Isolation of an osmotin-like protein gene from strawberry and analysis of the response of this gene to abiotic stresses

A strawberry genomic clone containing an osmotin-like protein (OLP) gene, designated FaOLP2, was isolated and sequenced. FaOLP2 is predicted to encode a precursor protein of 229 amino acid residues, and its sequence shares high degrees of homology with a number of other OLPs. Genomic DNA hybridization analysis indicated that FaOLP2 represents a multi-gene family. The expression of FaOP2 in different strawberry organs was analyzed using real-time PCR. The results showed that FaOLP2 expressed at different levels in leaves, crowns, roots, green fruits and ripe red fruits. In addition, the expression of FaOLP2 under different abiotic stresses was analyzed at different time points. All of the three tested abiotic stimuli, abscisic acid, salicylic acid and mechanical wounding, triggered a significant induction of FaOLP2 within 2-6h post-treatment. Moreover, FaOLP2 was more prominently induced by salicylic acid than by abscisic acid or mechanical wounding. The positive responses of FaOLP2 to the three abiotic stimuli suggested that strawberry FaOLP2 may help to protect against osmotic-related environmental stresses and that it may also be involved in plant defense system against pathogens.     

Expression analysis of the two ferrochelatase genes in Arabidopsis in different tissues and under stress conditions reveals their different roles in haem biosynthesis

The Arabidopsis thaliana genome has two genes (AtFC-I and AtFC-II), encoding ferrochelatase, the terminal enzyme of haem biosynthesis. The roles of the two enzymes in the synthesis of haem for different haemoproteins was investigated using reporter gene analysis. A 1.41 kb fragment from the 5' upstream region of the AtFC-II gene was fused to the luciferase gene, and then introduced into tobacco plants, followed by luciferase activity measurements. AtFC-II-LUCwas expressed in all aerial parts of the plant, and was highest in flowers, but it was not expressed in roots. It was unaffected by viral infection, and considerably reduced by wounding or oxidative stress. Similarly, a 1.76 kb region of the AtFC-I promoter was fused to the uidAgene encoding -glucuronidase. AtFC-I-GUS was expressed in all tissues of the plant, but was higher in roots and flowers than in leaves or stems. It was induced by sucrose, wounding and oxidative stress and, most markedly, by plants undergoing the hypersensitive response to TMV infection. Levels of endogenous ferrochelatase activity were increased in pea chloroplasts isolated from wounded leaves, indicating that the induction in promoter activity is likely to result in increased haem biosynthetic potential. Salicylic acid, but not methyl-jasmonate was able to replace the stress treatment in induction of AtFC-I expression, suggesting that the requirement for haem synthesis is part of the defence response. The implications of the results for the different roles of the two ferrochelatases in haem biosynthesis are discussed.     

Two<Emphasis Type="Italic"> Brassica napus</Emphasis> polygalacturonase inhibitory protein genes are expressed at different levels in response to biotic and abiotic stresses

Plants encode a distinct set of polygalacturonase inhibitory proteins (PGIPs) that function to inhibit polygalacturonase enzymes produced by soft-rot fungal pathogens. We characterized two PGIP-encoding genes ( Bnpgip1 and Bnpgip2) from Brassica napus DH12075 (a double-haploid line derived from a cross between 'Crésor' and 'Westar'). The two proteins exhibit 67.4% identity at the amino acid level and contain 10 imperfect leucine-rich repeats. The pgip genes are present as a small multigene family in B. napus with at least four members. Bnpgip1 and Bnpgip2 are constitutively expressed in roots, stems, flower buds and open flowers. In mature leaf tissue, different levels of induction were observed in response to biotic and abiotic stresses. Bnpgip1 expression was highly responsive to flea beetle feeding and mechanical wounding, weakly responsive to Sclerotinia sclerotiorum infection and exposure to cold but not to dehydration. Conversely, Bnpgip2 expression was strongly induced by S. sclerotiorum infection and to a lesser degree by wounding but not by flea beetle feeding. Application of jasmonic acid to leaves induced both Bnpgip1 and Bnpgip2 gene expression; however, salicylic acid did not activate either gene. Taken together, these results suggest that separate pathways regulate Bnpgip1 and Bnpgip2, and that their roles in plant development or resistance to biotic and abiotic stress differ.     

Tissue specific and inducible expression of resveratrol synthase gene in peanut plants.

The expression of resveratrol synthase (RS) genes is induced by biotic and abiotic factors in peanut cell cultures. However, little is known about the regulation of the RS gene expression in peanut plants. The expression of RS genes was investigated in peanut plants with a peanut RS clone, pPRS3C, which encodes two polypeptides that show about a 96% amino acid sequence identity to peanut RS2 and RS3, respectively. A low level of RS mRNA was detected in the roots of peanut plants grown aseptically in vitro. In mature peanut plants that were grown in the field, however, RS mRNAs were present at relatively high levels in both the roots and pods, but at below the detection limit in leaves. RS mRNAs were abundant in young pods and decreased dramatically in mature pods. The RS mRNA expression was induced by yeast extract and UV in leaves and roots, and also by wounding in leaves. Stress hormones, such as ethylene, jasmonic acid, and salicylic acid, induced RS mRNA accumulation in leaves. These results indicate that the RS gene expression is induced by biotic and abiotic stresses through the stress hormones in peanut plants. The induction of the RS gene expression by biotic and abiotic stresses could provide peanut plants with protection from microbial infections through resveratrol synthesis. The RS gene expression in developing pods has significant implications in terms of the role of resveratrol as a phytochemical for human health.     

拟南芥AtJ2和AtJ3基因表达对环境胁迫的响应

用PCR的方法获得AtJ2和AtJ3基因的3'非编码区的核甘酸片段作为探针,Northern杂交结果表明:AtJ2和AtJ3基因在植物的根、茎、叶、花蕾、花和长角果中都有表达,并在植物整个生长周期中都有表达,但随着植株的衰老表达量有所下降.不同环境胁迫的实验结果表明:热激使AtJ2和AtJ3基因的表达迅速升高;冷胁迫也能诱导这两个基因表达的明显增加,但需要的时间比热激要长得多,达9 h;水分胁迫能引起AtJ2和AtJ3基因表达量的微弱增加;可盐胁迫对AtJ2和AtJ3基因的表达没有影响.说明AtJ2和AtJ3基因可能参与对除盐胁迫以外多种环境刺激的响应.     

Transgenic cucumber fruits that produce elevated level of an anti-aging superoxide dismutase

Superoxide dismutase (SOD) plays an important role in cellular defense against oxidative stress in aerobic organisms. To generate cucumber (Cucumis sativus L.) fruits producing high yields of SOD for an anti-aging cosmetic material as a plant bioreactor, the CuZnSOD cDNA (mSOD1) from cassava was introduced into cucumber fruits by Agrobacterium-mediated transformation using the ascorbate oxidase promoter with high expression in fruits. The bialaphos-resistant shoots were selected on medium containing MS basal salts, 2 mg l^–1 BA, 0.1 mg l^–1 IAA, 300 mg l^–1 claforan, and 2 mg l^–1 bialaphos. After 6 weeks of culture on the selection medium, the shoots were transferred to MS medium containing 1 mg l^–1 IAA, 300 mg l^–1 claforan, 2 mg l^–1 bialaphos to induce roots. Southern blot analysis confirmed that the mSOD1 gene was properly integrated into the nuclear genomes of three cucumber plants tested. The mSOD1 gene was highly expressed in the transgenic cucumber fruits, whereas it was expressed at a low level in the transgenic leaves. The SOD specific activity (units/mg protein) in transgenic fruits was approximately 3 times higher than in those of non-transgenic plants.     

Comparative expression profiles of maize genes from a water stress-specific cDNA macroarray in response to high-salinity, cold or abscisic acid

cDNA macroarray has become a useful tool to analyze expression profiles and compare the similarities and differences of various expression patterns. We have prepared a cDNA macroarray containing 190 maize expressed sequence tags (ESTs) specifically induced by water stress to analyze the expression profiles of maize seedlings under abscisic acid (ABA) treatment, high-salinity and cold stress conditions. The results indicated that 48 ESTs in leaves and 111 ESTs in roots were significantly up-regulated by ABA treatment, 36 ESTs in leaves and 41 ESTs in roots by high-salinity stress, 14 ESTs in leaves and 18 ESTs in roots by cold induction, whereas 22 ESTs were induced under all 3 stresses. Results from the hierarchical cluster analysis suggest that the leaves and roots of maize seedlings had different expression profiles after these stresses. The overlap analysis of different stress-induced ESTs indicated that there is more crosstalk between water stress and ABA and high-salinity stress than between water stress and cold stress. It will be helpful to study the precise function of the corresponding overlapping-induced genes for understanding the relationship and crosstalk between different stress signal pathways.     

Drought, salt and wounding stress induce the expression of the plasma membrane intrinsic protein 1 gene in poplar (Populus alba×P. tremula var. glandulosa)

Water uptake across cell membranes is a principal requirement for plant growth at both the cellular and whole-plant levels; water movement through plant membranes is regulated by aquaporins (AQPs) or major intrinsic proteins (MIPs). We examined the expression characteristics of the poplar plasma membrane intrinsic protein 1 gene (PatPIP1), a type of MIP, which was isolated from a suspension cell cDNA library of Populus alba×P. tremula var. glandulosa. Examination of protoplasts expressing the p35S-PatPIP1::sGFP fusion protein revealed that the protein was localized in the plasma membrane. Northern blot analysis revealed that the gene was strongly expressed in poplar roots and leaves. Gene expression was inducible by abiotic factors including drought, salinity, cold temperatures and wounding, and also by plant hormones including gibberellic acid, jasmonic acid and salicylic acid. Since we found that the PatPIP1 gene was strongly expressed in response to mannitol, NaCl, jasmonic acid and wounding, we propose that PatPIP1 plays an essential role in the defense of plants against water stress.     

Expression of asparagine synthetase genes in sunflower (Helianthus annuus) under various environmental stresses.

In sunflower, asparagine synthetase (AS; EC 6.3.5.4) is encoded by a small family of three genes (HAS1, HAS1.1 and HAS2) that are differentially regulated by light, carbon and nitrogen availability. In this study, the response of each gene to various stress conditions was examined by Northern analysis with gene-specific probes in leaves and roots. The expression of HAS1 and HAS1.1 genes was induced by osmotic stress (300 mM mannitol), salt stress (150 mM NaCl), and heavy-metal stress (20 microM CuSO(4)), more in roots than in leaves. The expression of HAS2 was not significantly altered by stress treatments. The positive response of HAS1 and HAS1.1 genes to osmotic and salt stresses occurred in the light, in contrast to that previously found in unstressed plants. Measurements of sucrose and total free amino acid contents in leaves and roots indicate that the expression of root HAS1 and HAS1.1 genes in stressed plants is not under metabolic control by the intracellular C/N ratio, suggesting the involvement of some specific stress factor(s). Growth of plants at 40 degrees C for 12h negatively affected the expression of HAS1 and HAS1.1 but not that of HAS2.     

Molecular cloning of a cytosolic ascorbate peroxidase cDNA from cell cultures of sweetpotato and its expression in response to stress

A cDNA encoding a cytosolic ascorbate peroxidase (APX), swAPX1 , was isolated from cell cultures of sweetpotato (Ipomoea batatas) by cDNA library screening, and its expression in the context of various environmental stresses was investigated. swAPX1 contains an ORF of 250 amino acids (27.5 kDa) encoding a protein with a pI value of 5.32. The swAPX1 ORF does not code for a transit peptide, suggesting that the product is a cytosolic isoform. RNA blot analysis showed that swAPX1 gene is expressed in cultured cells and mature leaves, but not in stems, non-storage or storage roots of sweetpotato. The level of swAPX1 RNA progressively increased during cell growth in suspension cultures. In leaf tissues, the gene responded differentially to various abiotic stresses, as revealed by RT-PCR analysis. swAPX1 was highly induced in leaves by wounding, and treatment with methyl viologen (50 M), hydrogen peroxide (440 mM), abscisic acid (ABA; 100 M) or exposure to high temperature (37°C). In addition, the gene was strongly induced in the leaves following inoculation with a bacterial pathogen (Pectobacterium chrysanthemi). These results indicate that swAPX1 may be involved in hydrogen peroxide-detoxification and thus help to overcome the oxidative stress induced by abiotic and biotic stresses.Communicated by G. Jürgens     

5个毛果杨PtrZFP基因的鉴定和表达分析

ZFP转录因子是植物中的一类具有指环结构域的转录因子。从毛果杨中鉴定出5条ZFP基因（命名为PtrZFP1-5）,对其特性和表达模式进行了分析,以期初步了解这些基因是否能对胁迫做出应答。对PtrZFP1-5基因进行生物学分析,进一步利用qRT-PCR技术分析NaCl、PEG₆₀₀₀和ABA胁迫处理后毛果杨根、茎和叶中5条基因的表达情况。PtrZFP1-5基因编码蛋白氨基酸残基数为258~338 aa,编码蛋白的分子量为27.7~37.3 kDa,理论等电点为4.87~8.61,5个基因不均等的分布在毛果杨基因组的3条染色体上。qRT-PCR结果显示,0.2 mol·L^-1 NaCl、15%（w/v）PEG6000和100 μmol·L^-1 ABA胁迫处理后,5个PtrZFP基因在毛果杨根、茎和叶中的表达模式明显不同。PtrZFP1基因在3种胁迫后毛果杨中均被明显的上调表达;PtrZFP2基因在盐、渗透和ABA胁迫处理后,叶中的表达都明显被抑制;PtrZFP3基因受到干旱胁迫时在根中的响应最为明显;而叶和茎中,表达量在大部分胁迫的大部分时间点无明显改变。PtrZFP4基因也能在根和茎中对干旱胁迫做出明显应答。PtrZFP5基因在经受盐和ABA胁迫后,在叶中的表达受到明显抑制。PtrZFP1-5这5个基因至少能在一种器官中对一种胁迫处理做出应答,但参与的胁迫应答类型和机制可能不同。     

木薯MeMYC2.2基因耐低温功能研究

MYC2（MYeloCytomatosis）转录因子是植物应对逆境胁迫过程中茉莉酸信号传导相关的核心转录因子。本研究旨在初步分析木薯MeMYC2.2基因在低温胁迫响应中的功能。利用生物信息学分析木薯MeMYC2.1和MeMYC2.2基因的结构及其编码蛋白的理化性质;通过定量PCR分析了上述2个基因在木薯组培苗叶片中对低温胁迫的响应;通过转基因拟南芥研究MeMYC2.2的抗冻功能。木薯组培苗叶片中2个MeMYC2基因的表达均在低温胁迫早期被诱导,其中,与MeMYC2.1相比,MeMYC2.2差异表达更显著。MeMYC2.2蛋白主要定位于细胞核中,且在酵母中具有明显转录自激活功能,表明该蛋白具有转录因子特性。与野生型相比,过表达MeMYC2.2的转基因拟南芥抗冻能力显著提高。在低温处理下,CBF3基因在转基因拟南芥中的表达量要明显高于其在野生型的表达量,但另外3个CBF基因在转基因拟南芥中的表达量明显下降。木薯MeMYC2.2的表达受低温和茉莉酸调控,可以提高植物的抗冻性,且可能影响CBF基因对低温的响应。本研究为进一步利用MeMYC2基因改良木薯的低温耐受性奠定了理论基础。