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.     

Tomato sugar transporter genes associated with mycorrhiza and phosphate

A new kind of ribosome-inactivating protein (curcin 2), induced by several different kinds of stress from Jatropha curcas leaves, under the control of the CaMV (cauliflower mosaic virus) 35S promoter, was introduced into the tobacco genome by Agrobacterium tumefaciens-mediated transformation method. The curcin 2 protein was only detected in the transgenic tobacco plantlets transformed with the cur2p fragment (coding premature curcin 2 protein), but not in the plantlets with the cur2m fragment (coding mature curcin 2 protein). The T1 population of the transgenic lines shows an increased tolerance to tobacco mosaic virus (TMV) and a fungal pathogen Rhizoctonia solani by delaying the development of systemic symptoms of TMV and reducing the damage caused by the fungal disease. The increases of the tolerances correspond to the curcin 2 level in the transgenic plants.     

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.     

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.     

Transgenic tobacco and peanut plants expressing a mustard defensin show resistance to fungal pathogens

Defensins are small positively charged, antimicrobial peptides (~5 kDa in size) and some of them exhibit potent antifungal activity. We have cloned the complete cDNA containing an ORF of 243 bp of a defensin of mustard. The deduced amino acid sequence of the peptide showed more than 90% identity to the amino acid sequence of the well-characterized defensins, RsAFP-1 and RsAFP-2 of Raphanus sativus. We have generated and characterized transgenic tobacco and peanut plants constitutively expressing the mustard defensin. Transgenic tobacco plants were resistant to the fungal pathogens, Fusarium moniliforme and Phytophthora parasitica pv. nicotianae. Transgenic peanut plants showed enhanced resistance against the pathogens, Pheaoisariopsis personata and Cercospora arachidicola, which jointly cause serious late leaf spot disease. These observations indicate that the mustard defensin gene can be deployed for deriving fungal disease resistance in transgenic crops.     

Expression of bacterial chitinase protein in tobacco leaves using two photosynthetic gene promoters

Summary A bacterial chitinase gene from Serratia marcescens (chiA) was fused to (i) a promoter of the ribulose bisphosphate carboxylase small subunit (rbcS) gene and (ii) two different chlorophyll a/b binding protein (cab) gene promoters from petunia. The resulting constructions were introduced into Agrobacterium Ti plasmid-based plant cell transformation vectors and used to generate multiple independent transgenic tobacco plants. ChiA mRNA and protein levels were measured in these plants. On average, the rbcS/chiA fusion gave rise to threefold more chiA mRNA than either cab/chiA fusion. We investigated the influence of sequences around the translational initiation ATG codon on the level of ChiA protein. The rbcS/chiA and cab/chiA fusions in which the sequence in the vicinity of the translational initiation codon is ACC ATGGC gave rise to transformants with higher levels of ChiA protein than those carrying a cab/chiA fusion with the sequence CAT ATGCG in the same region. This difference in translational efficiency is consistent with previous findings on preferred sequences in this region of the mRNA. In those transformants showing the highest level of ChiA expression, ChiA protein accumulated to about 0.25% of total soluble leaf protein. These plants contained significantly higher chitinase enzymatic activity than control plants.     

The Saccharomyces cerevisiae chitinase,encoded by the CTS1-2 gene,confers antifungal activity against Botrytis cinerea to Transgenic tobacco

The Saccharomyces cerevisiae chitinase, encoded by the CTS1-2 gene has recently been confirmed by in vitro tests to possess antifungal abilities. In this study, the CTS1-2 gene has been evaluated for its in planta antifungal activity by constitutive overexpression in tobacco plants to assess its potential to increase the plant's defence against fungal pathogens. Transgenic tobacco plants, generated by Agrobacterium-mediated transformation, showed stable integration and inheritance of the transgene. Northern blot analyses conducted on the transgenic tobacco plants confirmed transgene expression. Leaf extracts from the transgenic lines inhibited Botrytis cinerea spore germination and hyphal growth by up to 70% in a quantitative in vitro assay, leading to severe physical damage on the hyphae. Several of the F₁ progeny lines were challenged with the fungal pathogen, B. cinerea, in a detached leaf infection assay, showing a decrease in susceptibility ranging from 50 to 70%. The plant lines that showed increased disease tolerance were also shown to have higher chitinase activities.     

Expression of the bacteriophage T4 lysozyme gene in tall fescue confers resistance to gray leaf spot and brown patch diseases

Tall fescue (Festuca arundinacea Schreb.) is an important turf and forage grass species worldwide. Fungal diseases present a major limitation in the maintenance of tall fescue lawns, landscapes, and forage fields. Two severe fungal diseases of tall fescue are brown patch, caused by Rhizoctonia solani, and gray leaf spot, caused by Magnaporthe grisea. These diseases are often major problems of other turfgrass species as well. In efforts to obtain tall fescue plants resistant to these diseases, we introduced the bacteriophage T4 lysozyme gene into tall fescue through Agrobacterium-mediated genetic transformation. In replicated experiments under controlled environments conducive to disease development, 6 of 13 transgenic events showed high resistance to inoculation of a mixture of two M. grisea isolates from tall fescue. Three of these six resistant plants also displayed significant resistance to an R. solani isolate from tall fescue. Thus, we have demonstrated that the bacteriophage T4 lysozyme gene confers resistance to both gray leaf spot and brown patch diseases in transgenic tall fescue plants. The gene may have wide applications in engineered fungal disease resistance in various crops.     

Thaumatin gene confers resistance to fungal pathogens as well as tolerance to abiotic stresses in transgenic tobacco plants

We report here the development of transgenic tobacco plants with thaumatin gene of Thaumatococcus daniellii under the control of a strong constitutive promoter-CaMV 35S. Both polymerase chain reaction and genomic Southern analysis confirmed the integration of transgene. Transgenic plants exhibited enhanced resistance with delayed disease symptoms against fungal diseases caused by Pythium aphanidermatum and Rhizoctonia solani. The leaf extract from transgenic plants effectively inhibited the mycelial growth of these pathogenic fungi in vitro. The transgenic seeds exhibited higher germination percentage and seedling survival under salinity and PEG-mediated drought stress as compared to the untransformed controls. These observations suggest that thaumatin gene can confer tolerance to both fungal pathogens and abiotic stresses.     

Bacterial chitinase is modified and secreted in transgenic tobacco

The chiA gene of Serratia marcescens codes for a secreted protein, bacterial chitinase (ChiA). We have investigated the modifications and the cellular location of ChiA when it is expressed in transgenic tobacco plants. Immunoblots on total leaf protein probed with antibody to ChiA showed that when the bacterial chitinase is expressed in plants, it migrates as a series of discrete bands with either the same or a slower mobility than the secreted bacterial protein. Analysis of the vacuum infiltrate of leaves expressing ChiA showed that the modified forms of the protein are enriched in the intercellular fluid. Media recovered from suspension cultures of cell lines expressing the chiA gene were also enriched for the modified forms of ChiA. Washed protoplasts, however, contained only the nonmodified form. The molecular weight of these polypeptides is reduced by treatment with glycopeptidase F but not with endoglycosidase H. Treatment of the suspension cultures with tunicamycin also leads to reduction in the molecular weight of the chitinase bands. We suggest that some of the ChiA protein is N-glycosylated and secreted when expressed in plants, and that the modifications are complex glycans. These results show that a bacterial signal sequence can function in plant cells, and that protein secretion from plant cells probably operates by a default pathway.     

Transgenic indica Rice Expressing ns-LTP-Like Protein Shows Enhanced Resistance to Both Fungal and Bacterial Pathogens

Antimicrobial peptides (AMPs) from plant seeds, known to inhibit pathogen growth have a great potential in developing transgenic plants resistant to disease. Some of the nonspecific-lipid transfer proteins (ns-LTP) that facilitate in vitro transport of lipids, show antimicrobial activity in vitro. Rice seeds also contain ns-LTPs; however, these genes are expressed weakly in seedlings. We have transformed Pusa Basmati 1, an elite indica rice cultivar, with the gene for Ace-AMP1 from Allium cepa, coding for an effective antimicrobial protein homologous to ns-LTPs. The gene for Ace-AMP1 was cloned under an inducible rice phenylalanine ammonia-lyase (PAL) or a constitutive maize ubiquitin (UbI) promoter. Ace-AMP1 was expressed in transgenic lines and secreted in the apoplastic space. Protein extracts from leaves of transgenic plants inhibited three major rice pathogens, Magnaporthe grisea, Rhizoctonia solani and Xanthomonas oryzae, in vitro. Enhanced resistance against these pathogens was observed in in planta assays, and the degree of resistance correlating with the levels of Ace-AMP1 with an average increase in resistance to blast, sheath blight, and bacterial leaf blight disease by 86%, 67%, and 82%, respectively. Importantly, transgenic rice plants, with stable integration and expression of Ace-AMP1, retained their agronomic characteristics while displaying enhanced resistance to both fungal and bacterial pathogens.     

Transgenic Tobacco Plants Constitutively Overexpressing a Rice Thaumatin-like Protein (PR-5) Show Enhanced Resistance to Alternaria alternata

Overexpression of antifungal pathogenesis-related (PR) proteins in crop plants has the potential for enhancing resistance against fungal pathogens. Thaumatin-like proteins (TLPs) are one group (PR-5, permatins) of antifungal PR-proteins isolated from various plants. In the present study, a plasmid containing a cDNA of rice tlp (D34) under the control of the CaMV-35S promoter was introduced into tobacco plants through Agrobacterium-mediated transformation system. A considerable overproduction of TLP was observed in transformed tobacco plants by Western blot analysis. There was a large accumulation of tlp mRNA in transgenic plants as revealed by Northern blot analysis. Southern blot analysis of the DNA from transgenic tobacco plants confirmed the presence of the rice tlp gene in the genomic DNA of transgenic tobacco plants. Immunoblot analysis of intracellular and extracellular proteins of transgenic tobacco leaves using a Pinto bean TLP antibody demonstrated that the 23-kDa TLP was secreted into the extracellular matrix. T₂ progeny of regenerated plants transformed with TLP gene were tested for their disease reaction to Alternaria alternata, the brown spot pathogen. Transgenic tobacco plants expressing TLP at high levels showed enhanced tolerance to necrotization caused by the pathogen. This revised version was published online in July 2006 with corrections to the Cover Date.     

Transgenic tobacco plants expressingBoRS1 gene fromBrassica oleracea var.acephala show enhanced tolerance to water stress

Water stress is by far the leading environmental stress limiting crop yields worldwide. Genetic engineering techniques hold great promise for developing crop cultivars with high tolerance to water stress. In this study, theBrassica oleracea var.acephala BoRS1 gene was transferred into tobacco throughAgrobacterium- mediated leaf disc transformation. The transgenic status and transgene expression of the transgenic plants was confirmed by polymerase chain reaction (PCR) analysis, Southern hybridization and semi-quantitative one step RT-PCR analysis respectively. Subsequently, the growth status under water stress, and physiological responses to water stress of transgenic tobacco were studied. The results showed that the transgenic plants exhibited better growth status under water stress condition compared to the untransformed control plants. In physiological assessment of water tolerance, transgenic plants showed more dry matter accumulation and maintained significantly higher levels of leaf chlorophyll content along with increasing levels of water stress than the untransformed control plants. This study shows thatBoRS1 is a candidate gene in the engineering of crops for enhanced water stress tolerance.     

Expression of the B subunit of <Emphasis Type="Italic">E. coli</Emphasis> heat-labile enterotoxin in tobacco using a herbicide resistance gene as a selection marker

The B subunit of Escherichia coli heat-labile enterotoxin (LTB) has been transformed to plants for use as an edible vaccine. We have developed a simple and reliable Agrobacterium-mediated transformation method to express synthetic LTB gene in N. tabacum using a phosphinothricin acetyltransferase (bar) gene as a selectable marker. The synthetic LTB gene adapted to the coding sequence of tobacco plants was cloned to a plant expression vector under the control of the ubiquitin promoter and transformed to tobacco by Agrobacterium-mediated transformation. Transgenic plants were selected in the medium supplemented with 5 mg l^-1 phosphinothricin (PPT). The amount of LTB protein detected in the transgenic tobacco was approximately 3.3% of the total soluble protein, approximately 300-fold higher than in the plants generated using the native LTB gene under the control of the CaMV 35S promoter. The transgenic plants that were transferred to a greenhouse had harvested seeds that proved to be resistant to herbicide. Thus, the described protocol could provide a useful tool for the transformation of tobacco plants.     

Over-expression of tobacco NtHSP70-1 contributes to drought-stress tolerance in plants

HSP70, a heat shock protein, is a molecular chaperone responsive to various environmental stresses. Here, NtHSP70-1 (AY372069) was a drought-/ABA-inducible gene. We monitored the expression of CaERD15 (early responsive to dehydration, DQ267932) with exposing plants to progressive drought stress. Its activity was used as an indicator of water-deficit conditions. To analyze the protective role of HSP70, we obtained transgenic tobacco plants that constitutively expressed elevated levels of the tobacco HSP70, NtHSP70-1, as well as transgenic plants containing either the vector alone or else having NtHSP70-1 in the antisense orientation. Plants with enhanced levels of NtHSP70-1 in their transgenic sense lines exhibited tolerance to water stress. Under progressive drought, the amount of leaf NtHSP70-1 was correlated with maintenance of optimum water content, with contents being higher in the leaves of dehydrated transgenic sense plants than in those of either the control (vector-only) or the transgenic antisense plants. Moreover, the expression of CaERD15 was considerably reduced in tobacco plants that over-expressed NtHSP70-1. These results suggest that elevated levels of NtHSP70-1 can confer drought-stress tolerance.     

Transgenic canola lines expressing pea defense gene DRR206 have resistance to aggressive blackleg isolates and to Rhizoctonia solani

We have previously demonstrated that transgenic Brassica napus plants expressing pea DRR206 constitutively are resistant to the hemibiotrophic blackleg fungus, Leptosphaeria maculans isolate PG2. The present work seeks to determine whether DRR206 is effective against a wider range of fungi. Transgenic plants expressing DRR206 exhibit decreased severity of stem canker in adult plants inoculated with aggressive L. maculans isolates PG3 and PG4. Decreased seedling mortality with the biotrophic root pathogen Rhizoctonia solani is also seen. Finally, leaves of DRR206 transgenic plants inoculated with the necrotroph Sclerotinia sclerotiorum show smaller lesions at 48 h after inoculation, leading to a delay, but not a prevention, of disease development. These results demonstrate the effectiveness of DRR206 against several fungal species with three distinct modes of pathogenicity. Although its precise function remains to be determined, a recent report shows that pea DRR206 shares strong amino acid sequence similarity with `dirigent proteins' which couple monolignol radicals to form the lignan (+) pinoresinol.     

Osmoregulation in the model organismEscherichia coli: genes governing the synthesis of glycine betaine and trehalose and their use in metabolic engineering of stress tolerance

Glycine betaine is known to be the preferred osmoprotectant in many bacteria, and glycine betaine accumulation has also been correlated with increased cold tolerance. Trehalose is often a minor osmoprotectant in bacteria and it is a major determinant for desiccation tolerance in many so-called anhydrobiotic organisms such as baker's yeast(Saccharomyces cerevisiae). Escherichia coli has two pathways for synthesis of these protective molecules; i.e., a two-step conversion of UDP-glucose and glucose-6-phosphate to trehalose and a two-step oxidation of externally-supplied choline to glycine betaine. The genes governing the choline-to-glycine betaine pathway have been studied inE. coli and several other bacteria and higher plants. The genes governing UDP-glucose-dependent trehalose synthesis have been studied inE. coli andS. cerevisiae. Because of their well-documented function in stress protection, glycine betaine and trehalose have been identified as targets for metabolic engineering of stress tolerance. Examples of this experimental approach include the expression of theE. coli betA andArthrobacter globiformis codA genes for glycine betaine synthesis in plants and distantly related bacteria, and the expression of theE. coli otsA and yeastTPS1 genes for trehalose synthesis in plants. The published data show that glycine betaine synthesis protects transgenic plants and phototrophic bacteria against stress caused by salt and cold. Trehalose synthesis has been reported to confer increased drought tolerance in transgenic plants, but it causes negative side effects which is of concern. Thus, the much-used model organismE. coli has now become a gene resource for metabolic engineering of stress tolerance.     

Analysis of late-blight disease resistance and freezing tolerance in transgenic potato plants expressing sense and antisense genes for an osmotin-like protein

The expression patterns of plant defense genes encoding osmotin and osmotin-like proteins imply a dual function in osmotic stress and plant pathogen defense. We have produced transgenic potato (Solanum commersonii Dun.) plants constitutively expressing sense or antisense RNAs from chimeric gene constructs consisting of the cauliflower mosaic virus 35S promoter and a cDNA (pA13) for an osmotin-like protein. Transgenic potato plants expressing high levels of the pA13 osmotin-like protein showed an increased tolerance to the late-blight fungus Phytophthora infestans at various phases of infection, with a greater resistance at an early phase of fungal infection. There was a decrease in the accumulation of osmotin-like mRNAs and proteins when antisense transformants were challenged by fungal infection, although the antisense transformants did not exhibit any alterations in disease susceptibility. Expression of pA13 sense and antisense RNAs had no effect on the development of freezing tolerance in transgenic plants when assayed under a variety of conditions including treatments with abscisic acid or low temperature. These results provide evidence of antifungal activity for a potato osmotin-like protein against the fungus P. infestans, but do not indicate that pA13 osmotin-like protein is a major determinant of freezing tolerance.     

Heterologous expression of <Emphasis Type="Italic">Arabidopsis</Emphasis><Emphasis Type="Italic">NPR1</Emphasis> (<Emphasis Type="Italic">AtNPR1</Emphasis>) enhances oxidative stress tolerance in transgenic tobacco plants

In Arabidopsis, NPR1 (non-expressor of pathogenesis related genes 1, AtNPR1) functions downstream of salicylic acid (SA) and modulates the SA mediated systemic acquired resistance. It is also involved in a cross talk with the jasmonate pathway that is essential for resistance against herbivores and necrotrophic pathogens. Overexpression of AtNPR1 in transgenic plants resulted in enhanced disease resistance. Recently, tobacco transgenic plants expressing AtNPR1 were shown to be tolerant to the early instars of Spodoptera litura (Meur et al., Physiol Plant 133:765–775, 2008). In this communication, we show that the heterologous expression of AtNPR1 in tobacco has also enhanced the oxidative stress tolerance. The transgenic plants exhibited enhanced tolerance to the treatment with methyl viologen. This tolerance was associated with the constitutive upregulation of PR1, PR2 (glucanase), PR5 (thaumatin like protein), ascorbate peroxidase (APX) and Cu²⁺/Zn²⁺ superoxide dismutase (SOD). This is the first demonstration of the novel function of heterologous expression of AtNPR1 in oxidative stress tolerance in transgenic tobacco.