Expression of the nuclear encoded OEE1 protein is required for oxygen evolution and stability of photosystem II particles in Chlamydomonas reinhardtii.

In Chlamydomonas reinhardtii the oxygen evolving enhancer protein 1 (OEE1), which is part of the oxygen evolving complex of photosystem II (PS II), is coded for by a single nuclear gene (psb1). The nuclear mutant FuD44 specifically lacks the OEE1 polypeptide and is completely deficient in photosynthetic oxygen evolution. In this mutant a 5 kb DNA insertion into the 5' region of the psb1 gene results in the complete absence of OEE1 mRNA and protein. A revertant, FuD44-R 2, which is capable of 30% of the photosynthetic oxygen evolution of wild-type cells, has lost 4 kb of the 5 kb DNA insert, and accumulates both OEE1 mRNA and protein, although at levels somewhat less than those of wild-type cells. Absence of the OEE1 protein in the FuD44 mutant does not affect the accumulation of other nuclear encoded PS II peripheral polypeptides. OEE1 absence does, however, result in a more rapid turnover of the chloroplast encoded PS II core polypeptides, thus resulting in a substantial deficiency of PS II core polypeptides in FuD44 cells. These PS II core proteins again accumulate in revertant FuD44-R2 cells.     

Putative involvement of Thioredoxin h in early response to gravitropic stimulation of poplar stems

Gravity perception and gravitropic response are essential for plant development. In herbaceous species, it is widely accepted that one of the primary events in gravity perception involves the displacement of amyloplasts within specialized cells. However, the early signaling events leading to stem reorientation are not fully known, especially in woody species in which primary and secondary growth occur. Thirty-six percent of the identified proteins that were differentially expressed after gravistimulation were established as potential Thioredoxin targets. In addition, Thioredoxin h expression was induced following gravistimulation. In situ immunolocalization indicated that Thioredoxin h protein co-localized with the amyloplasts located in the endodermal cells. These investigations suggest the involvement of Thioredoxin h in the first events of signal transduction in inclined poplar stems, leading to reaction wood formation.     

A proteomic approach to analyze salt-responsive proteins in rice leaf sheath

To examine the response of rice to salt stress, changes in protein expression were analyzed using a proteomic approach. To investigate dose- and time-dependent responses, rice seedlings were exposed to 50, 100 and 150 mM NaCl for 6 to 48 h. Proteins were extracted from leaf sheath and separated by two-dimensional polyacrylamide gel electrophoresis. Eight proteins showed 1- to 3-fold up-regulation in leaf sheath, in response to 50 mM NaCl for 24 h. Among these, three proteins were unidentified (LSY081, LSY262 and LSY363) while five proteins were identified as fructose bisphosphate aldolases, photosystem II (PSII) oxygen evolving complex protein, oxygen evolving enhancer protein 2 (OEE2) and superoxide dismutase (SOD). The maximum expression levels of seven proteins were at 24 h. Their expression declined after 48 h of 50 mM NaCl treatment. In contrast, SOD maintained its elevated expression throughout these conditions. The increased expression of proteins seen in the 50 mM NaCl treatment group was less pronounced in the groups receiving 100 or 150 mM NaCl for 24 h. The expression of SOD was a common response to cold, drought, salt and abscisic acid (ABA) stresses while the expression of LSY081, LSY363 and OEE2 was enhanced by salt and ABA stresses. LSY262 was expressed in leaf sheath and root, while fructose bisphosphate aldolases, PSII oxygen evolving complex protein and OEE2 were expressed in leaf sheath and leaf blade. LSY363 was expressed in leaf sheath but was below the level of detection in leaf blade and root. These results indicate that specific proteins expressed in specific regions of rice show a coordinated response to salt stress.     

Proteomic Analysis of the Relationship between Metabolism and Nonhost Resistance in Soybean Exposed to Bipolaris maydis

Nonhost resistance (NHR) pertains to the most common form of plant resistance against pathogenic microorganisms of other species. Bipolaris maydis is a non-adapted pathogen affecting soybeans, particularly of maize/soybean intercropping systems. However, no experimental evidence has described the immune response of soybeans against B. maydis. To elucidate the molecular mechanism underlying NHR in soybeans, proteomics analysis based on two-dimensional polyacrylamide gel electrophoresis (2-DE) was performed to identify proteins involved in the soybean response to B. maydis. The spread of B. maydis spores across soybean leaves induced NHR throughout the plant, which mobilized almost all organelles and various metabolic processes in response to B. maydis. Some enzymes, including ribulose-1,5-bisphosphate carboxylase/oxygenase (RuBisCO), mitochondrial processing peptidase (MPP), oxygen evolving enhancer (OEE), and nucleoside diphosphate kinase (NDKs), were found to be related to NHR in soybeans. These enzymes have been identified in previous studies, and STRING analysis showed that most of the protein functions related to major metabolic processes were induced as a response to B. maydis, which suggested an array of complex interactions between soybeans and B. maydis. These findings suggest a systematic NHR against non-adapted pathogens in soybeans. This response was characterized by an overlap between metabolic processes and response to stimulus. Several metabolic processes provide the soybean with innate immunity to the non-adapted pathogen, B. maydis. This research investigation on NHR in soybeans may foster a better understanding of plant innate immunity, as well as the interactions between plant and non-adapted pathogens in intercropping systems.     

Remodeling of chloroplast proteome under salinity affects salt tolerance of <Emphasis Type="Italic">Festuca arundinacea</Emphasis>

Acclimation of photosynthetic apparatus to variable environmental conditions is an important component of tolerance to dehydration stresses, including salinity. The present study deals with the research on alterations in chloroplast proteome of the forage grasses. Based on chlorophyll fluorescence parameters, two genotypes of a model grass species—Festuca arundinacea with distinct levels of salinity tolerance: low salt tolerant (LST) and high salt tolerant (HST), were selected. Next, two-dimensional electrophoresis and mass spectrometry were applied under both control and salt stress conditions to identify proteins accumulated differentially between these two genotypes. The physiological analysis revealed that under NaCl treatment the studied plants differed in photosystem II activity, water content, and ion accumulation. The differentially accumulated proteins included ATPase B, ATP synthase, ribulose-1,5-bisphosphate carboxylase large and small subunits, cytochrome b6-f complex iron-sulfur subunit, oxygen-evolving enhancer proteins (OEE), OEE1 and OEE2, plastidic fructose-bisphosphate aldolase (pFBA), and lipocalin. A higher level of lipocalin, potentially involved in prevention of lipid peroxidation under stress, was also observed in the HST genotype. Our physiological and proteomic results performed for the first time on the species of forage grasses clearly showed that chloroplast metabolism adjustment could be a crucial factor in developing salinity tolerance.     

植物盐胁迫应答蛋白质组学分析

土壤盐渍化是限制植物生长和分布的关键因素之一,揭示植物盐胁迫应答的分子机理是借助分子生物学手段提高植物耐盐性的基础.近年来,人们利用高通量蛋白质组学技术分析了拟南芥、水稻等19种植物的盐胁迫应答蛋白质表达图谱.从植物类群(盐生植物和甜土植物)、组织器官(根、地上部分/茎、胚根和胚轴、叶片、花序和配子体)、细胞(悬浮培养细胞、愈伤组织细胞和单细胞生物)和亚细胞结构(叶绿体、质膜和质外体)几方面整合分析了植物盐胁迫应答蛋白质组表达模式特征,主要特征包括:(1)盐生植物通过全面调节细胞骨架重塑、离子转运和区隔化、渗透平衡、活性氧(ROS)清除、信号转导、光合作用和能量代谢等信号与代谢网络体系,获得相对较高的抗/耐盐能力;(2)植物地上部分(叶片、茎、配子体)或光合组织细胞(悬浮培养细胞、愈伤组织细胞和单细胞盐藻)通过调节参与光合作用、碳和能量代谢、ROS清除过程蛋白质的表达模式应对盐胁迫环境;(3)植物地下部分(根、胚根)通过调控信号转导和离子转运相关蛋白质感知/传递盐胁迫信号并维持离子平衡;(4)花序中参与渗透调节、转录调控、蛋白质加工和ROS清除的蛋白质在盐胁迫条件下变化显著;(5)叶绿体通过调控参与光合作用、蛋白质加工和周转,以及氧化还原系统平衡等过程应对盐胁迫;(6)质外体中参与细胞壁代谢、胁迫防御和信号转导过程的蛋白质受盐胁迫影响明显;(7)细胞膜中参与维持膜结构稳定、物质/离子运输和信号转导过程的蛋白质对植物盐胁迫应答具有重要作用.这些分析为深入研究植物耐盐的分子机制提供了重要信息.     

Analysis of the genes of the OEE1 and OEE3 proteins of the photosystem II complex from Chlamydomonas reinhardtii

The sequences of the nuclear genes of the 33 kDa (OEE1) and the 16 kDa (OEE3) polypeptides of the oxygen evolving complex of Chlamydomonas reinhardtii have been established. Comparison between the OEE1 protein sequences of C. reinhardtii and higher plants and cyanobacteria reveals 67 and 47% homology. In contrast, C. reinhardtii and higher plants have only 28% overall homology for OEE3 which is mostly limited to the central portion of the protein. The transit peptides of the C. reinhardtii proteins consist of 52 (OEE1) and, most likely, 51 (OEE1) amino acids. They have a basic amino terminal region and, at least in the case of OEE1, a hydrophobic segment at their carboxy terminal end typical of thylakoid lumen proteins. Comparison of the genomic and cDNA clones indicates that the OEE1 and OEE3 genes contain five and four introns, respectively, some of which are located within the coding sequences of the transit peptides.     

Characterization and expression of cytoplasmic copper/zinc superoxide dismutase (CuZn SOD) gene under temperature and hydrogen peroxide (H2O2) in rotifer Brachionus calyciflorus

Superoxide dismutase (SOD, EC 1.15.1.1) is an important antioxidant enzyme that protects organs from damage by reactive oxygen species (ROS). We cloned cDNA encoding SOD activated with copper/zinc (CuZn SOD) from the rotifer Brachionus calyciflorus Pallas. The full-length cDNA of CuZn SOD was 692 bp and had a 465 bp open reading frame encoding 154 amino acids. The deduced amino acid sequence of B. calyciflorus CuZn SOD showed 63.87%, 60.00%, 59.74% and 48.89% similarity with the CuZn SOD of the Ctenopharyn godonidella, Schistosoma japonicum, Drosophila melanogaster and Caenorhabditis elegans, respectively. The phylogenetic tree constructed based on the amino acid sequences of CuZn SODs from B. calyciflorus and other organisms revealed that rotifer is closely related to nematode. Analysis of the expression of CuZn SOD under different temperatures (15, 30 and 37 °C) revealed that its expression was enhanced 4.2-fold (p < 0.001) at 30 °C after 2 h, however, the lower temperature (15 °C) promoted CuZn SOD transiently (4.1-fold, p < 0.001) and then the expression of CuZn SOD decreased to normal level (p > 0.05). When exposed to H₂O₂ (0.1 mM), CuZn SOD, manganese superoxide dismutase (Mn SOD) and catalase (CAT) gene were upregulated, and in addition, the mRNA expression of CuZn SOD gene was induced instantaneously after exposure to vitamin E. It indicates that the CuZn SOD gene would be an important gene in response to oxidative and temperature stress.     

The Pleiades are a cluster of fungal effectors that inhibit host defenses

Biotrophic plant pathogens secrete effector proteins to manipulate the host physiology. Effectors suppress defenses and induce an environment favorable to disease development. Sequence-based prediction of effector function is impeded by their rapid evolution rate. In the maize pathogen Ustilago maydis, effector-coding genes frequently organize in clusters. Here we describe the functional characterization of the pleiades, a cluster of ten effector genes, by analyzing the micro- and macroscopic phenotype of the cluster deletion and expressing these proteins in planta. Deletion of the pleiades leads to strongly impaired virulence and accumulation of reactive oxygen species (ROS) in infected tissue. Eight of the Pleiades suppress the production of ROS upon perception of pathogen associated molecular patterns (PAMPs). Although functionally redundant, the Pleiades target different host components. The paralogs Taygeta1 and Merope1 suppress ROS production in either the cytoplasm or nucleus, respectively. Merope1 targets and promotes the auto-ubiquitination activity of RFI2, a conserved family of E3 ligases that regulates the production of PAMP-triggered ROS burst in plants.     

Oxygen and reactive oxygen species-dependent regulation of plant growth and development

Oxygen and reactive oxygen species (ROS) have been co-opted during evolution into the regulation of plant growth, development, and differentiation. ROS and oxidative signals arising from metabolism or phytohormone-mediated processes control almost every aspect of plant development from seed and bud dormancy, liberation of meristematic cells from the quiescent state, root and shoot growth, and architecture, to flowering and seed production. Moreover, the phytochrome and phytohormone-dependent transmissions of ROS waves are central to the systemic whole plant signaling pathways that integrate root and shoot growth. The sensing of oxygen availability through the PROTEOLYSIS 6 (PRT6) N-degron pathway functions alongside ROS production and signaling but how these pathways interact in developing organs remains poorly understood. Considerable progress has been made in our understanding of the nature of hydrogen peroxide sensors and the role of thiol-dependent signaling networks in the transmission of ROS signals. Reduction/oxidation (redox) changes in the glutathione (GSH) pool, glutaredoxins (GRXs), and thioredoxins (TRXs) are important in the control of growth mediated by phytohormone pathways. Although, it is clear that the redox states of proteins involved in plant growth and development are controlled by the NAD(P)H thioredoxin reductase (NTR)/TRX and reduced GSH/GRX systems of the cytosol, chloroplasts, mitochondria, and nucleus, we have only scratched the surface of this multilayered control and how redox-regulated processes interact with other cell signaling systems.

Oxygen and reactive oxygen species regulate plant growth, development, and differentiation through multiple interlinked signaling pathways.

Advances

• Developmentally regulated hypoxia and reactive oxygen species (ROS) production are key features of the stem cell niches, providing information about stem cell position, the environment, and metabolic state.
• Protein cysteine oxidation is central to oxygen and ROS signaling. However, S-nitrosylation, S-glutathionylation, S-sulfhydration, and S-sulfenylation modifications can occur on the same cysteine. The influence of each modification on stability, localization, and function remains unknown.
• Numerous intersecting ROS signaling pathways are probable and likely depend on the site of ROS production and the nature of the oxidized receptor protein. ROS sensors such as the hydrogen peroxide (H₂O₂)-INDUCED Ca²⁺ INCREASES 1 (HPCA1) leucine rich receptor kinase translate redox signals into protein modifications to regulate signaling cascades. H₂O₂ perception/transduction is dependent on thiol-dependent mechanisms policed by the ferredoxin/thioredoxin (TRX), NAD(P)H TRX reductase C (NTRC), reduced glutathione (GSH), and glutaredoxin (GRX) systems.
• ROS waves transmit redox signals from cell to cell in the apoplast, and probably through plasmodesmata. Long-distance transport of H₂O₂ and other ROS, therefore, appears to be unnecessary. Similarly, contact sites between organelles allow ROS transfer.
• Convergence points for oxygen and ROS signaling occur on proteins such as ROH OF PLANT 2 (ROP2) GTPase,RESPIRATORY BURST OXIDASE HOMOLOG D (RBOHD), and TRX-h to regulate meristematic activity via TARGET OF RAPAMYCIN (TOR) kinase activity.

     

A key role for mitochondria in endothelial signaling by plasma cysteine/cystine redox potential

The redox potential of the plasma cysteine/cystine couple (E_hCySS) is oxidized in association with risk factors for cardiovascular disease (CVD), including age, smoking, type 2 diabetes, obesity, and alcohol abuse. Previous in vitro findings support a cause–effect relationship for extracellular E_hCySS in cell signaling pathways associated with CVD, including those controlling monocyte adhesion to endothelial cells. In this study, we provide evidence that mitochondria are a major source of reactive oxygen species (ROS) in the signaling response to a more oxidized extracellular E_hCySS. This increase in ROS was blocked by overexpression of mitochondrial thioredoxin-2 (Trx2) in endothelial cells from Trx2-transgenic mice, suggesting that mitochondrial thiol antioxidant status plays a key role in this redox signaling mechanism. Mass spectrometry-based redox proteomics showed that several classes of plasma membrane and cytoskeletal proteins involved in inflammation responded to this redox switch, including vascular cell adhesion molecule, integrins, actin, and several Ras family GTPases. Together, the data show that the proinflammatory effects of oxidized plasma E_hCySS are due to a mitochondrial signaling pathway that is mediated through redox control of downstream effector proteins.     

活性氧在气孔运动中的作用

水分代谢是植物基础代谢的重要组成部分,气孔开关精细地调节着植物水分散失和光合作用。气孔运动受到多种因子的调控,保卫细胞内大量的第二信使分子是响应外界刺激、调节保卫细胞代谢方式、改变保卫细胞水势进而引起气孔开关的重要功能组分。细胞内的活性氧就是其中重要的成员之一。保卫细胞中的活性氧包括过氧化氢、超氧阴离子自由基和羟自由基等,这些活性氧可以通过光合作用、呼吸作用产生或通过专门的酶催化合成,在触发下游生理反应、完成信号转导后由专门的酶将其清除。在植物激素(脱落酸、水杨酸)、一氧化氮、质外体钙调素、细胞外ATP等因子调节气孔运动的过程中,活性氧都发挥了介导作用。该文对于近年来活性氧在气孔运动过程中发挥的作用方面的研究进展进行了综述。     

Comparative proteomics of high light stress in the model alga Chlamydomonas reinhardtii

High light (HL) stress adversely affects growth, productivity and viability of photosynthetic organisms. The green alga Chlamydomonas reinhardtii is a model system to study photosynthesis and light stress. Comparative proteomics of wild-type and two very high light (VHL)-resistant mutants, VHL(R)-S4 and VHL(R)-S9, revealed complex alterations in response to excess light. A two-dimensional reference map of the soluble subproteome was constructed representing about 1500 proteins. A total of 83 proteins from various metabolic pathways were identified by peptide mass fingerprinting. Quantitative comparisons of 444 proteins showed 105 significantly changed proteins between wild type and mutants under different light conditions. Commonly, more proteins were decreased than increased, but different proteins were affected in each genotype. Proteins uniquely altered in either VHL(R) mutant may be involved in VHL resistance. Such candidate proteins similarly altered without light stress, thus possibly contributing to "pre-adaptation" of mutants to VHL, included decreased levels of a DEAD box RNA helicase (VHL(R)-S4) and NAB1 and RB38 proteins (VHL(R)-S9), and increased levels of an oxygen evolving enhancer 1 (OEE1) isoform and an unknown protein (VHL(R)-S4). Changes from increased levels in HL to decreased levels in excess light, included OEE1 (VHL(R)-S9) or the reverse change for NAB1, RB38, beta-carbonic anhydrase and an ABC transporter-like protein (VHL(R)-S4).     

二色补血草OEE2基因的克隆和表达

从二色补血草中分离出一条含有完整开放读码框（ORF）序列的OEE2基因。该基因全长994bp,其中5’非翻译区27bp,3’非翻译区160bp,ORF全长807bp,共编码264个氨基酸,编码蛋白的分子量为28．2kDa,理论上的等电点为7．66。BlastP分析表叽二色补血草OEE2与马铃薯OEE2序列同源性最高,与喇叭水仙OEE2序列同源性最低,从9个物种的氨基酸多序列比对中可以看出,OEE2的氨基酸序列保守性较高。实时定量RT．PCR方法检测该基因对低温、NaCl和聚乙二醇（PEG）胁迫的基因表达模式的结果表明,PEG和低温能诱导OEE2基因在二色补血草叶中表达,这两种处理的OEE2基因表达量于胁迫48h后都达到高峰,而在NaCl胁迫下OEE2在二色补血草根和叶中表达都受抑制。     

Role of mitochondria in reactive oxygen species generation and removal; relevance to signaling and programmed cell death

Reactive oxygen species (ROS) are universal products of aerobic metabolism, which can be also produced in stress conditions. In eukaryotic cells, mitochondria are the main source of ROS. The main mitochondrial sites of ROS formation are electron carriers of respiratory chain. However, there are also other enzymatic sites capable of ROS generation in different mitochondrial compartments. Reactive oxygen species can cause serious damage to many biological macromolecules, such as proteins, lipids and nucleic acids, which oxidation leads to a lost of their biological properties and eventually to a cell death. Mitochondria, which are also exposed to harmful ROS action, have a defense system that decreases ROS production (first line of defense) or removes generated ROS (second line of defense). Mitochondrial antioxidant system involves proteins that decrease ROS formation, enzymes that directly react with ROS, and non-enzymatic antioxidants that also remove ROS and other oxygen derivatives. Mitochondrial ROS can also act as signal messengers and modify operation of many routes in different cell compartments. Mitochondrial ROS are also important in execution of programmed cell death.