Characterisation of the <Emphasis Type="Italic">Vitis vinifera</Emphasis>PR10 multigene family

Background  

Genes belonging to the pathogenesis related 10 (PR10) group have been studied in several plant species, where they form multigene families. Until now, such an analysis has not been performed in Vitis vinifera, although three different PR10 genes were found to be expressed under pathogen attack or abiotic stress, and during somatic embryogenesis induction. We used the complete genome sequence for characterising the whole V. vinifera PR10 gene family. The expression of candidate genes was studied in various non-treated tissues and following somatic embryogenesis induction by the auxin 2,4-D.     

转录因子WRKY6和PR1在拟南芥胁迫记忆中的表达模式

植物暴露在细菌或其它微生物病原体下,会形成全身防御,称为系统获得性抗性SAR（Systemic Acquired Resistance）,该系统可以在病原体二次侵染时有效抑制病原体对植物的伤害。其中,WRKY转录因子和病程相关蛋白PRs（Pathogenesis-related proteins）在植物抗病信号调控途径中起着重要作用。本研究以模式植物拟南芥为实验材料,对WRKY6和PR1（PATHOGENESIS RELATED）两个转录因子进行初步研究。首先,从拟南芥eFP数据库中获得WRKY6和PR1的基因表达数据,进行生物信息学分析,获得WRKY6和PR1基因在不同胁迫条件下的表达热图。其次,通过实时荧光定量PCR技术,比较了经过生物胁迫和非生物胁迫处理后WRKY6和PR1的基因表达水平。结果表明,拟南芥经过生物胁迫丁香假单胞菌[Pseudomonas syringae pv.tomato（P_st） DC3000]处理后,WRKY6和PR1的基因表达模式具有一定的相似性,然而经过非生物胁迫和机械损伤组合处理后,WRKY6和PR1基因又呈现出不同的表达模式。本研究初步探索了WRKY6和PR1基因的表达模式及其关系,为今后进一步研究系统性获得抗性应答机制提供了思路。     

Differential expression of ferritin genes in response to abiotic stresses and hormones in pear (<Emphasis Type="Italic">Pyrus pyrifolia</Emphasis>)

In this study, the expression patterns of four ferritin genes (PpFer1, PpFer2, PpFer3, and PpFer4) in pear were investigated using quantitative real-time PCR. Analysis of tissue-specific expression revealed higher expression level of these genes in leaves than in other tested tissues. These ferritin genes were differentially expressed in response to various abiotic stresses and hormones treatments. The expression of ferritin wasn’t affected by Fe(III)-citrate treatment. Abscisic acid significantly enhanced the expression of all four ferritin genes, especially PpFer2, followed by N-benzylyminopurine, gibberellic acid, and indole-3-acetic acid. The expression peaks of PpFer1 and PpFer3 in leaves appeared at 6, 6, and 12 h, respectively, after pear plant was exposed to oxidative stress (5 mM H₂O₂), salt stress (200 mM NaCl), and heat stress (40°C). A significant increase in PpFer4 expression was detected at 6 h after salt stress or heat stress. The expression of ferritin genes was not altered by cold stress. These results suggested that ferritin genes might be functionally important in acclimation of pear to salt and oxidative stresses. Hormone treatments had no significant effect on expression of ferritin genes compared to abiotic stresses. This showed accumulation of ferritin genes could be operated by different transduction pathways under abiotic stresses and hormones treatments.     

Activation of tomato PR and wound-related genes by a mutagenized tomato MAP kinase kinase through divergent pathways

A mitogen-activated protein kinase kinase (MAPKK) gene, tMEK2, was isolated from tomato cv. Bonny Best. By mutagenesis, a permanently active variant, tMEK2 ^MUT, was created. Both wild-type tMEK2 and mutant tMEK2 ^MUT were driven by a newly described strong plant constitutive promoter, tCUP, in a tomato protoplast transient gene expression system. Pathogenesis-related genes, PR1b1, PR3 and Twi1, and a wound-inducible gene, ER5, were activated by tMEK2^MUT. Specific inhibitors of p38 class MAPK inhibited tMEK2^MUT-induced activation of PR3 and ER5 genes but not that of the PR1b1 or Twi1 gene. Arabidopsis dual-specificity protein tyrosine phosphatase1 (DsPTP1) and maize protein phosphatase 1 (PP1) inhibited tMEK2^MUT-induced activation of the ER5 gene and the Twi1 gene, respectively, whereas PR1b1 and PR3 were not affected by either AtDsPTP1, or maize PP1, or Arabidopsis protein phosphatase 2A (PP2A). We have demonstrated for the first time that a single MAPKK activates an array of PR and wound-related genes. Our observation indicates that the activation of the genes downstream of tMEK2 occurs through divergent pathways and that tMEK2 may play an important role in the interaction of signal transduction pathways that mediate responses to both biotic (e.g. disease) and abiotic stresses (e.g. wound responsiveness).     

Cloning of Ten Peroxidase (<Emphasis Type="Italic">POD</Emphasis>) Genes from <Emphasis Type="Italic">Tamarix Hispida</Emphasis> and Characterization of their Responses to Abiotic Stress

Plant peroxidases (PODs) have been ascribed a variety of biological functions, including hydrogen peroxide detoxification, lignin biosynthesis, hormonal signaling, and stress response. In the present study, ten POD genes, including three ascorbate peroxidases (class I PODs) and seven secretory peroxidases (class III PODs), were cloned from Tamarix hispida. The roles of the ten POD genes were addressed under different abiotic stress conditions, and gene expression profiles in roots, stems, and leaves were evaluated using real-time quantitative reverse-transcribed polymerase chain reaction. Our results showed that the relative abundance of the PODs was markedly different in roots, stems, and leaves, indicating that POD activity differs in these three organs. ThPOD1 and ThPOD8 were the most and least abundant, respectively, in all organs. The expression profiles in response to abiotic stresses were organ specific. All of the genes were highly induced by drought, salt, salt–alkaline, CdCl₂, and abscisic acid (ABA) treatments in at least one organ. Five ThPOD genes were induced in roots, stems, and leaves under all of the studied stress conditions, indicating that they are closely associated with abiotic stress. Our results demonstrate that the ten plant peroxidases are all expressed in leaves, stems, and roots, that they are involved in different abiotic stress responses, and that they are controlled by an ABA-dependent stress signaling pathway.     

Interactive Effects of Abiotic Stress and Elevated CO2 on Physio-Chemical and Photosynthetic Responses in Suaeda Species

Suaeda fruticosa and S. monoica are important halophytes for ecological rehabilitation of saline lands. We report differential physio-chemical, photosynthetic, and chlorophyll fluorescence responses in these halophytes under 100 mM sodium chloride (NaCl), 50% strength (16.25 ppt) of seawater (SW)-imposed salinity, and 10% polyethylene glycol 6000 imposed osmotic stress at 380 (ambient) and 1200 (elevated) µmol mol^–1 CO₂ concentrations. SW salinity enhanced the growth in both species; however, compared with S. fruticosa, the S. monoica exhibited comparatively better growth and biomass accumulation under saline conditions at elevated CO₂. Results demonstrated better photosynthetic performances of S. monoica under stress conditions at both levels of CO₂, and this resulted in higher accumulation of carbon, nitrogen, sugar, and starch contents. S. monoica exhibited improved antenna size, electron transfer at PSII donor side, and efficient working of photosynthetic machinery at elevated CO₂, which might be due to efficient upstream utilization of reducing power to fix the CO₂. The δ¹³C results supported the operation of C₄ CO₂ fixation in S. monoica and C₃ or intermediate pathway of CO₂ fixation in S. fruticosa. Lower accumulation of reactive oxygen species, reduced membrane damage, lowered solute potential, and higher accumulation of proline and polyphenol contents indicated elevated CO₂-induced abiotic stress tolerance in Suaeda. Higher activity of antioxidant enzymes in both species at both levels of CO₂ help plants to combat the oxidative stress. Upregulation of NADP-dependent malic enzyme and NADP-dependent malate dehydrogenase genes indicated their role in abiotic stress tolerance as well as photosynthetic carbon (C) sequestration. Operation of C₄ type CO₂ fixation in S. monoica and an intermediate CO₂ fixation in S. fruticosa could be the possible reason for the superior photosynthetic efficiency of S. monoica under stress conditions at elevated CO₂.

     

水稻病程相关蛋白质在逆境胁迫下的表达研究

植物病程相关(PR)基因一般在病原物侵染过程中受诱导发生转录上调．目前有证据提示植物PR基因在非生物逆境胁迫下也发生转录变化,但其蛋白质的表达变化情况还鲜有报道．为了解水稻PR蛋白质在逆境胁迫下的表达特征,本文采用免疫印迹技术(Western blotting,WB)调查了8个PR蛋白质在冷、热、旱、淹和盐等5种胁迫下的表达谱．结果表明：在冷胁迫下PR8表达上调,在热胁迫下PR1a、PR3、PR5和PR16表达下调;在旱胁迫下PR1a、PR2和PR8表达上调,而PR5 和PR16表达下调,在淹胁迫下PR1、PR2和PR15表达上调,PR1a、PR3、PR5和PR8表达下调;在盐胁迫下PR2和PR3表达上调,而PR1a、PR5、PR8和PR16表达下调．另外,对这些PR 基因的上游启动子区进行分析,发现存在与胁迫响应相关的调控元件,其中脱落酸反应元件(ABRE)、TC-rich repeats和HSE的出现频率较高．这些蛋白质表达数据进一步佐证了PR蛋白在逆境胁迫反应中发挥着重要且不尽相同的作用．     

Responses of grass pea seedlings to salinity stress in in vitro culture conditions

Physiological and molecular mechanisms of adaptation to abiotic stresses of grass pea (Lathyrus sativus L.) are still poorly understood. Responses of four genotypes of grass pea to salinity stress in tissue culture conditions were investigated at early seedling growth stages. Salinity stress was induced in the agar media by adding 0, 50, 100 and 200 mM of NaCl. Germination and seedling emergence percentage was not significantly affected by 50 and 100 mM of NaCl. However, NaCl in 200 mM concentration lowered level of these parameters. Generally, exposure to NaCl stress significantly reduced length of grass pea seedling organs (root and shoot) but did not influence the content of dry weight in shoots and increased it in the roots in two cases. Increasing salt concentration decreased integrity of cellular membranes both in root and shoot tissues. Higher accumulation of phenolic compounds and significant changes in activity of antioxidant enzymes (peroxidase and catalase) were observed in the roots but not in the shoots. Similarly, the content of proline increased mostly in the roots from moderate (100 mM) salinity conditions. Adverse conditions did not resulted in alterations in photosynthetic pigments content of any tested genotypes. The better performance of shoots than roots may result from in vitro conditions in which experiments were conducted.

     

Role of Pathogen-Related Protein 10 (PR 10) under Abiotic and Biotic Stresses in Plants

Members of the Pathogenesis Related (PR) 10 protein family have been identified in a variety of plant species and a wide range of functions ranging from defense to growth and development has been attributed to them. PR10 protein possesses ribonuclease (RNase) activity, interacts with phytohormones, involved in hormone-mediated signalling, afforded protection against various phytopathogenic fungi, bacteria, and viruses particularly in response to biotic and abiotic stresses. The resistance mechanism of PR10 protein may include activation of defense signalling pathways through possible interacting proteins involved in mediating responses to pathogens, degradation of RNA of the invading pathogens. Moreover, several morphological changes have been shown to accompany the enhanced abiotic stress tolerance. In this review, the possible mechanism of action of PR10 protein against biotic and abiotic stress has been discussed. Furthermore, our findings also confirmed that the in vivo Nitric oxide (NO) is essential for most of environmental abiotic stresses and disease resistance against pathogen infection. The proper level of NO may be necessary and beneficial, not only in plant response to the environmental abiotic stress, but also to biotic stress. The updated information on this interesting group of proteins will be useful in future research to develop multiple stress tolerance in plants.     

A proper PiCAT2 level is critical for sporulation,sporangium function,and pathogenicity of Phytophthora infestans

Catalase is present in prokaryotic and eukaryotic organisms and is important for the protective effects of the antioxidant system against free radicals. Many studies have confirmed that catalase is required for the growth, development, and pathogenesis of bacteria, plants, animals, and fungi. However, there has been relatively little research on the catalases in oomycetes, which form an important group of fungus-like eukaryotes that produce zoosporangia. In this study, we detected two Phytophthora infestans genes encoding catalases, but only PiCAT2 exhibited catalase activity in the sporulation stage and was highly produced during asexual reproduction and in the late infection stage. Compared with the wild-type strain, the PiCAT2-silenced P. infestans transformants were more sensitive to abiotic stress, were less pathogenic, and had a lower colony expansion rate and lower PiMPK7, PiVPS1, and PiGPG1 expression levels. In contrast, the PiCAT2-overexpressed transformants were slightly less sensitive to abiotic stress. Interestingly, increasing and decreasing PiCAT2 expression from the normal level inhibited sporulation, germination, and infectivity, and down-regulated PiCdc14 expression, but up-regulated PiSDA1 expression. These results suggest that PiCAT2 is required for P. infestans mycelial growth, asexual reproduction, abiotic stress tolerance, and pathogenicity. However, a proper PiCAT2 level is critical for the formation and normal function of sporangia. Furthermore, PiCAT2 affects P. infestans sporangial formation and function, pathogenicity, and abiotic stress tolerance by regulating the expression of cell cycle-related genes (PiCdc14 and PiSDA1) and MAPK pathway genes. Our findings provide new insights into catalase functions in eukaryotic pathogens.