Expression of three osmotin-like protein genes in response to osmotic stress and fungal infection in potato

We have characterized three cDNAs encoding osmotin-like proteins from potato (Solanum commersonii) cell cultures. These cDNAs (pA13, pA35, and pA81) have extensive nucleotide identity in the coding regions but low homology in the 3 non-coding sequences, and may encode three isoforms of potato pathogenesis-related (PR) type 5 proteins. Using gene-specific probes, RNA gel blot analyses showed constitutive accumulation of osmotin-like protein mRNAs in cell cultures, leaves, stems, roots and flowers, with high abundance in the roots and mature flowers. Treatments with abscisic acid (ABA), low temperature, and NaCl increased the accumulation of all three mRNAs in S. commersonii cell cultures and plants grown in vitro. Salicylic acid (SA), and wounding resulted in a moderate increase in the levels of pA13 and pA81 but not pA35 mRNAs. Infection with the fungus Phytophthora infestans activated strong and non-systemic expression of all three osmotin-like protein genes. The accumulation of osmotin-like proteins, however, was detected only in P. infestans-infected tissues but not in plants treated with ABA, SA, NaCl, low temperature, or wounding.     

Transgenic potato plants overexpressing the pathogenesis-related STH-2 gene show unaltered susceptibility to Phytophthora infestans and potato virus X

The STH-2 gene is rapidly activated in potato leaves and tubers following elicitation or infection by Phytophthora infestans. However, its biochemical function remains unknown. In order to ascertain if STH-2 protein is directly involved in the defense of potato against pathogens, the STH-2 coding sequence under the control of the CaMV 35S promoter was introduced into potato plants. Transgenic plants expressing the STH-2 gene were analyzed for an altered pattern of susceptibility to a compatible race of P. infestans and to potato virus X. Results indicate that constitutive expression of the STH-2 gene did not reduce susceptibility of potato to these pathogens.     

An agglutinating chitinase with two chitin-binding domains confers fungal protection in transgenic potato

Brassica juncea BjCHI1 is a unique chitinase with two chitin-binding domains. Here, we show that, unlike other chitinases, potato-expressed BjCHI1 shows hemagglutination ability. BjCHI1 expression in B. juncea seedlings is induced by Rhizoctonia solani infection, suggesting its protective role against this fungus. To verify this, transgenic potato (Solanum tuberosum L. cv. Desiree) plants expressing BjCHI1 generated by Agrobacterium-mediated transformation were challenged with R. solani. We also transformed potato with a cDNA encoding Hevea brasiliensis -1,3-glucanase, designated HbGLU, and a pBI121-derivative that contains cDNAs encoding both BjCHI1 and HbGLU. In vitro fungal bioassays using Trichoderma viride showed that extracts from transgenic potato lines co-expressing BjCHI1 and HbGLU inhibited fungal growth better than extracts from transgenic potato expressing either BjCHI1 or HbGLU, suggesting a synergistic effect. Consistently, in vivo fungal bioassays with soil-borne R. solani on young transgenic potato plants indicated that the co-expressing plants showed healthier root development than untransformed plants or those that expressed either BjCHI1 or HbGLU. Light microscopy and transmission electron microscopy revealed abundant intact R. solani hyphae and monilioid cells in untransformed roots and disintegrated fungus in the BjCHI1-expressing and the BjCHI1 and HbGLU co-expressing plants. Observations of collapsed epidermal cells in the co-expressing potato roots suggest that these proteins effectively degrade the fungal cell wall, producing elicitors that initiate other defense responses causing epidermal cell collapse that ultimately restricts further fungal penetration.     

Potato hexokinase 2 complements transgenic Arabidopsis plants deficient in hexokinase 1 but does not play a key role in tuber carbohydrate metabolism

Potato plants (Solanum tuberosum L. cv. Désirée) transformed with sense and antisense constructs of a cDNA encoding the potato hexokinase 2 exhibited altered enzyme activities and expression of hexokinase 2 mRNA. Measurements of the maximum catalytic activity of hexokinase revealed an 11-fold variation in leaf (from 48% of the wild-type activity in antisense transformants to 446% activity in sense transformants) and an 8-fold variation in developing tubers (from 35% of the wild-type activity in antisense transformants to 212% activity in sense transformants). Despite the wide range of hexokinase activities, no substantial change was found in the fresh weight yield, starch, sugar and metabolite levels of transgenic tubers. However, both potato hexokinases 1 and 2 were able to complement the hyposensitivity of antisense hexokinase 1 Arabidopsis transgenic plants to glucose. In an in vitro bioassay of seed germination in a medium with high glucose levels, double transformants showed the same sensitivity to glucose as that of the wild-type ecotype, displaying a stunted phenotype in hypocotyls, cotyledons and roots.     

Effect of chitinase antisense RNA expression on disease susceptibility of Arabidopsis plants

Chitinases accumulate in higher plants upon pathogen attack are capable of hydrolyzing chitin-containing fungal cell walls and are thus implicated as part of the plant defense response to fungal pathogens. To evaluate the relative role of the predominate chitinase (class I, basic enzyme) of Arabidopsis thaliana in disease resistance, transgenic Arabidopsis plants were generated that expressed antisense RNA to the class I chitinase. Young plants or young leaves of some plants expressing antisense RNA had <10% of the chitinase levels of control plants. In the oldest leaves of these antisense plants, chitinase levels rose to 37–90% of the chitinase levels relative to vector control plants, most likely because of accumulation and storage of the enzyme in vacuoles. The rate of infection by the fungal pathogen Botrytis cinerea was measured in detached leaves containing 7–15% of the chitinase levels of control plants prior to inoculation. Antisense RNA was not effective in suppressing induced chitinase expression upon infection as chitinase levels increased in antisense leaves to 47% of levels in control leaves within 24 hours after inoculation. Leaves from antisense plants became diseased at a slightly faster rate than leaves from control plants, but differences were not significant due to high variability. Although the tendency to increased susceptibility in antisense plants suggests that chitinases may slow the growth of invading fungal pathogens, the overall contribution of chitinase to the inducible defense reponses in Arabidopsis remains unclear.     

Genetic transformation of Rangpur lime (Citrus limonia osbeck) with thebO (bacterio-opsin) genen and its initial evaluation forPhytophthora nicotianae resistance

Transgenic plants expressing the bacterio-opsin (bO) gene can spontaneously activate programmed cell death (ped) and may enhance broad-spectrum pathogen resistance by activating an intrinsic defense pathway in plant species such as tobacco and potato. In this work, we produced transgenic Rangpur lime plants with thebO gene, viaAgrobacterium tumefaciens-mediated transformation, and evaluated these plants forPhytophthora nicotianae resistance. Two transgenic lines were successfully regenerated and transformation was confirmed by GUS activity assay, PCR analysis, Southern, Northern and Western blot analyses, in addition to detecting the expressed bO protein by an immunological approach. Evaluation forPhytophthora nicotianae resistance was carried out by plant inoculations with the pathogen and quantification of the affected area. One of the two transgenic lines showed greater tolerance to the fungal pathogen as compared to the control, with significantly smaller stem lesions after pathogen challenge. This increase in pathogen tolerance is correlated with a significantly higher level of transgene expression in this line when compared with the other transgenic line. This is the first report of the introduction of a potentially important gene into Rangpur lime to provide novel pathogen tolerance.     

Manipulating freezing tolerance in transgenic plants

Winterhardiness is a composite of tolerances to freezing, desiccation, ice-encasement, flooding and diseases. From one point of view, winterhardiness may not be easily manipulated by genetic engineering technology because many different genes are involved in the tolerance of these diverse stresses. However, these various stresses have similarities. They promote formation of activated forms of oxygen, promote membrane lipid and protein degradation, cause similar biophysical changes in membrane structure, and culminate with increased leakage of cytoplasmic solutes and loss of cellular membrane functions. These similarities led to the hypothesis that winter injury might be reduced in crop plants if their tolerance of oxidative stress was increased. Towards that objective we created transgenic alfalfa (Medicago sativa L.) plants that overexpress either Mn-SOD or Fe-SOD cDNA (provided by Dirk Inzé, Universiteit Gent). Petiole explants were transformed using Agrobacterium tumefaciens and plants were regenerated by somatic embryogenesis. The primary transgenic plants were screened using PCR (polymerase chain reaction), Southern hybridization and native PAGE for SOD activity. Greenhouse and laboratory studies showed a minimal difference in stress tolerance between the primary transgenic and non-transgenic plants. In the first field trial, four primary transgenic plants expressing two forms of the Mn-SOD cDNA had greater survival after two winters than the non-transgenic RA3. Similar results were obtained in a second field trial, comparing 18 independent transformants with Mn-SOD targeted to the mitochondria, 11 independent transformants with Mn-SOD targeted to the chloroplast and 39 independent transformants with Fe-SOD targeted to the chloroplast, expressed in three different non-transgenic plants. The transgenic plants averaged over 25% higher survival than the non-transgenic controls after one winter. There was no effect of subcellular targeting or SOD type on field survival, but there was variation among independent transformants containing the same SOD construct. Activated oxygen therefore appears to be one of the possible causes of winter injury, and it should be possible to reduce winter injury in transgenic plants by constitutive overexpression of SOD.     

Transgenic tobacco plants which express thechiA gene fromSerratia marcescens have enhanced tolerance toRhizoctonia solani

We have prepared independent lines of transgenic tobacco plants which express high levels of theSerratia marcescens ChiA protein intracellulary or extracellularly (in glycosylated or unglycosylated forms). We have measured the susceptibility, of these plants toRhizoctonia solani infection in greenhouse trials and in the field. Transgenic tobacco plants which constitutively express theS. marcescens ChiA protein exhibit tolerance to the fungal pathogenR. solani. Disease tolerance is observed in transgenic tobacco plants which express the bacterial chitinase intra-or extracellulary. This is the first report to document disease reduction in the field in transgenic plants engineered for fungal disease tolerance.     

Overexpression of the Tomato 13-Lipoxygenase Gene TomloxD Increases Generation of Endogenous Jasmonic Acid and Resistance to Cladosporium fulvum and High Temperature

Expression of the tomato gene encoding 13-lipoxygenase,TomloxD, is stimulated by wounding, pathogen infection, jasmonate, and systemin, but its role during growth and development of tomato (Lycopersicon Spp.) remains unclear. To assess the physiological role of TomloxD, we produced transgenic tomato plants with greatly increased TomloxD content using sense constructs under the control of the CaMV 35S promoter. Overexpression of TomloxD in transgenic tomatoes led to a marked increase in the levels of lipoxygenase activity and content of endogenous jasmonic acid (JA), which suggested that TomloxD can use α-linolenic acid as a substrate to produce (13S)-hydroperoxyoctadecatrienoic acid (13-HPOT); the 13-HPOT produced appears to be metabolized further to synthesize JA. Real-time RT-PCR revealed that the expression levels of defense genes LeHSP90, LePR1, LePR6 and LeZAT in the transformants were higher than those in non-transformed plants. Assay for resistance to pathogenic fungus and high temperature stresses suggested that transgenic plants harboring TomloxD were more tolerant to Cladosporium fulvum and high temperature stress than non-transformed tomato plants. The data presented here indicate clearly that TomloxD is involved in endogenous JA synthesis and tolerance to biotic and abiotic stress. The tomloxD gene has potential applications in engineering cropping plants that are resistant to biotic and/or abiotic stress factors.     

Stacking of antimicrobial genes in potato transgenic plants confers increased resistance to bacterial and fungal pathogens

Solanum tuberosum plants were transformed with three genetic constructions expressing the Nicotiana tabacum AP24 osmotine, Phyllomedusa sauvagii dermaseptin and Gallus gallus lysozyme, and with a double-transgene construction expressing the AP24 and lysozyme sequences. Re-transformation of dermaseptin-transformed plants with the AP24/lysozyme construction allowed selection of plants simultaneously expressing the three transgenes. Potato lines expressing individual transgenes or double- and triple-transgene combinations were assayed for resistance to Erwinia carotovora using whole-plant and tuber infection assays. Resistance levels for both infection tests compared consistently for most potato lines and allowed selection of highly resistant phenotypes. Higher resistance levels were found in lines carrying the dermaseptin and lysozyme sequences, indicating that theses proteins are the major contributors to antibacterial activity. Similar results were obtained in tuber infection tests conducted with Streptomyces scabies. Plant lines showing the higher resistance to bacterial infections were challenged with Phytophthora infestans, Rhizoctonia solani and Fusarium solani. Considerable levels of resistance to each of these pathogens were evidenced employing semi-quantitative tests based in detached-leaf inoculation, fungal growth inhibition and in vitro plant inoculation. On the basis of these results, we propose that stacking of these transgenes is a promising approach to achieve resistance to both bacterial and fungal pathogens.     

Inhibition of agrobacterial oncogene expression by means of antisense RNAs

Infection of plants by soil bacterium Agrobacterium tumefaciens induces tumors referred to as crown galls. Tumor development is determined by the introduction of agrobacterial genes governing phytohormone (auxin and cytokinin) production into the plant genome. The most important of these genes are iaaM and ipt. Development of transgenic plants inhibiting the expression of these genes allows a raise of varieties resistant to crown gall disease. For this purpose, single and double tobacco transformants with antisense copies of iaaM and ipt fused with single and double promoters for the 35S RNA of the cauliflower mosaic virus (CaMV 35S and CaMV 35SS) were obtained. Inoculation of transgenic plants harboring the antisense oncogene copies with virulent A. tumefaciens strains C58 (pTiC58) and A6 (pTiA6) revealed significant, but still incomplete, inhibition of these genes. Agrobacterium-mediated transformation of transgenic plants gave rise to weakened tumors, which varied in morphology and allowed regeneration of whole plants. Analysis of the inhibition of the iaaM and ipt expression in tumor cells demonstrated that the RNA interference strategy is promising for developing plant varieties resistant to agrobacterial infection.     

Optimization of transgene-mediated silencing in Phytophthora infestans and its association with small-interfering RNAs

Methods for silencing genes in Phytophthora transformants have been demonstrated previously, but wide variation in effectiveness was reported in different studies. To optimize this important tool for functional genomics, we compared the abilities of sense, antisense, and hairpin transgenes introduced by protoplast, electroporation, and bombardment methods to silence the inf1 elicitin gene in Phytophthora infestans. A hairpin construct induced silencing three times more often than sense or antisense vectors, and protoplast transformation twice as much as electroporation. Using hairpins introduced into protoplasts, 61% of strains were silenced, and transgene copy number was positively correlated with silencing. The utility of bombardment was reduced by the occurrence of heterokaryons containing silenced and non-silenced nuclei, but silenced strains were obtainable from about 20% of primary transformants by single-nuclear purification. Most inf1-deficient strains were fully silenced, however some exhibited partial suppression. These produced inf1-derived RNAs of about 21-nt which correspond to both the sense and antisense strands of inf1, implicating an RNAi-like mechanism in silencing.     

Microbial populations,fungal species diversity and plant pathogen levels in field plots of potato plants expressing theBacillus thuringiensis var.tenebrionis endotoxin

The environmental release of genetically engineered (transgenic) plants may be accompanied by ecological effects including changes in the plant-associated microflora. A field release of transgnic potato plants that produce the insecticidal endotoxin ofBacillus thuringiensis var.tenebrionis (Btt) was monitored for changes in total bacterial and fungal populations, fungal species diversity and abundance, and plant pathogen levels. The microflora on three phenological stages of leaves (green, yellow and brown) were compared over the growing season (sample days 0, 21, 42, 63 and 98) for transgenic potato plants, commercial Russet Burbank potato plants treated with systemic insecticide (Di-Syston) and commercial Russet Burbank potato plants treated with microbialBtt (M-Trak). In addition, plant and soil assays were performed to assess disease incidence ofFusarium spp.,Pythium spp.,Verticillium dahliae, potato leaf roll virus (PLRV) and potato virus Y (PVY). Few significant differences in phylloplane microflora among the plant types were observed and none of the differences were persisent. Total bacterial populations on brown leaves on sample day 21 and on green leaves on sample day 42 were significantly higher on the transgenic potato plants. Total fungal populations on gree leaves on sample day 63 were significantly different among the three plant types; lowest levels were on the commerical potato plants treated with systemic insecticide and highest levels were on the commercial potato plants treated with microbialBtt. Differences in fungal species assemblages and diversity were correlated with sampling dates, but relatively consistent among treatments.Alternaria alternata, a common saprophyte on leaves and in soil and leaf litter, was the most commonly isolated fungus species for all the plant treatments. Rhizosphere populations of the soilborne pathogensPythium spp.,Fusarium spp. andV. dahliae did not differ between the transgenic potato plants and the commercial potato plants treated with systemic insecticide. The incidence of tuber infection at the end of the growing season by the plant pathogenV. dahliae was highest for the transgenic potato plants but this difference was related to longer viability of the transgenic potato plants. This difference in longevity between the transgenic potato plants and the commercial + systemic insecticide potato plants also made comparison of the incidence of PVY and PLRV problematic. Our results indicate that under field conditions the microflora of transgenicBtt-producing potato plants differed minimally from that of chemically and microbially treated commerical potato plants.     

Improvement of freezing tolerance in tobacco plants expressing a cold-responsive and chloroplast-targeting protein WCOR15 of wheat

Cold acclimation, an adaptive process for developing freezing tolerance in over-wintering plants, is associated with increased expression levels of a series of cold-responsive (Cor)/late embryogenesis abundant (Lea) genes. To investigate the function of Wcor15, a member of the wheat Cor/Lea gene family, for improvement of freezing tolerance, two types of transgenic tobacco lines expressing Wcor15-containing chimeric genes were produced and characterized. Immunoblot and gene expression analyses of a transgenic tobacco line expressing the Wcor15-GFP fusion gene under control of the CaMV35S promoter showed transport and abundant accumulation of the WCOR15 protein in the stromal compartment of the chloroplasts. The 5' upstream region of Wcor15 induced expression of the GFP reporter gene under low-temperature conditions in the transgenic tobacco. Both transgenic lines expressing the Wcor15-GFP fusion gene showed a similar and significantly improved level of freezing tolerance compared with the wild-type tobacco plants. Our results demonstrate that the induced expression of the wheat Wcor15 gene positively contributes to the development of freezing tolerance in the heterologous tobacco plants.     

The expression of cecropin peptide in transgenic tobacco does not confer resistance to Pseudomonas syringae pv tabaci

Summary We used in vitro growth inhibition assays to demonstrate that synthetic cecropin protein has potent activity against a range of plant pathogenic bacteria. We then prepared transgenic tobacco plants which express cecropin mRNA and protein. We have used Pseudomonas syringae pv tabaci infection of these transgenic tobacco as a model system to evaluate whether the plants which express cecropin protein also have increased tolerance to infection. We found no dramatic difference in disease response between plants which are expressing cecropin protein and control plants which were derived from the transformation with a binary vector which did not carry the gene encoding cecropin protein.