The glabra1 Mutation Affects Cuticle Formation and Plant Responses to Microbes

Systemic acquired resistance (SAR) is a form of defense that provides resistance against a broad spectrum of pathogens in plants. Previous work indicates a role for plastidial glycerolipid biosynthesis in SAR. Specifically, mutations in FATTY ACID DESATURASE7 (FAD7), which lead to reduced trienoic fatty acid levels and compromised plastidial lipid biosynthesis, have been associated with defective SAR. We show that the defective SAR in Arabidopsis (Arabidopsis thaliana) fad7-1 plants is not associated with a mutation in FAD7 but rather with a second-site mutation in GLABRA1 (GL1), a gene well known for its role in trichome formation. The compromised SAR in gl1 plants is associated with impairment in their cuticles. Furthermore, mutations in two other components of trichome development, GL3 and TRANSPARENT TESTA GLABRA1, also impaired cuticle development and SAR. This suggests an overlap in the biochemical pathways leading to cuticle and trichome development. Interestingly, exogenous application of gibberellic acid (GA) not only enhanced SAR in wild-type plants but also restored SAR in gl1 plants. In contrast to GA, the defense phytohoromes salicylic acid and jasmonic acid were unable to restore SAR in gl1 plants. GA application increased levels of cuticular components but not trichome formation on gl1 plants, thus implicating cuticle, but not trichomes, as an important component of SAR. Our findings question the prudence of using mutant backgrounds for genetic screens and underscore a need to reevaluate phenotypes previously studied in the gl1 background.Plants have evolved a large array of defense mechanisms to resist infection by pathogens. Upon recognition, the host plant initiates one or more signal transduction pathways that activate various plant defenses and thereby prevent pathogen colonization. In many cases, resistance is associated with increased expression of defense genes, including the pathogenesis-related (PR) genes and the accumulation of salicylic acid (SA) in the inoculated leaf. Induction of these responses is accompanied by localized cell death at the site of pathogen entry, which can often restrict the spread of pathogen to cells within and immediately surrounding the lesions. This phenomenon, known as the hypersensitive response, is one of the earliest visible manifestations of induced defense responses and resembles programmed cell death in animals (Dangl et al., 1996; Gray, 2002; Glazebrook, 2005; Kachroo and Kachroo, 2006). Concurrent with hypersensitive response development, defense reactions are triggered in sites both local and distal from the primary infection. This phenomenon, known as systemic acquired resistance (SAR), is accompanied by a local and systemic increase in SA and jasmonic acid (JA) and a concomitant up-regulation of a large set of defense genes (Durrant and Dong, 2004; Truman et al., 2007; Vlot et al., 2009).SAR involves the generation of a mobile signal in the primary leaves that, upon translocation to the distal tissues, activates defense responses resulting in broad-spectrum resistance. The production of the mobile signal takes places within 3 to 6 h of avirulent pathogen inoculation in the primary leaves (Smith-Becker et al., 1998), and the inoculated leaf must remain attached for at least 4 h after inoculation for immunity to be induced in the systemic tissues (Rasmussen et al., 1991). Mutations compromising SA synthesis or impairing SA, JA, or auxin signaling abolish SAR (Durrant and Dong, 2004; Truman et al., 2007, 2010). SAR is also dependent on the SALICYLIC ACID-BINDING PROTEIN2 (SABP2)-catalyzed conversion of methyl SA to SA in the distal tissues (Kumar and Klessig, 2003). Recent studies have suggested that methyl SA is the mobile signal required to initiate SAR in distal tissues in tobacco (Nicotiana tabacum; Park et al., 2007) and Arabidopsis (Arabidopsis thaliana; Liu et al., 2010), although another group reported a disparity in their findings related to the role of methyl SA in Arabidopsis (Attaran et al., 2009). Notably, the time point of requirement of SABP2 activity (between 48 and 72 h post inoculation; Park et al., 2009) does not coincide with the early generation and/or translocation of the mobile signal into distal tissues (within 6 h post inoculation).The mutations acyl carrier protein4 (acp4), long-chain acyl-CoA synthetase2 (lacs2), and lacs9, which are impaired in fatty acid (FA)/lipid flux (Schnurr et al., 2004; Xia et al., 2009), also compromise SAR (Xia et al., 2009). Detailed characterization has shown that the SAR defect in acp4, lacs2, and lacs9 mutants correlates with their defective cuticles. Analysis of the SAR response in acp4 plants has shown that these plants can generate the mobile signal required for inducing SAR but are unable to respond to it. It is likely that the defective cuticle in these plants impairs their ability to perceive the SAR signal, because mechanical abrasion of cuticles disrupts SAR in wild-type plants (Xia et al., 2009). This SAR-disruptive effect of cuticle abrasion is highly specific, because it does not alter local defenses and hinders SAR only during the time frame during which the mobile signal is translocated to distal tissues.SAR is also compromised in plants that contain a mutation in glycerol-3-phosphate dehydrogenase (Nandi et al., 2004). The glycerol-3-phosphate dehydrogenase (GLY1) reduces dihydroxyacetone phosphate to generate glycerol-3-phosphate, an obligatory component and precursor for the biosynthesis of all plant glycerolipids. Consequently, a mutation in GLY1 results in reduced carbon flux through the prokaryotic pathway of lipid biosynthesis, which leads to a reduction in the hexadecatrienoic (16:3) FAs (Miquel et al., 1998; Kachroo et al., 2004). Carbon flux and SAR are also impaired in plants containing mutations in FATTY ACID DESATURASE7 (FAD7; Chaturvedi et al., 2008). The FAD7 enzyme desaturates 16:2 and 18:2 FA species present on plastidial lipids to 16:3 and 18:3, respectively. Consequently, the fad7 mutant plants accumulate significantly reduced levels of trienoic FAs (16:3 and 18:3). Compromised SAR in mutants affected in certain plastidial FA/lipid pathways has prompted the suggestion that plastidial FA/lipids participate in SAR (Chaturvedi et al., 2008). Such a tempting conclusion is also favored by the fact that SAR requires the DIR1-encoded nonspecific lipid transfer protein, which is required for the generation and/or translocation of the mobile signal (Maldonado et al., 2002). In addition, azelaic acid, a dicarboxylic acid, was recently shown to prime SA biosynthesis and thereby SAR (Jung et al., 2009). The fact that azelaic acid is derived from oleic acid, a FA well known for its role in defense (Kachroo et al., 2003, 2004, 2005, 2007, 2008; Chandra-Shekara et al., 2007; Jiang et al., 2009; Venugopal et al., 2009; Xia et al., 2009), further suggests that FA/lipids might participate in SAR.This study was undertaken to reexamine the role of the FA/lipid pathways in SAR and to determine the nature of the FA/lipid species mediating SAR in fad7-1 plants. Our results show that impaired FA/lipid flux is not associated with compromised SAR in fad7-1 plants but, rather, with an abnormal cuticle, which is the result of a nonallelic mutation in the GLABRA1 (GL1) gene. Besides GL1, other mutations affecting trichome formation also compromised cuticle and thereby SAR. A compensatory effect of exogenous GA on gl1 plants suggests that GA might participate in resistance to bacterial pathogens by restoring cuticle formation.     

A mutational analysis and molecular dynamics simulation of quinolone resistance proteins QnrA1 and QnrC from <Emphasis Type="Italic">Proteus mirabilis</Emphasis>

Background  

The first report on the transferable, plasmid-mediated quinolone-resistance determinant qnrA1 was in 1998. Since then, qnr alleles have been discovered worldwide in clinical strains of Gram-negative bacilli. Qnr proteins confer quinolone resistance, and belong to the pentapeptide repeat protein (PRP) family. Several PRP crystal structures have been solved, but little is known about the functional significance of their structural arrangement.     

Proteome characterization of cassava (<Emphasis Type="Italic">Manihot esculenta</Emphasis> Crantz) somatic embryos,plantlets and tuberous roots

Background  

Proteomics is increasingly becoming an important tool for the study of many different aspects of plant functions, such as investigating the molecular processes underlying in plant physiology, development, differentiation and their interaction with the environments. To investigate the cassava (Manihot esculenta Crantz) proteome, we extracted proteins from somatic embryos, plantlets and tuberous roots of cultivar SC8 and separated them by sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE).     

A review of current large‐scale mouse knockout efforts

After the successful completion of the human genome project (HGP), biological research in the postgenome era urgently needs an efficient approach for functional analysis of genes. Utilization of knockout mouse models has been powerful for elucidating the function of genes as well as finding new therapeutic interventions for human diseases. Gene trapping and gene targeting are two independent techniques for making knockout mice from embryonic stem (ES) cells. Gene trapping is high‐throughput, random, and sequence‐tagged while gene targeting enables the knockout of specific genes. It has been about 20 years since the first gene targeting and gene trapping mice were generated. In recent years, new tools have emerged for both gene targeting and gene trapping, and organizations have been formed to knock out genes in the mouse genome using either of the two methods. The knockout mouse project (KOMP) and the international gene trap consortium (IGTC) were initiated to create convenient resources for scientific research worldwide and knock out all the mouse genes. Organizers of KOMP regard it as important as the HGP. Gene targeting methods have changed from conventional gene targeting to high‐throughput conditional gene targeting. The combined advantages of trapping and targeting elements are improving the gene trapping spectrum and gene targeting efficiency. As a newly‐developed insertional mutation system, transposons have some advantages over retrovirus in trapping genes. Emergence of the international knockout mouse consortium (IKMP) is the beginning of a global collaboration to systematically knock out all the genes in the mouse genome for functional genomic research. genesis 48:73–85, 2010. © 2010 Wiley‐Liss, Inc.     

Comparison of strong cation exchange and SDS-PAGE fractionation for analysis of multiprotein complexes

Affinity purification of protein complexes followed by identification using liquid chromatography/mass spectrometry (LC-MS/MS) is a robust method to study the fundamental process of protein interaction. Although affinity isolation reduces the complexity of the sample, fractionation prior to LC-MS/MS analysis is still necessary to maximize protein coverage. In this study, we compared the protein coverage obtained via LC-MS/MS analysis of protein complexes prefractionated using two commonly employed methods, SDS-PAGE and strong cation exchange chromatography (SCX). The two complexes analyzed focused on the nuclear proteins Bmi-1 and GATA3 that were expressed within the cells at low and high levels, respectively. Prefractionation of the complexes at the peptide level using SCX consistently resulted in the identification of approximately 3-fold more proteins compared to separation at the protein level using SDS-PAGE. The increase in the number of identified proteins was especially pronounced for the Bmi-1 complex, where the target protein was expressed at a low level. The data show that prefractionation of affinity isolated protein complexes using SCX prior to LC-MS/MS analysis significantly increases the number of identified proteins and individual protein coverage, particularly for target proteins expressed at low levels.     

植物类型III聚酮合酶超家族基因结构、功能及代谢产物

植物聚酮类化合物主要包括酚类、芪类及类黄酮化合物等,在植物花色、防止紫外线伤害、预防病原菌、昆虫危害以及作为植物与环境互作信号分子方面行使着重要的生物学功能。该类化合物具有显著多样的生物学活性,对人体保健及疾病治疗有显著意义。植物类型III 聚酮化合物合酶 (PKS) 在该类化合物生物合成起始反应中行使着关键作用,决定该类化合物基本分子骨架建成和代谢途径碳硫走向,为合成途径关键酶和限速酶。以查尔酮合酶为原型酶的植物类型III PKS超家族是研究系统进化和蛋白结构与功能关系的模式分子家族,目前已经分离得到14种植物类型III PKS基因,这些同祖同源基因及其表达产物既有共性,也表现出许多独特个性,这些个性赋予此类次生代谢产物结构上的多样性。以下综述了植物类型III PKS超家族基因结构、功能及代谢产物研究进展。     

PHD finger protein 8蛋白多克隆抗体的制备、纯化与检测

PHD finger8(PHF8)蛋白是最新发现的一种带有PHD结构域和Jmjc结构域的蛋白。现有研究表明其可能在基因转录、组蛋白去甲基化等方面发挥重要作用。为研究其功能,本研究构建原核表达载体pET41b-PHF8(aa886-936),在大肠杆菌Escherichia coli BL21中诱导表达带有GST标签的PHF8(aa886-936)亲水片段融合蛋白,并纯化该片段作为抗原免疫家兔,再以CNBr活化Sepharose4B微珠纯化抗血清制备PHF8特异性多克隆抗体。Western blotting以及免疫荧光检测表明该抗体具有很好的特异性,同时免疫荧光染色的结果也表明PHF8蛋白定位于细胞核。     

不同pH调节剂对产琥珀酸放线杆菌NJ113发酵产丁二酸的影响

在3L发酵罐中分别采用不同的碱性物质作为pH调节剂,考察其对产琥珀酸放线杆菌Actinobacillus succinogenes NJ113厌氧发酵制备丁二酸的影响。结果表明:Ca2+、NH4+调节剂对菌体生长代谢有较大阻碍作用,丁二酸产量较低;采用含Na+调节剂,在发酵中后期菌体出现絮凝现象严重,且产丁二酸能力骤降;采用含Mg2+调节剂,整个发酵过程菌体代谢旺盛,发酵效果较佳。根据各碱性物质的调节能力以及对菌体生长代谢的影响,选择NaOH、Mg(OH)2和Na2CO3、Mg(OH)2分别作为混合碱组分调节pH,并对两组混合碱中各物质的质量比例进行优化。结果表明,以NaOH、Mg(OH)2混合,两者质量比为1:1时,发酵效果最好,丁二酸质量浓度高达到69.8g/L,质量收率74.5%。该种混合碱配比可有效替代碱式MgCO3调节pH,既达到高产丁二酸的目的,又可降低生物制备丁二酸的成本。