Systemic acquired resistance, NPR1, and pathogenesis-related genes in wheat and barley

In Arabidopsis, systemic acquired resistance （SAR） is established beyond the initial infection by a pathogen or is directly induced by treatment with salicylic acid （SA） or its functional analogs, 2,6-dichloroisonicotinic acid （INA） and benzothiadiazole （BTH）. NPR1 protein is considered the master regulator of SAR in both SA signal sensing and transduction. In wheat （Triticum aesfivum） and barley （Hordeum vulgare）, both pathogen infection and BTH treatment can induce broad-spectrum resistance to various diseases, including powdery mildew, leaf rust, Fusarium head blight, etc. However, three different types of SAR-like responses including acquired resistance （AR）, systemic immunity （SI）, and BTH-induced resistance （BIR） seem to be achieved by activating different gene pathways. Recent research on wheat and barley NPR1 homologs in AR and SI has provided the initial clue for understanding the mechanism of SAR in these two plant species. In this review, the specific features ofAR, Si, and BIR in wheat and barley were summarized and compared with that of SAR in model plants of Arabidopsis and rice. Research updates on downstream genes of SAR, including pathogenesis-related （PR） and BTH-induced genes, were highlighted.

Cloning and Characterization of a Pathogenesis-Related Protein Gene TaPR10 from Wheat Induced by Stripe Rust Pathogen

Pathogenesis-related proteins （PRs） play many important roles in plant defense response against pathogen attack. To better understand the molecular mechanism of PR genes involved in wheat adult plant resistance （APR） to stripe rust, based on a differentially expressed transcribed derived fragment （TDF）, a novel PR gene from wheat cv. Xingzi 9104 infected by the Puccinia striiformis Westend f. sp. tritici Erikss. pathotype CY32, which was highly similar to the maize ZmPRIO gene and designated as TaPRIO, was identified using in silico cloning and RT-PCR method. This novel TaPRIO gene was predicted to encode a 160-amino acid protein with a deduced molecular weight of 17.06 kDa and an isoelectronic point （pI） of 5.19. An amino acid sequence analysis of TaPR10 demonstrated the presence of a typical conserved domain of pathogenesis related protein Bet v I family. Multiple alignment analysis based on the amino acids encoded by 10 different PRIO genes from maize （Zea mays）, rice （Oryza sativa）, broomcorn （Sorghum bicolor）, and wheat （Triticum aestivum） indicated that PR proteins of class 10 was conserved among the 4 plant species with about 80% similarity. DNA sequence of TaPRIO suggested the presence of one 84-bp intron with the splicing sites of GT-AT bi-nucleotide sequence between 188 and 271 bp. Using a real-time quantitative RT-PCR （qRT-PCR）, expression profiles of TaPRIO revealed that at the adult-plant stage, TaPRIO transcript was up-regulated as early as 12 h post-inoculation （hpi）, with the occurrence of maximum induction at 24 hpi. At the seedling stage, TaPRIO was also slightly induced 18 hpi. However, the transcript amount was relatively lower than that of the adult-plant stage. Taken together, these results suggest that TaPRIO may participate in wheat defense response of APR to stripe rust.

Expression Comparisons of Pathogenesis-Related(PR) Genes in Wheat in Response to Infection/Infestation by Fusarium, Yellow dwarf virus(YDV) Aphid-Transmitted and Hessian Fly

Expression profiles of ten pathogenesis-related （PR） genes during plant defense against Fusarium, Yellow dwarf virus （YDV） aphid-transmitted and Hessian fly （Hf） were compared temporally in both resistant and susceptible genotypes following pathogen infection or insect infestation. Quantitative real-time PCR （qRT-PCR） revealed that PR1, PR2, PR3, PR5, PR6, PR8, PR9, and PR15 appeared to be induced or suppressed independently in response to Fusarium, YDV aphid-transmitted or Hf during the interactions. The PR gene（s） essential to defense against one organism may play little or no role in defense against another pathogen or pest, suggesting the alternative mechanisms may be involved in different interactions of wheat- Fusarium, wheat-YDV aphid-transmitted and wheat-Hf. However, strong up- or down-regulation of PRl2 and PR14 encoding low molecular membrane acting protein, defensin and lipid transfer protein （LTP）, respectively, had been detected after either pathogen infection or insect infestation, therefore showed broad responses to pathogens and insects. It was postulated that low molecular proteins such as defensins and LTPs might play a role in the early stages of pathogenesis in the signaling process that informs plants about the attack from biotic stresses. In addition, a synergistic action between different PR genes might exist in plants to defense certain pathogens and insects on the basis of comprehensive expression profiling of various pathogenesis-related genes revealed by qRT-PCR in this study.

The Influence of Co-Suppressing Tomato 1-Aminocyclopropane-1-Carboxylic Acid OxidaseⅠon the Expression of Fruit Ripening-Related and Pathogenesis-Related Protein Genes

The purpose of this study is to explore the influence of co-suppressing tomato ACC oxidase Ⅰ on the expression of fruit ripening-related and pathogenesis-related protein genes, and on the biosynthesis of endogenous ethylene and storage ability of fruits. Specific fragments of several fruit ripening-related and pathogenesis-related protein genes from tomato （Lycopersicon esculentum） were cloned, such as the l-aminocyclopropane-1-carboxylic acid oxidase 1 gene （LeAC01）, 1- aminocyclopropane-l-carboxylic acid oxidase 3 gene （LeAC03）, EIN3-binding F-box 1 gene （LeEBF1）, pathogenesis-related protein 1 gene （LePR1）, pathogenesis-related protein 5 gene （LePR5）, and pathogenesis-related protein osmotin precursor gene （LeNP24） by PCR or RT-PCR. Then these specific DNA fragments were used as probes to hybridize with the total RNAs extracted from the wild type tomato Ailsa Craig （AC＋＋） and the LeAC01 co-suppression tomatoes （V1187 and T4B）, respectively. At the same time, ethylene production measurement and storage experiment of tomato fruits were carded out. The hybridization results indicated that the expression of fruit ripening-related genes such as LeACO3 and LeEBF1, and pathogenesis-related protein genes such as LePR1, LePR5, and LeNP24, were reduced sharply, and the ethylene production in the fruits, wounded leaves decreased and the storage time of ripening fruits was prolonged, when the expression of LeACO1 gene in the transgenic tomato was suppressed. In the co-suppression tomatoes, the expression of fruit ripening-related and pathogenesis-related protein genes were restrained at different degrees, the biosynthesis of endogenous ethylene decreased and the storage ability of tomato fruits increased.

猕猴桃病程相关蛋白PR-1基因的克隆和功能分析

【目的】探究猕猴桃病程相关蛋白(pathogenesis-related proteins,PRs)PR-1基因在响应丁香假单胞杆菌中的功能。【方法】以毛花猕猴桃(Actinidia eriantha)为材料,克隆得到PR-1同源基因AePR-1全长序列,并对其序列进行生物信息学分析。采用实时荧光定量方法检测AePR-1基因在不同组织、花器官以及接种细菌性溃疡病菌(Psa)和不同激素(SA、ABA、GA_(3))处理条件下的表达情况。利用亚细胞定位技术分析AePR-1基因在细胞中的表达位置。通过在本氏烟草中过表达AePR-1基因,验证其在溃疡病菌响应过程中的功能。【结果】猕猴桃AePR-1基因序列全长522 bp,编码173个氨基酸,序列中含有6个保守的半胱氨酸结构基序和4个allergen V5/Tpx-1 related保守结构域。亚细胞定位发现AePR-1定位在细胞膜和细胞质中。AePR-1在猕猴桃根和雌蕊中高表达,且能够响应溃疡病菌及激素处理。过表达AePR-1的烟草在接种溃疡病菌后,叶片病斑数明显少于对照组。【结论】AePR-1基因在溃疡病菌和激素诱导下显著表达且过表达能够增强烟草对溃疡病的抗性,说明猕猴桃PR-1基因在响应生物和非生物胁迫中具有重要作用。

Cloning of Broad-spectrum Anti-disease NPR1 Gene with RT-PCR and Construction of Its Protein Expression Vector

[Objective] It is to clone broad-spectrum anti-disease gene NPR1 and to construct its protein expression vector.[Method] First to extract total RNA of Arabidopsis thaliana and design relevant primers,and then the method of reverse transcription PCR was adopted to clone.With the method of enzyme digestion and ligation,this gene will be directed into protein expression vector.[Result] After relevant testing,NPR1 was inserted into vector pMXB10 to obtain pMXB10-NPR1 protein expression vector.[Conclusion] Protein expression vector including NPR1 was successfully constructed.

Analysis of Codon Usage Pattern of Banana Basic Secretory Protease Gene

[Objective] The objective of this study was to understand the codon usage bias pattern of banana pathogenesis-related 17 gene, Basic Secretory Protease gene(MaBSP). [Method] Relative codon usage patterns of MaBSP were calculated using the software CodonW version 1.4.2. and the web-based tool(http://kazusa.or.jp/codon/).[Result] Our findings showed that C-ended and G-ended codons were the most preferential except the TER codon UGA which was coded for by just one codon. The ENc value, relationship between AT bias and GC bias, Random synonymous codon usage(RSCU) and CAI all showed that codon bias usage existed in MaBSP gene.[Conclusion] The codon usage patterns of MaBSP gene is principally influenced by natural selection in the third position. However, other multiple factors also influence this pattern.

Characterization of NPR1 Genes from Norton and Cabernet Sauvignon Grapevine

Non-expressor of pathogenesis-related genes 1 （NPR1） plays a significant role in the defense responses of plants to pathogens by regulating the expression of defense-related genes. In the present study, we isolated two NPR1 genes from Vitis aestivalis cv. Norton and Vitis vinifera cv. Cabernet Sauvignon, which were referred to as VaNPR1.1 and VvNPR1. 1-CS, respectively. They encode a protein of 584 amino acids with a predicted molecular weight of 64.8 kDa and a theoretical isoelectric point （pI） of 5.74. The predicted amino acid sequences of VaNPR1.1 and VvNPR1.1-CS differ by only one amino acid. Over-expression of VaNPR1.1 gene in Arabidopsis npr1-1 mutant plants restores the transcriptional expression of AtPR-1 gene, though not to the full scale. This result demonstrated that a grapevine VaNPR1.1 possesses a similar function to the Arabidopsis NPR1 in the regulation of defense-related genes. Over-expression of VaNPR1.1 in transgenic Arabidopsis plant increased tolerance to salinity, but had no effect on the drought tolerance. We conclude that VaNPR1.1 is a functional ortholog of AtNPR1 and also involved in grapevine＇s response to the salt stress.

Bioinformatics Analysis of Disease Resistance Gene PR1 and Its Genetic Transformation in Soybeans and Cultivation of Multi-resistant Materials

In agricultural production,a single insect-resistant and disease-resistant variety can no longer meet the demand.In this study,the expression vector pCAMBIA-3301-PR1 containing the disease-resistant gene PR1 was constructed by means of genetic engineering,and the PR1 gene was genetically transformed to contain the PR1 gene through the pollen tube method.In CryAb-8Like transgenic high-generation T7 receptor soybean,a new material that is resistant to insects and diseases is obtained.For T2 transformed plants,routine PCR detection,Southern Blot hybridization,fluorescence quantitative PCR detection,indoor and outdoor pest resistance identification and indoor disease resistance identification were performed.The results showed that there were 9 positive plants in the routine PCR test of T2 generation.In Southern Blot hybridization,both PR1 and CryAb-8Like genes are integrated in soybeans in the form of single copies.Fluorescence quantitative PCR showed that the expression levels of PR1 and CryAb-8Like genes are different in different tissues.The average expression levels of PR1 gene in plant roots,stems,and leaves are 2.88,1.54,and 5.26,respectively.CryAb-8Like genes are found in roots,stems,and leaves.The average expression levels were 1.36,1.39,and 4.25,respectively.The insectivorous rate of the CryAb-8Like gene in outdoor plants with positive insect resistance identification was 3.78%.The disc partition method was used indoors for pest resistance identification,and the bud length of transformed plants increased significantly.The average mortality rate of untransformed plants in indoor disease resistance identification was as high as 56.66%,and the average mortality rate of plants transformed with PR1 gene was 10.00%,and disease resistance was significantly improved.Therefore,a new material with resistance to diseases and insects is obtained.

Presence of Virulence-Associated Genes and Ability to Form Biofilm among Clinical Isolates of <i>Escherichia coli</i>Causing Urinary Infection in Domestic Animals

Background: Urinary tract infection caused by Escherichia coli is a frequently observed condition both in humans and animals. Uropathogenic E. coli (UPEC) has been shown to have a pathogenicity island that enables them to infect the urinary tract. Because there is little information about the presence of UPEC-associated virulent genes in animal isolates this work was carried out with the intent to enhance the understanding about the strains of E.coli that cause infections in animals. Results: We screened 21 E. coli strains isolated causing urinary tract infection in domestic animals. Primers were designed to amplify urinary infection-associated genes. Nine genes, papA, tcpC, fyuA, tpbA, Lma, hylA, picU, tonB, and flicC were then amplified and sequenced. Different from the human isolate CFT073, all the animals E. coli lack some of the pathogenesis-associated genes. Genes encoding for proteins used to scavenge iron appear not to be so necessary during animal infections as they are in human infection. In further investigation of phenotypic properties, it was observed that animal UPECs have significantly more impaired ability to form biofilms than human UPEC strain. Conclusions: This study identified significant differences between human and animal UPECs. This may have its roots in the fact that it is difficult to determine if an animal has symptoms. Future studies will focus on some of the observations.

GmSKP1,a Novel S-phase Kinase-associated Protein 1 in Glycine max,Enhancing Resistance Against Phytophthora sojae Infection

Phytophthora root and stem rot of soybean caused by Phytophthora sojae(P.sojae)is a devastating disease that affects soybean[Glycine max(L.)Merr.]all over the world.S-phase kinase-associated protein 1(SKP1)proteins are key members of the SKP1/Cullin/F-box protein(SCF)ubiquitin ligase complex and play diverse roles in plant biology.However,the role of SKP1 in soybean against the phytopathogenic oomycete P.sojae remains unclear.In this study,a novel member of the soybean SKP1 gene family,GmSKP1 which was significantly induced by P.sojae,was reported.The expression of GmSKP1 was simultaneously induced by methyl jasmonate(MeJA),salicylic acid(SA)and ethylene(ET),which might suggest an important role for GmSKP1 of plant in responses to hormone treatments.Functional analysis using GmSKP1 overexpression lines showed that GmSKP1 enhanced resistance to P.sojae in transgenic soybean plants.Further analyses showed that GmSKP1 interacted with a homeodomain-leucine zipper protein transcription factor(GmHDL56)and a WRKY transcription factor(GmWRKY31),which could positively regulate responses to P.sojae in soybean.Importantly,several pathogenesis-related(PR)genes were constitutively activated,including GmPR1a,GmPR2,GmPR3,GmPR4,GmPR5a and GmPR10,in GmSKP1-OE soybean plants.Taken together,these results suggested that GmSKP1 enhanced resistance to P.sojae in soybean,possibly by activating the defense-related PR genes.

番茄PR-1和PR-5基因的表达特性分析

分别克隆番茄PR-1和PR-5基因片段,并以之制备探针,采用Northern blot方法研究了PR-1和PR-5基因在正常生长条件下番茄根、茎、叶、果实发育中的表达模式,研究了干旱、复水和内外源乙烯对这两种基因表达的影响.结果表明:这两个基因主要在衰老叶片、B期果实和根部表达,干旱抑制了这两个基因的表达,复水和乙烯诱导其表达.

拟南芥NPR1基因的克隆与表达载体的构建

NPR1基因为植物抗病基因表达和系统获得性抗性中的一个关键基因。该文以DNA PCR扩增的方法,从拟南芥基因组DNA中克隆出NPR1基因,通过序列分析,所克隆的 NPR1 基因与报道的基因序列完全一致。将其构建成植物表达载体,为今后植物抗病基因工程的开展奠定了基础。

大豆GmPR10基因克隆与植物表达载体的构建

为探明大豆中PR10蛋白质基因的抗大豆花叶病毒(SMV)作用机理,从抗SMV材料中克隆到GmPR10基因完整的cDNA序列,GmPR10基因的开放阅读框(ORF)全长477 bp,编码158个氨基酸。序列比对与进化树分析结果表明:GmPR10是大豆中一个新的PR10蛋白质基因,GmPR10基因在大豆的根、茎、叶中均能表达,接种大豆SMV后该基因在大豆叶片中被强烈诱导并高效表达,推测其可能使植物本身获得系统抗性以抵抗外来病原菌的侵袭。该研究构建了GmPR10基因的植物表达载体,为探究GmPR10基因在大豆抗病中的分子作用机理打下了基础。

水稻纹枯病发病过程PR1和PBZ1的表达动态

采用从福建省稻田分离纯化的纹枯病菌(Rhizoctonia so lani)菌株FJ-15接种籼稻9311,分析了水稻在纹枯病菌侵染致病过程中,编码病程相关蛋白的基因表达动态,并观察了症状的变化。Northern b lot分析表明:PR1在接种12 h后开始表达,在之后的4个时间段其表达量逐步增强;而PBZ1也在12 h开始表达,在48 h表达量激剧增强几乎与72 h表达量相当。组织和症状观察表明,接种12 h后叶鞘表面菌丝纵横分枝,接种36 h后出现零星病斑,接种48 h后表现典型的受害症状,接种72 h后病斑继续扩大,并可蔓延到非接种叶鞘。结果表明,PR1和PBZ1的表达与水稻和纹枯病菌亲和互作的过程存在对应关系。

c-erbB-2、ER、PR在乳腺癌中的表达及其临床意义

目的探讨c-erbB-2、雌激素受体(ER)、孕激素受体(PR)在乳腺癌中的表达及其临床意义。方法采用免疫组化方法检测54例乳腺癌患者中c-erbB-2、ER、PR的表达,并分析其与临床的关系。结果54例乳腺癌中,ER、PR、c-erbB-2的阳性表达率分别为48.2%(26/54)、53.7%(29/54)、72.2%(39/54)。ER、PR的阳性表达率与患者年龄、有无淋巴结转移及组织学类型的差异无统计学意义(P>0.05);c-erbB-2阳性表达率与有无淋巴结转移的差异有统计学意义(P<0.05),与患者年龄、肿瘤体积及组织学类型的差异无统计学意义(P>0.05);ER、PR与c-erbB-2表达一致率为46.3%(25/54),表达不一致率为27.8%(15/54),ER、PR表达与c-erbB-2表达无显著相关性(P>0.05)。结论c-erbB-2的阳性表达是乳腺癌患者预后差的指标,联合检测ER、PR更有助于乳腺癌患者临床疗效和预后的判断。

谷氨酰胺对断奶仔猪抗菌肽PR-39 mRNA的表达调控

本文旨在探讨谷氨酰胺(Gln)对断奶仔猪抗菌肽PR-39 mRNA表达的影响。选取64头胎次相同、28日龄断奶、体重(7.50±0.67)kg的三元杂交仔猪(杜×长×大),随机分为2个组,即基础日粮对照组和1.0%Gln添加组,每组设4个重复,每个重复8头猪(公母各1/2)。于试验第28天,进行细胞因子白细胞介素-1β(IL-1β)、白细胞介素-6(IL-6)和肿瘤坏死因子(TNF-α)含量的分析。于第30天,采用半定量RT-PCR研究日粮中添加Gln对PR-39 mRNA的影响。试验结果表明:Gln添加显著提高仔猪血清中IL-1β含量(P<0.05),但对血清IL-6和TNF-α及空肠黏膜TNF-α、IL-2无显著影响(P>0.05);显著促使骨髓、空肠黏膜中PR-39 mRNA的表达(P<0.05),与对照组相比,骨髓和空肠黏膜中PR-39 mRNA分别提高50.5%(P<0.05)和24.0%(P<0.05)。由结果可知,断奶仔猪日粮中添加Gln能显著促使骨髓及空肠黏膜PR-39 mRNA表达上调。

Her-2,nm23,ER和PR在老年女性乳腺癌中的表达及意义

目的研究老年女性乳腺癌中Her-2,nm23,ER和PR的表达及意义。方法用免疫组化法测定108例老年女性原发乳腺癌各抗体的表达情况。结果Her-2,nm23,ER和PR的阳性率分别为48.1%(52/108)、68.5%(74/108)、57.4%(62/108)和55.6%(60/108),Her-2随淋巴结转移数目的增多,其阳性表达率随之增加。ER阳性表达率随淋巴结转移数目的增多而降低。nm23的表达与淋巴结有无转移有关,转移组较无转移组阳性率明显下降,nm23的表达与临床分期相关有统计学意义。结论Her-2、ER、nm23与淋巴结转移有关,可以作为判断老年女性乳腺癌淋巴结转移和评估预后的有效指标。

小麦PR-1、PR-2、PR-5基因的白粉菌和水杨酸诱导表达分析及白粉病抗性研究(英文)

病程相关蛋白基因PR-1、PR-2和PR-5是植物抗病基因介导的抗病反应和系统获得抗性(systemic acquired resistance,SAR)中的标志基因。为了研究病程相关蛋白基因和水杨酸在小麦(TriticumaestivumL.)抗白粉病反应中所起的作用,以抗白粉病和感白粉病小麦品系为材料,在白粉病菌(Blumeria graminisf.sp.tritici,Bgt)诱导不同时间,或水杨酸处理不同时间后,用半定量RT-PCR技术检测了小麦叶片中PR-1、PR-2和PR-5基因的表达变化。结果表明,白粉病菌的侵染激活和显著增强了病程相关蛋白基因PR-1、PR-2和PR-5在周麦18中的转录。与感病品系相比,PR-1和PR-5在抗病品系中转录激活得更快、更强。水杨酸处理显著激活了PR-1和PR-5的转录,但对PR-2的转录影响不大。白粉病菌和水杨酸均能显著激活和增强PR-1和PR-5的表达,但白粉病菌的作用更强,说明PR-1和PR-5基因在小麦抗白粉病反应中起重要作用。PR-1和PR-5可以作为小麦SAR的标志基因。水杨酸处理后周麦18和中国春的白粉病抗性得到提高,提示水杨酸在小麦抗白粉病信号传导途径中起一定作用。

环境胁迫和乙烯对番茄PR-NP24基因表达的影响

根据已报道的番茄PR-NP24基因序列设计引物,经PCR克隆出长为477bp的番茄PR-NP24基因片段,以该片段制备探针,采用Northern杂交技术对该基因在番茄(WT)和乙烯反应突变体番茄(Nr,rin,T4B-11)中的表达进行了研究.杂交结果表明,该基因主要在果实和根部表达,伤害抑制WT、Nr番茄叶片中该基因的表达,而对rin番茄叶片无明显影响;干旱、淹水等环境胁迫和乙烯均能不同程度地诱导其表达,而在不同温度下,PR-NP24基因表达变化不大.