Effects of a biocontrol bacterium on growth and defence of transgenic rice plants expressing a bacterial type-III effector

Expression of HpaG_xoo, a bacterial type-III effector protein, in transgenic plants induces disease resistance. Resistance also can be elicited by biocontrol bacteria. We studied effects of the biocontrolBacillus subtilis strain B-916 on the rice variety R109 and the thehpaG _xoo -expressing rice line HER1. Colonisation of roots by B-916 caused 12.5±1.3% and 0.5±0.05% increases, in contrast to controls, in root growth of R109 and HER1. Growth of R109 leaves and stems was increased by 0.5±0.05% but that of HER1 was inhibited. When B-916 colonisation was subsequent to plant inoculation withRhizoctonia solani, a pathogen that causes sheath blight, the disease was less severe than controls in both R109 and HER1; HER1, nevertheless, was more resistant, suggesting that B-916 and HpaG_xoo cooperate in inducing disease resistance. In R109 roots, theOsARF1 gene, which regulates plant growth, was expressed in consistence with growth promotion by B-916. Inversely, the depression ofOsARF1 expression was coincident with inhibition in growth of HER1 leaves and stems. In both plants, the expression ofOsEXP1, which encodes an expansin protein involved in plant growth, was concomitant with growth promotion in leaves and roots responding to B-916. We also studiedOsMAPK5b encoding a mitogen-activated protein kinase involved in multiple defence responses in rice. In response to B-916, early expression ofOsMAPK5b was coincident with R109 resistance to the disease, while HER1 expressed the gene similarly whether B-916 was present or not. Evidently, B916 and HER1 interact differently in rice growth and resistance. The combinative efffects should stimulate agricultural use and furthestudies on mechanisms that underlie the interaction.     

Phytodetoxification of TNT by transgenic plants expressing a bacterial nitroreductase.

There is major international concern over the wide-scale contamination of soil and associated ground water by persistent explosives residues. 2,4,6-Trinitrotoluene (TNT) is one of the most recalcitrant and toxic of all the military explosives. The lack of affordable and effective cleanup technologies for explosives contamination requires the development of better processes. Significant effort has recently been directed toward the use of plants to extract and detoxify TNT. To explore the possibility of overcoming the high phytotoxic effects of TNT, we expressed bacterial nitroreductase in tobacco plants. Nitroreductase catalyzes the reduction of TNT to hydroxyaminodinitrotoluene (HADNT), which is subsequently reduced to aminodinitrotoluene derivatives (ADNTs). Transgenic plants expressing nitroreductase show a striking increase in ability to tolerate, take up, and detoxify TNT. Our work suggests that expression of nitroreductase (NR) in plants suitable for phytoremediation could facilitate the effective cleanup of sites contaminated with high levels of explosives.     

Characterization of sunlight-grown transgenic rice plants expressing Arabidopsis phytochrome A

Transgenic rice (Oryza sativa) overexpressing Arabidopsis phytochrome A (phyA) was cultivated up to the T₃ generation in paddy to elucidate the role of phyA in determining the plant architecture and the productivity of sunlight-grown rice plants. PhyA is light-labile and controls plant growth in response to the far-red light-dependent high-irradiance response as well as the very low fluence response. The Arabidopsis phyA gene linked to the rice rbcS promoter was transformed into embryogenic rice calli, and the calli were regenerated to whole plants. Compared to wild-type seedlings, the rbcS::PHYA transgenic seedlings contained more phyA when grown in the dark, and at least 10-fold more phyA when exposed to white light. When grown in paddy, the phyA transgenic plants in general exhibited reduced plant height (dwarfing), larger grain size, higher chlorophyll content, smaller tiller number, and low grain fertility compared to wild-type plants. The heading stage was not significantly changed. However, it is likely that a certain level of phyA is a prerequisite for induction of such changes. It is suggested that phyA overproduction in rice could be a useful tool to improve rice grain productivity by the larger grain size that increases grain yield and the dwarfing that tolerates lodging-associated damage.     

Molecular and genetic analysis of transgenic rice plants expressing the maize ribosome-inactivating protein b-32 gene and the herbicide resistance bar gene

We have previously transformed rice (Oyrza sativa L.) with the maize ribosome-inactivating protein b-32 gene (Zmcrip3a) and the phosphinothricin resistance gene (bar). In the present study, Southern blot hybridization analysis of 56 primary fertile transformants resulted in distinct band patterns, indicating that all the transformants had been generated by independent integration events and 30% of them contained a single copy of the transgene. Segregation analysis of 15 R0 plants revealed that transgene was stably transmitted to their progenies and Southern blot band patterns of R1 progenies remained the same as the corresponding parents, suggesting that all the loci of multiple integration events are genetically linked. Also, in most of the lines, physical presence of the b-32 transgene co-segregated with the phosphinothricin- resistant phenotype, confirming that the transgene is behaving as a normal locus in the genome. However, some of R1 seedlings that contained multiple copies of the transgene became sensitive to phosphinothricin, indicating that its expression was silenced. Immunoblot analysis demonstrated that b-32 protein was produced and the levels of expression differed in different lines, estimated to be 0.5–1% of total soluble protein in the leaf tissues. In addition, the transgene-encoded protein was preferentially processed in germinating seeds and young leaves of R2 transgenic plants in a way similar to that in maize kernels, suggesting that the processing mechanism is conserved in the germination stage between rice and maize. This revised version was published online in June 2006 with corrections to the Cover Date.     

Phytodegradation of organophosphorus compounds by transgenic plants expressing a bacterial organophosphorus hydrolase

Organophosphorus (OP) compounds are widely used as pesticides in agriculture but cause broad-area environmental pollution. In this work, we have expressed a bacterial organophosphorus hydrolase (OPH) gene in tobacco plants. An assay of enzyme activity showed that transgenic plants could secrete OPH into the growth medium. The transgenic plants were resistant to methyl parathion (Mep), an OP pesticide, as evidenced by a toxicity test showing that the transgenic plants produced greater shoot and root biomass than did the wild-type plants. Furthermore, at 0.02% (v/v) Mep, the transgenic plants degraded more than 99% of Mep after 14 days of growth. Our work indicates that transgenic plants expressing an OPH gene may provide a new strategy for decontaminating OP pollutants.     

Recovery of transgenic rice plants expressing the rice dwarf virus outer coat protein gene (S8)

 The coding region of the eighth largest segment (S8) of the rice dwarf virus (RDV) was obtained from a RDV Fujian isolate. It was then cloned into pTrcHisA for expression in E. coli and into vector pE3 for plant transformation. By using callus derived from mature rice embryos as the target tissue, we obtained regenerated rice plants after bombardment of the former with plasmid pE3R8 containing the RDV S8 gene and the marker gene neomycin phosphotransferase (NPT II). Southern blotting confirmed the integration of the RDV S8 gene into the rice genome. The expression of the outer coat protein in both E. coli and rice plants was confirmed by western blotting. The recovery of transgenic rice plants expressing S8 gene is an important step towards studying the function of the RDV genes and obtaining RDV-resistant rice plants. Received: 1 March 1996 / Accepted: 2 August 1996     

Characterization of tobacco plants expressing a bacterial salicylate hydroxylase gene

Transgenic tobacco plants that express the bacterial nahG gene encoding salicylate hydroxylase have been shown to accumulate very little salicylic acid and to be defective in their ability to induce systemic acquired resistance (SAR). In recent experiments using transgenic NahG tobacco and Arabidopsis plants, we have also demonstrated that salicylic acid plays a central role in both disease susceptibility and genetic resistance. In this paper, we further characterize tobacco plants that express the salicylate hydroxylase enzyme. We show that tobacco mosaic virus (TMV) inoculation of NahG tobacco leaves induces the accumulation of the nahG mRNA in the pathogen infected leaves, presumably due to enhanced stabilization of the bacterial mRNA. SAR-associated genes are expressed in the TMV-infected leaves, but this is localized to the area surrounding necrotic lesions. Localized acquired resistance (LAR) is not induced in the TMV-inoculated NahG plants suggesting that LAR, like SAR, is dependent on SA accumulation. When SA is applied to nahG-expressing leave's SAR gene expression does not result. We have confirmed earlier reports that the salicylate hydroxylase enzyme has a narrow substrate specificity and we find that catechol, the breakdown product of salicylic acid, neither induces acquired resistance nor prevents the SA-dependent induction of the SAR genes.     

Production of marker-free transgenic rice expressing tissue-specific Bt gene

The hybrid Bacillus thuringiensis (Bt) δ-endotoxin gene Cry1Ab/Ac was used to develop a transgenic Bt rice (Oryza sativa L.) targeting lepidopteran insects of rice. Here, we show the production of a marker-free and tissue-specific expressing transgenic Bt rice line L24 using Agrobacterium-mediated transformation and a chemically regulated, Cre/loxP-mediated DNA recombination system. L24 carries a single copy of marker-free T-DNA that contains the Cry1Ab/Ac gene driven by a maize phosphoenolpyruvate carboxylase (PEPC) gene promoter. The marker-free T-DNA was integrated into the 3′ untranslated region of rice gene Os01g0154500 on the short arm of chromosome 1. Compared to the constitutive and non-specific expression of the P _Actin1 :Cry1Ab/Ac:T _Nos gene in the control Bt rice line T51-1, the P _Pepc :Cry1Ab/Ac:T _Nos gene was detected only in the leaf and stem tissues of L24. More importantly, compared to high levels of CRY1Ab/Ac proteins accumulated in T51-1 seeds, the CRY1Ab/Ac proteins were not detectable in L24 seeds by Western blot analysis. As demonstrated by insect bioassay, L24 provided similar level of resistance to rice leaffolder (Cnaphalocrocis medinalis) as T51-1. The marker-free transgenic line L24 can be used directly in rice breeding for insect resistance to lepidopteran insects where absence of Bt toxin protein in the seed is highly desirable.     

Increased baculovirus susceptibility of armyworm larvae feeding on transgenic rice plants expressing an entomopoxvirus gene.

We have introduced an entomopoxvirus gene encoding a virus enhancing factor (EF) into rice, which resulted in high-level accumulation of the EF in the transgenic plants. The introduced gene was stably inherited in the progeny of the primary transformants, as shown by analysis of their genomic DNA. Bioassays for insect susceptibility to baculovirus infection showed that armyworm larvae feeding on the transgenic rice had increased susceptibility to a Nucleopolyhedrovirus. Thus, introduction of the EF gene into plants can be used as a strategy to increase the effectiveness of baculoviruses in insect pest management.     

Enhanced stress-tolerance of transgenic tobacco plants expressing a human dehydroascorbate reductase gene

To analyze the physiological role of dehydroascorbate reductase (DHAR, EC 1.8.5.1) catalyzing the reduction of DHA to ascorbate in environmental stress adaptation, T1 transgenic tobacco (Nicotiana tabacum cv. Xanthi) plants expressing a human DHAR gene in chloroplasts were biochemically characterized and tested for responses to various stresses. Fully expanded leaves of transgenic plants had about 2.29 times higher DHAR activity (units/g fresh wt) than non-transgenic (NT) plants. Interestingly, transgenic plants also showed a 1.43 times higher glutathione reductase activity than NT plants. As a result, the ratio of AsA/DHA was changed from 0.21 to 0.48, even though total ascorbate content was not significantly changed. When tobacco leaf discs were subjected to methyl viologen (MV) at 5 mumol/L and hydrogen peroxide (H2O2) at 200 mmol/L, transgenic plants showed about a 40% and 25% reduction in membrane damage relative to NT plants, respectively. Furthermore, transgenic seedlings showed enhanced tolerance to low temperature (15 degrees C) and NaCl (100 mmol/L) compared to NT plants. These results suggest that a human derived DHAR properly works for the protection against oxidative stress in plants.     

Fungal and bacterial disease resistance in transgenic plants expressing human lysozyme

The human lysozyme gene, which is assembled by the stepwise ligation of chemically synthesized oligonucleotides, was introduced into tobacco (Nicotiana tabacum cv `SR1') by the Agrobacterium-mediated method. The introduced human lysozyme gene was highly expressed under the control of the cauliflower mosaic virus 35S promoter, and the gene product accumulated in the transgenic tobacco plants. The transgenic tobacco plants showed enhanced resistance against the fungus Erysiphe cichoracearum – both conidia formation and mycelial growth were reduced, and the size of the colony was diminished. Microscopic observation revealed that the transgenic tobacco plants carried the resistant phenotype, analogous to that of the resistant cultivar `Kokubu' which had been selected by conventional breeding. Growth of the phytopathogenic bacterium Pseudomonas syringae pv. tabaci was also strongly retarded in the transgenic tobacco, and the chlorotic halo of the disease symptom was reduced to 17% of that observed in the wild-type tobacco. Thus, the introduction of a human lysozyme gene is an effective approach to protect crops against both fungal and bacterial diseases. Received: 9 September 1996 / Revision received: January 9 1997 / Accepted: 20 February 1997     

Evaluation of transgenic tobacco plants expressing a bacterial Co-Ni transporter for acquisition of cobalt

Phytoremediation is a viable strategy for management of toxic wastes in a large area/volume with low concentrations of toxic elemental pollutants. With increased industrial use of cobalt and its alloys, it has become a major metal contaminant in soils and water bodies surrounding these industries and mining sites with adverse effects on the biota. A bacterial Co-Ni permease was cloned from Rhodopseudomonas palustris and introduced into Nicotiana tabacum to explore its potential for phytoremediation and was found to be specific for cobalt and nickel. The transgenic plants accumulated more cobalt and nickel as compared to control, whereas no significant difference in accumulation of other divalent ions was observed. The transgenic plants were evaluated for cobalt content and showed increased acquisition of cobalt (up to 5 times) as compared to control. The plants were also assessed for accumulation of nickel and found to accumulate up to 2 times more nickel than control. At the same initial concentration of cobalt and nickel, transgenic plant preferentially accumulated cobalt as compared to nickel. The present study is perhaps the first attempt to develop transgenic plants expressing heterologous Co transporter with an improved capacity to uptake cobalt.     

Ethylene formation and phenotypic analysis of transgenic tobacco plants expressing a bacterial ethylene-forming enzyme

A bacterial ethylene-forming enzyme (EFE) catalyzes oxygenation of 2-oxoglutarate to produce ethylene and carbon dioxide in contrast to a plant enzyme which uses 1-aminocyclopropane-1-carboxylic acid as a substrate. We constructed several lines of transgenic tobacco plants which expressed an EFE from Pseudomonas syringae pv. phaseolicola PK2. The gene encoding a chimeric protein consisting of EFE and beta-glucuronidase (GUS) was introduced into the tobacco genome using a binary vector which directs expression of the EFE-GUS fusion protein under the control of constitutive promoter of cauliflower mosaic virus 35S RNA. Two lines of transgenic plants produced ethylene at consistently higher rates than the untransformed plant, and their GUS activities were expressed in different tissues. A significant dwarf morphology observed in the transgenic tobacco displaying the highest ethylene production resembled the phenotype of a wild-type plant exposed to excess ethylene. These results demonstrate a potential use of bacterial EFE to supply ethylene as a hormonal signal via an alternative route using an ubiquitous substrate 2-oxoglutarate in plant tissues.     

Herbicide resistance of transgenic rice plants expressing human CYP1A1

Cytochrome P450 monooxygenases (P450s) metabolize herbicides to produce mainly non-phytotoxic metabolites. Although rice plants endogenously express multiple P450 enzymes, transgenic plants expressing other P450 isoforms might show improved herbicide resistance or reduce herbicide residues. Mammalian P450s metabolizing xenobiotics are reported to show a broad and overlapping substrate specificity towards lipophilic foreign chemicals, including herbicides. These P450s are ideal for enhancing xenobiotic metabolism in plants. A human P450, CYP1A1, metabolizes various herbicides with different structures and modes of herbicide action. We introduced human CYP1A1 into rice plants, and the transgenic rice plants showed broad cross-resistance towards various herbicides and metabolized them. The introduced CYP1A1 enhanced the metabolism of chlorotoluron and norflurazon. The herbicides were metabolized more rapidly in the transgenic rice plants than in non-transgenic controls. Transgenic rice plants expressing P450 might be useful for reducing concentrations of various chemicals in the environment.     

The creation of sugar beet transgenic plants expressing bar gene

The parameters of transformation using Agrobacterium tumefaciens EHA 105 for 5 domestic sorts and lines of sugar beet (Beta vulgaris L. var. saccharifera (Alef) Krass) were optimized. The system of transgenic tissue selection based on resistance to phosphinothricin, allowing to avoid the appearing of chimeric shoots among initial transformants was developed. The transgenic plants of sugar beet sorts Ramonskaya single seed 47, L’govskaya single seed 52 and RMS 73, and LBO 17 and LBO 19 lines expressing the gene of phosphinothricin acetyl transferase bar have been obtained. The resistance of these sorts and lines to the effect of phosphinothricin in vitro has been shown.     

Enhanced cold stress tolerance of transgenic Dendrocalamus latiflorus Munro (Ma bamboo) plants expressing a bacterial CodA gene

Ma bamboo (Dendrocalamus latiflorus Munro) is a widespread culm and shoot-producing species in southern China. However, low temperatures reduce Ma bamboo shoot production and delay its development. In an attempt to enhance its cold-tolerance, a bacterial CodA gene encoding choline oxidase was introduced into Ma bamboo by Agrobacterium-mediated transformation, an approach that had not been previously utilized in bamboo. PCR and Southern blot analyses confirmed that CodA had integrated into the Ma bamboo genome. RT-PCR results showed that expression of CodA driven by the Arabidopsis Rd29A promoter was induced by cold stress in the transgenic bamboo lines. Following treatment at 4°C for 24 h, the content of glycine betaine (GB) increased to 83% and 140% in control plants (wild type (WT)) and CodA transgenic Ma bamboo plants, respectively. Superoxide dismutase, peroxidase, and catalase activities increased in both transgenic and WT plants. However, increases in these enzymes activities were much greater in the transgenic lines than in the WT plants under cold stress. The accumulation of malondialdehyde and electrolyte leakage (REL) in CodA transgenic Ma bamboo plants was less than that in control plants. Collectively, these results suggest that increased cold-tolerance induced by accumulation of GB in vivo was associated with the enhancement of antioxidant enzyme activities, which led to reduced accumulation of reactive oxygen species and stabilization of membrane integrity against extreme temperatures in transgenic plants.     

Photoresponses of transgenic tobacco plants expressing an oat phytochrome gene

The physiological responses of transgenic tobacco (Nicotiana tabacum L.) plants that express high levels of an introduced oat (Avena sativa L.) phytochrome (phyA) gene to various light treatments are compared with those of wild-type (WT) plants. Seeds, etiolated seedlings, and light-grown plants from a homozygous transgenic tobacco line (9A4) constructed by Keller et al. (EMBO J, 8, 1005–1012, 1989) were treated with red (R), far-red (FR), or white light (WL) with or without supplemental FR light, revealing major perturbations of the normal photobiological responses. White light stimulated germination of both WT and transgenic seed, but addition of FR to the WL treatment suppressed germination. In the WT, all fluence rates tested inhibited germination, but in the transgenics, reduction effluence rate partially relieved germination from the FR-mediated inhibition. It is suggested that the higher absolute levels of the FR-absorbing form of phytochrome (Pfr) in the irradiated transgenics, compared to the WT, may be responsible for the reduced FR-mediated inhibition of germination in the former. Hypocotyl extension of dark-grown seedlings of both WT and transgenic lines was inhibited by continuous R or FR irradiation, typical of the high-irradiance response (HIR). After 2 d of de-etiolation in WL, the WT seedlings had lost the FR-mediated inhibition of hypocotyl extension, whereas it was retained in the transgenics. The FR-mediated inhibition of hypocotyl extension in the transgenic seedlings after de-etiolation may reflect the persistence of an, FR-HIR response mediated by the overexpressed oat PhyA phytochrome. Light-grown WT seedlings exhibited typical shade-avoidance responses when treated with WL supplemented with high levels of FR radiation. Internode and petiole extension rates were markedly increased, and the chlorophyll ab ratio decreased, in the low-R: FR treatment. The transgenics, however, showed no increases in extension growth under low-R: FR treatments, and at low fluence rates both internode and petiole extension rates were significantly decreased by low R FR. Interpretation of these data is difficult. The depression of the chlorophyll ab ratio by low R FR was identical in WT and transgenic plants, indicating that not all shade-avoidance responses of light-grown plants were disrupted by the over-expression of the introduced oat phyA gene. The results are discussed in relation to the proposal that different members of the phytochrome family may have different physiological roles.Abbreviations FR far-red light - PAR photosynthetically active radiation - Pr, Pfr red- and FR-absorbing forms of phytochrome - Ptot total phytochrome - PhyA (PhyA) gene (encoded protein) for phytochrome - R red light - WL white light - WT wild type This work was supported by an Agricultural and Food Research Council research grant to H.S. and A.C.M.; the production of the transgenic seed was funded by the U.S. Department of Energy (DE-F602-88ER13968) to R.D.V., and by E.I. du Pont de Nemours; Dr. G.C. Whitelam is thanked for the provision of monoclonal antibodies for the immunoblot analyses.