transformation system, using tobacco cell suspensions, that permits evaluation of factors affecting transformation within seven days of co-cultivation. Tobacco cell transformation was determined by monitoring -glucuronidase (GUS) activity detected in plant cell extracts. The use of a chimeric gene construct, 35S-GUS/INT, containing a portable intron in theuidA reading frame, assured only plant-specific GUS expression. During the co-cultivation period, induction of the bacterialvir-region was monitored using a heterologous gene construct composed of avirB promoter fragment from pTiC58 fused to the chloramphenicol acetyltranferase (CAT) gene ofTn9. Tobacco cell transformants were confirmed by antibiotic selection of transformed plant cells and by X-Gluc staining. Maximum transformation was obtained when plant suspension cultures were growing rapidly which also was coincidental with elevated levels of bacterialvir-region expression. One week after co-cultivation, the transformed cultures exhibited a stable pattern of GUS activity which remained constant without antibiotic selection. The system was used to compare the virulence of a number ofAgrobacterium strains. GUS activity of plant cells co-cultivated with a strain containing a cointegrate plasmid was 3-fold higher than that of one with a binary configuration of the T-DNA. When the co-cultivatingAgrobacterium strain also carried the plasmid used to monitorvir induction, the frequency of transformation was reduced by as much, as 97%.     

Temperature-sensitive step in Ti plasmid vir-region induction and correlation with cytokinin secretion by Agrobacteria

Summary DNA transfer from Agrobacteria to plant cells requires activation of functions which are inactive under normal growth conditions. We studied two aspects with nopaline plasmid pGV3850: (1) conditions required for induction of a representative vir-region protein (virD2); for this we prepared antiserum against the protein and used the Western blot technique, and (2) correlation between vir-region induction and secretion of plant hormones. The results show that three factors are necessary and sufficient: the previously identified acetosyringone and acidic pH and, in addition, a carbon/energy source. Induction correlates with cytokinin secretion, suggesting that release of this hormone by the bacteria may play a role in tumor induction. No pronounced correlation is observed with release of indole-3-acetic acid. VirD2 induction and cytokinin secretion are temperature-dependent with similar optima. It is proposed that the thermosensitive step discovered decades ago with tumor induction in planta is in the activation of the vir functions.Abbreviations vir virulence gene - iP N⁶-(2-isopentenyl)adenine - iPA N⁶-(2-isopentenyl)adenosine - trans-Z trans-Zeatin - trans ZR, trans-Zeatinriboside - IAA indole-3-acetic acid - IPTG isopropyl--D-thiogalactoside     

A partially disarmed<Emphasis Type="Italic"> vir</Emphasis> helper plasmid,pKYRT1, in conjunction with 2,4-dichlorophenoxyactic acid promotes emergence of regenerable transgenic somatic embryos from immature cotyledons of soybean

Agrobacterium tumefaciens strain KYRT1 harboring the virulence helper plasmid pKYRT1 induces transgenic somatic embryos (SEs) at high frequency from infected immature soybean cotyledons. KYRT1 is derived from the highly oncogenic strain Chry5. However, pKYRT1 is not completely disarmed and still contains an entire T-right (T_R) and a portion of T-left (T_L). In this report, binary strains, each carrying fully disarmed vir helper plasmids including pKPSF2, which is a fully disarmed version of pKYRT1, were compared to strain KYRT1 for their ability to induce transgenic SEs on immature cotyledons of soybean. Six weeks following cocultivation, histochemical GUS assays of cultured explants indicated that all fully disarmed vir helper plasmids transferred their binary T-DNA, containing a GUS-intron gene, into soybean tissues. However, none of these transformed tissues developed SEs on medium with or without 2,4-dichlorophenoxyactic acid (2,4-D). On the other hand, immature cotyledons cocultivated with strain KYRT1 exhibited high induction of transgenic SEs, but only on medium supplemented with 2,4-D. Derivatives of strain Chry5 harboring other vir helper plasmids did not induce transgenic SEs under any conditions tested, thus suggesting that the chromosomal background of KYRT1 alone was not sufficient to promote somatic embryogenesis. PCR analysis indicated that 55% of transgenic embryogenic cultures and 29% of transgenic T₀ soybean plants derived by transformation using strain KYRT1 contained T_R from pKYRT1 in addition to the uidA gene from the binary construct. None of the transgenic tissues or T₀ plants contained T_L DNA. These results suggest that some function coded for by T_R of pKYRT1 influences somatic embryogenesis in conjunction with exposure of the plant tissues to 2,4-D. Since the co-transformation frequency of the undesirable T-DNA sequences from the vir helper plasmid was relatively low, the partially disarmed strain KYRT1 will likely be very useful for the production of normal transgenic plants of diverse soybean cultivars.Abbreviations 2,4-D 2,4-Dichlorophenoxyactic acid - GUS -Glucuronidase - hpt Hygromycin phosphotransferase gene - SE Somatic embryo - uidA -Glucuronidase gene     

The promoter of TL-DNA gene 5 controls the tissue-specific expression of chimaeric genes carried by a novel type of Agrobacterium binary vector

Summary A plant gene vector cassette to be used in combination with various Escherichia coli gene-cloning vectors was constructed. This cassette contains a replication and mobilization unit which allows it to be maintained and to be transferred back and forth between E. coli and Agrobacterium tumefaciens hosts provided these hosts contain plasmid RK2 replication and mobilization helper functions. The cassette also harbors a transferable DNA unit with plant selectable marker genes and cloning sites which can be combined with different bacterial replicons, thus facilitating the reisolation of transferred DNA from transformed plants in E. coli. The vector cassette contains two different promoters derived from the T-DNA-encoded genes 5 and nopaline synthase (NOS). By comparing the levels of expression of the marker enzymes linked to each of these promoter sequences, it was found that the gene 5 promoter is active in a tissue-specific fashion whereas this is not the case for the NOS promoter. This observation provides the first documented instance of a gene derived from a procaryotic host the expression of which is apparently regulated by plant growth factors.Abbreviations OCS octopine synthase (gene) - NOS nopaline synthase (gene) - NPT-II neomycin phosphotransferase (gene) of transposon Tn5 - vir Ti-plasmid region encoding virulence functions - Cb carbenicillin - Gm gentamycin - Km kanamycin - Cm chloramphenicol - Sm streptomycin - Sp spectinomycin - Rif rifampicin - Ery erythromycin - bom basis of mobilization - ori _r origin of conjugational plasmid transfer - Tra, Mob functions required for conjugational transfer of plasmids - BAP N⁶-benzylaminopurine - NAA -naphthaleneacetic acid - CTAB N-cetyl-N,N,N-trimethyl-ammonium bromide     

Lambda phage mutants insensitive to temperature-sensitive repressor

Summary The isolation of recombinant carrying virC mutation from newly isolated virulent carrying virL virC virR, (Horiuchi et al., 1969) was succeeded and the genetic character of virC mutation producing clear plaque was studied. virL virC shows weak-virulent character and produces clear plaque on CIts lysogen but not on wild type lysogen. virC shows avirulent character and no plaque is produced on these lysogen. The virC mutation is located very closely to and on the left side of the virR region (Fig. 1) which is presumed to be the operator of the right-side operon including O and P cistrons. The genetic characters of virL, virR and virC, were compared with v ₁, v ₂, v ₃ mutations of classical vir (Jacob and Wollman, 1954) and c ₁₇ mutation of another type of virulent (Da Silva and Jacob, 1968). The results indicate that virL, virC or virR mutation is similar to v ₂, v ₁ or v ₃ mutation, respectively, and an effect of virC mutation on producing virulent character was somewhat similar to that of c ₁₇ mutation and was stronger than that of virR mutation. The length of virR regions was suggested to be smaller than one tenth of that of the CI cistron.     

Genetic information of the bacteriocinogenic plasmid Clo DF13 involved in the inhibition of the multiplication of double stranded DNA phages

Summary The presence of plasmid Clo DF 13 in Escherichia coli cells alters the response of these cells to infection with the double stranded DNA phages P1 _vir , _vir or T1. The multiplication of these phages is reduced in Clo DF13 harbouring cells, resulting in an altered burstsize and plaque morphology. The degree of reduction is correlated to the amount of particular Clo DF13 gene product(s) in the cell. The genetic information of Clo DF13 involved in this plasmid-phage interaction could be located, using insertion and deletion mutants of Clo DF13 physical map. The genetic analysis of this region shows that at least two different genes, K and L, coding for polypeptides with a molecular weight of respectively 21 KD and 10.5 KD, are located in this region. The results presented, indicate that gene L and not gene K is involved in the interaction of Clo DF13 with the propagation of double stranded DNA phages.     

DNA transfer from Agrobacterium to Zea mays or Brassica by agroinfection is dependent on bacterial virulence functions

Summary DNA transfer fromAgrobacterium tumefaciens, a soil bacterium, to the non-host graminaceous monocotyledonous plantZea mays, was analysed using the recently developed technique of agroinfection. Agroinfection ofZ. mays with maize streak virus using strains ofA. tumefaciens carrying mutations in the pTiC58 virulence region showed an almost absolute dependence on the products of the bacterialvirC genes. In contrast, agroinfection of the control hostBrassica rapa with cauliflower mosaic virus was less dependent on thevirC gene products. In other respects, the basic mechanism of the plant-bacterium interaction was found to be similar. While intactvirA, B, D and G functions were absolutely necessary, mutants invirE were attenuated. Agroinfection of maize was effective in the absence of an exogenously suppliedvir gene inducer, and indeed woundedZ. mays tissues were found to produce substance(s) which induced the expression ofA. tumefaciens vir genes. These findings are discussed in the light of current knowledge about the function ofAgrobacterium vir genes.     

Genetic analysis of the signal-sensing region of the histidine protein kinase VirA of <Emphasis Type="Italic">Agrobacterium tumefaciens</Emphasis>

The membrane-bound sensor protein kinase VirA of Agrobacterium tumefaciens detects plant phenolic substances, which induce expression of vir genes that are essential for the formation of the crown gall tumor. VirA also responds to specific monosaccharides, which enhance vir expression. These sugars are sensed by the periplasmic domain of VirA that includes the region homologous to the chemoreceptor Trg, and the phenolics are thought to be detected by a part of the cytoplasmic linker domain, while the second transmembrane domain (TM2) is reported to be nonessential. To define regions of VirA that are essential for signal sensing, we introduced base-substitution and deletion mutations into coding regions that are conserved among the respective domains of VirA proteins from various Agrobacterium strains, and examined the effects of these mutations on vir induction and tumorigenicity. The results show that the Trg-homologous region in the periplasmic domain is not essential for the enhancement of vir gene expression by sugars. Most mutations in the TM2 domain also failed to influence enhancement by sugars and reduced the level of vir induction, but a mutation in the TM2 region adjacent to the cytoplasmic linker abolished induction of the vir genes. In the linker domain, sites essential for vir induction by phenolics were scattered over the entire region. We propose that a topological feature formed by the linker domain and at least part of the TM2 may be crucial for activation of a membrane-anchored VirA protein. Complementation analysis with two different VirA mutants suggested that intermolecular phosphorylation between VirA molecules occurs in vivo, and that two intact periplasmic regions in a VirA dimer are required for the enhancement of vir induction by sugars.     

Factors affecting the rate of T-DNA transfer from Agrobacterium tumefaciens to Nicotiana glauca plant cells

Different factors involved in the early steps of the T-DNA transfer process were studied by using a -glucuronidase gene (gusA) as a reporter in Nicotiana glauca leaf disc transformation experiments. The levels of transient expression of the gusA gene in leaf discs infected with several strains or vir mutants correlated well with their virulence phenotype, except for virC mutants. The rate of T-DNA transfer was shown to be stimulated in the case of non-oncogenic strains by the co-transfer of small amounts of oncogenic genes. It was found that the location of the T-DNA in the Agrobacterium genome affected the T-DNA transfer rate especially in virC mutants. The virC mutants transferred the gusA-containing T-DNA located on a binary vector more efficiently than the oncogenic T-DNA of the Ti plasmid. Although wild-type strains induced high levels of gusA expression early after infection, the gusA expression appeared to be lost late after infection in the infected leaf discs. In contrast, in leaf discs infected by virC mutants the level of gusA expression increased steadily in time. A model explaining these results is presented.     

Molecular Basis of ChvE Function in Sugar Binding,Sugar Utilization,and Virulence in Agrobacterium tumefaciens

ChvE is a chromosomally encoded protein in Agrobacterium tumefaciens that mediates a sugar-induced increase in virulence (vir) gene expression through the activities of the VirA/VirG two-component system and has also been suggested to be involved in sugar utilization. The ChvE protein has homology to several bacterial periplasmic sugar-binding proteins, such as the ribose-binding protein and the galactose/glucose-binding protein of Escherichia coli. In this study, we provide direct evidence that ChvE specifically binds the vir gene-inducing sugar d-glucose with high affinity. Furthermore, ChvE mutations resulting in altered vir gene expression phenotypes have been isolated and characterized. Three distinct categories of mutants have been identified. Strains expressing the first class are defective in both virulence and d-glucose utilization as a result of mutations to residues lining the sugar-binding cleft. Strains expressing a second class of mutants are not adversely affected in sugar binding but are defective in virulence, presumably due to impaired interactions with the sensor kinase VirA. A subset of this second class of mutants includes variants of ChvE that also result in defective sugar utilization. We propose that these mutations affect not only interactions with VirA but also interactions with a sugar transport system. Examination of a homology model of ChvE shows that the mutated residues associated with the latter two phenotypes lie in two overlapping solvent-exposed sites adjacent to the sugar-binding cleft where conformational changes associated with the binding of sugar might have a maximal effect on ChvE''s interactions with its distinct protein partners.Virulent strains of Agrobacterium tumefaciens contain the tumor-inducing (Ti) plasmid that carries virulence (vir) operons. Products of vir operons are involved in infecting wound sites of dicotyledonous plants and initiating tumor formation. The expression of vir genes in A. tumefaciens is activated by plant-released signals, namely, phenolic derivatives, acidic pH, and monosaccharides (for a review, see reference 6), via the combined activities of the periplasmic protein ChvE and the VirA/VirG two-component regulatory system. Upon perception of these plant signals, autophosphorylated VirA, a transmembrane histidine kinase, transfers a phosphoryl group to VirG, a response regulator, and then the phosphorylated VirG activates the expression of vir genes by binding vir boxes in their promoters (8, 19, 24, 31, 52).Perception and transduction of the sugar signals is crucial to the virulence of A. tumefaciens: strains lacking ChvE, a chromosomally encoded putative sugar-binding protein, are significantly less virulent than wild-type strains (17, 18). Previous studies have shown that, in fact, sugar signaling is neither sufficient for nor absolutely required for vir gene expression. Rather, sugars vastly increase both the sensitivity of VirA to phenol derivatives, such as acetosyringone (AS), and the maximal levels of vir gene expression observed at saturating levels of such compounds (for a review, see reference 26). The periplasmic domain of VirA is required for transduction of the sugar and pH signals (7, 8, 16, 41), whereas the so-called “linker” domain, located in the cytoplasm between the second transmembrane domain and the kinase domain, is required for perception and transduction of the phenolic signals (8, 46, 47).A working model for the ChvE/sugar/VirA signaling pathway suggests that monosaccharide-bound ChvE interacts with the periplasmic domain of VirA to relieve periplasmic repression, resulting in maximal sensitivity of VirA to phenolic signals (7, 11, 32, 41). However, limited evidence has been presented to reveal how ChvE recognizes monosaccharides and how it interacts with the periplasmic domain of VirA. Shimoda et al. (41) identified a mutant chvE allele [chvE(T211M)] that is able to suppress a sugar-insensitive virA allele [virA(E210V)], thereby restoring the sugar-sensing ability. The suppressing effect of chvE(T211M) was then proposed to be the result of the specific restoration of the capacity of VirA^E210V to bind ChvE^T211M. However, ChvE^T211M also activated wild-type VirA in the absence of sugars (32), suggesting that this mutant may not be a site-specific suppressor of VirA^E210V. Based on a homology model of ChvE, a recent study (16) does predict, though, that the residue T211 is located on the surface of the ChvE protein, consistent with the model that T211 is in a position to interact with the periplasmic domain of VirA.Based on sequence similarity, ChvE is a member of the periplasmic sugar-binding protein (PSBP) family. The structures of some PSBPs, including two ChvE homologues in Escherichia coli, ribose-binding protein (RBP) and glucose/galactose-binding protein (GBP), have been solved. The family of PSBPs shares very similar structural features, and each of them contains two similar but distinct globular domains connected by a flexible hinge (38). A sugar-binding site is located at the cleft between the two domains. PSBPs play an important role in active sugar transport, and some of them also serve as an initial receptor for sugar chemotaxis (45). A wealth of evidence has demonstrated that some specialized regions located on the surfaces of PSBPs are important for transport and chemotactic functions. In the case of RBP, four distinct regions spanning the N-terminal and C-terminal domains are involved in interaction with its permease (a transport partner), its chemotransducer (a chemotactic partner), or both (5, 15). In GBP, one residue was identified as being specifically involved in chemotaxis but not transport (36, 49). For maltose-binding protein (MBP), which is also a member of the PSBP family, two well-defined regions located on each domain of the protein are involved in interaction with its chemotransducer (54). These regions partially overlap with the regions involved in interaction with its permease (25, 54). Structural analysis indicates that both domains of MBP have direct interactions with its transport partners (35).ChvE also appears to be a highly versatile protein: not only does it play an important role in virulence, but as in the case of the PSPBs described above, it has been indicated to be a primary receptor for transport of and chemotaxis toward some sugars (7). This raises important biological/biochemical questions. How can ChvE interact with three presumably different periplasmic components of systems that are respectively involved in virulence, sugar utilization, and chemotaxis? How are the interactions of ChvE with these periplasmic components structurally segregated: do the interactions occur on the same or different regions of ChvE? To address these issues, we employed genetic and biophysical approaches to identify the residues of ChvE involved in sugar utilization versus the residues involved in virulence. The residues of both groups were mapped onto a homology model of ChvE based on a high-resolution crystal structure of E. coli GBP (PDB ID, 2ipn). Our results identify an extended surface spanning both the N-terminal and C-terminal domains of ChvE that is essential for interacting with VirA and that partially overlaps the surface responsible for the interaction of ChvE with a putative ABC sugar transport protein.     

O-methyltransferase(s)-suppressed plants produce lower amounts of phenolic vir inducers and are less susceptible to Agrobacterium tumefaciens infection

The first step of Agrobacterium tumefaciens/plant interaction corresponds to the activation of a transduction pathway of the bacterium by plant exudate. Phenolic compounds rapidly secreted by wounded plant cells induce the expression of bacterial virulence (vir) genes; however, little is known about their biosynthesis in plant. Here we show that inoculation of an Agrobacterium tumefaciens virulent strain on orthodiphenol-O-methyltransferases-suppressed tobacco plants leads to significantly smaller tumors compared to control plants. These transgenic plants are inhibited for caffeic acid O-methyltransferase class I or II (OMT; EC 2.1.1.6) and/or caffeoyl-coenzyme A O-methyltransferase (CCoAOMT; EC 2.1.1.104) that are involved in monolignol biosynthesis. The significant decrease of tumor size could be suppressed by the pre-activation of bacterial virulence, before inoculation, using acetosyringone a known vir inducer. Total soluble phenolic amounts and cell wall composition analyzed by FT-IR analysis did not show significant differences between transgenic and control plants. The potential of phenolic extracts from control and OMT-suppressed plants to induce virulence was evaluated using an Agrobacterium tumefaciens reporter strain carrying a vir::LacZ gene fusion plasmid. Lower vir-inducing activities were recorded for plants that show inhibition to caffeic acid O-methyltransferase activity. HPLC analysis confirmed that the levels of several phenolic compounds were differently affected by wounding and/or by bacterial inoculation. Statistical correlations were established between tumor sizes, vir-inducing activities, O-methyltransferases proteins accumulations and the levels of various soluble phenolic compounds such as acetosyringone. These results demonstrate the role of the O-methyltransferases of the phenylpropanoid pathway in the early production of soluble Agrobacterium tumefaciens vir inducers.     

Lambda phage mutants insensitive to temperature-sensitive repressor

Summary Weak-virulent mutants of temperate coli-phage were isolated which can grow on the CIts lysogen producing a temperature-sensitive repressor but which cannot grow on the wild type lysogen producing a normal repressor.Genetic analysis on the mutants shows that their weak-virulence is attributable to two mutations, one (virL) in the region between sus N₂₁₃ and c ₄₇ and the other (virR) in the region between c ₁ and sus O₈. Both mutations are located within the region of non-homology between and imm ⁴³⁴ phages.True virulent mutants which can grow on the wild type lysogen can be obtained easily from the weak-virulent mutant by an additional mutation, virC in a region very close to virR. The virulent mutants obtained are similar to the classical vir mutant (Jacob and Wollman, 1954). The virL and virR mutations are probably operator mutations which render the genome insensitive to the repressor.This work was reported at the XII th International Congress of Genetics, held in Tokyo, on August 23, 1968.     

Isolation and characterization of a temperature-sensitive amber suppressor mutant of Escherichia coli K12

Summary By mutagenizing an E. coli strain carrying an amber suppressor supD ^- (or su _I ⁺), we isolated a mutant whose amber suppressor activity was now temperature-sensitive. The mutant suppressor gene was named sup-126, which was found to be cotransduced with the his gene by phage P1vir at the frequency of ca. 20%. At 30° C it suppresses many amber mutations of E. coli, phage T4, and phage . At 42° C, however, it can suppress none of over 30 amber mutations tested so far. The sup-126 mutation is unambiguous and stable enough to be useful for making production of an amber protein temperature-sensitive.