基于蛋白质组学对螺旋藻在高温胁迫下响应机制的初步研究

本实验以螺旋藻为材料,通过i TRAQ对螺旋藻细胞在高温胁迫下的全蛋白进行定量分析。结果表明:40oC是螺旋藻可恢复的最大耐受胁迫温度,并在此温度胁迫条件下启动响应机制。差异表达蛋白的筛选结果确定了18 523个独特的肽和2 085个蛋白质,此外,在Uni Prot KB/Swiss-Prot数据库中注释了142种独特的蛋白质。GO功能注释中,共有207条蛋白序列被793条GO功能条目注释,平均GO层次为6.545。KEGG通路注释中,检测到呈现显著差异性表达的注释蛋白117个,涉及光合作用、能量代谢、RNA的转录和翻译等方面。荧光定量PCR结果显示,测序结果与i TRAQ实验相一致,光合系统I P700叶绿素脱辅基蛋白A1、果糖1,6-二磷酸酶、核酮糖二磷酸羧化酶大侧链、光合系统I反应中心亚基XI下调;顺反异构酶、热激蛋白70、热激蛋白90、磷酸甘油酸激酶、二磷酸核苷酸激酶上调。由此可知,螺旋藻经高温胁迫后,与光合作用和遗传信息相关的蛋白是影响螺旋藻热应激的关键。     

杜仲叶片干旱胁迫响应相关差异蛋白的筛选与鉴定

为研究干旱胁迫下杜仲幼苗生理生化及分子响应机制,利用盆栽试验,通过持续（3、6、9、12、15 d）干旱胁迫处理和复水处理,研究杜仲幼苗的生理响应特性。同时,通过研究对照与处理15 d后的杜仲幼苗差异蛋白质组,分析杜仲幼苗对干旱胁迫的分子响应机制。结果表明,随着干旱处理时间的延长,杜仲叶片的水分饱和亏逐渐增加;光合速率、蒸腾速率、胞间二氧化碳浓度、气孔导度均逐渐减小;SOD、POD、CAT活性呈先上升后降低的趋势;丙二醛含量则呈现先上升,然后下降,最后又上升的变化特点;脯氨酸和可溶性糖含量的变化趋势与SOD等活性变化一致,前期上升,后期下降。在复水后,杜仲叶片的所有指标均有所恢复,但未达到干旱处理之前的水平。表明干旱胁迫影响了杜仲叶片的正常生长代谢。通过对干旱处理15 d后杜仲叶片总蛋白进行双向电泳分离和MALDI-TOF-TOF生物质谱鉴定,成功鉴定出36个差异表达蛋白,其中22个上调表达,14个下调表达。对36个差异蛋白进行功能分析发现,这些差异蛋白主要涉及信号传导、光合作用、碳代谢、能量代谢、次级代谢物合成、抗氧化保护酶、氨基酸代谢和蛋白质代谢。推测杜仲为适应干旱胁迫,首先是感应干旱胁迫信号,并传导至细胞内,影响杜仲叶片中光合作用、次级代谢物合成和蛋白质的生物合成;同时,通过过氧化物保护酶的作用,将过多活性氧加以清除;另一方面,则是通过增强糖酵解,磷酸戊糖途径,产生能量供杜仲正常生长所需。从生理机制来看,杜仲叶片同过增加胞内脯氨酸、可溶性糖含量,降低胞内渗透势,减少叶片中水分损失,与氨基酸合成和糖代谢相关蛋白的表达量上升的结果一致。     

水胁迫下沙漠小球藻蛋白质组学分析

通过研究小球藻(Chlorella sp.)在干旱胁迫下的蛋白质组变化,从蛋白质表达水平解释小球藻对干旱胁迫的响应机理。以20%的PEG 6000胁迫处理0、6、12、18、24和30 d,提取小球藻总蛋白,利用双向电泳和质谱鉴定技术分析差异蛋白。共鉴定29个差异蛋白,按功能可分为7类:光合作用、能量合成和转化、物质代谢、抗氧化、转运和细胞结构、抗逆和功能未知蛋白质。这些蛋白的表达变化影响着沙漠小球藻的油脂积累,对干旱胁迫应答起到了至关重要的作用,并直接或间接地参与了沙漠小球藻细胞内的光合作用和油脂合成。     

乙醇胁迫抑制毕赤酵母表达外源蛋白的转录组学分析

在5 L发酵罐中进行毕赤酵母发酵表达猪?干扰素的实验,发现甘油培养末期乙醇的积累会抑制外源蛋白的表达。从转录组学角度系统分析不同浓度乙醇胁迫条件下,毕赤酵母甘油培养期和甲醇诱导期细胞的生理状态变化。研究结果表明,在甘油培养期,乙醇胁迫使得毕赤酵母细胞中的545个基因发生了显著差异表达(265个基因表达上调,280个基因表达下调),这些差异表达基因的功能主要涉及蛋白质合成、能量代谢、细胞周期和过氧化物酶代谢。乙醇胁迫增加了蛋白质错误折叠的情况,降低了核糖体和线粒体的结构完整性,使得甘油培养末期无法得到大量具有健全功能的酵母细胞。在甲醇诱导期,与甲醇代谢、蛋白质加工合成、氨基酸代谢等途径相关的294个基因发生了显著差异表达(171个基因表达上调,123个基因表达下调),导致内质网胁迫不能被及时解除,破坏了细胞内的氨基酸正常代谢。     

螺旋藻对增强的UV-B胁迫的响应

本文研究了实验室条件下增强的uv-B（280-320nm）胁迫对一种蓝藻一钝顶螺旋藻（Spirulina platensis）794生物量、色素和蛋白、细胞内MDA含量及活性氧产生的影响。结果表明,在增强的uV-B胁迫下,螺旋藻的生物量减少,细胞内叶绿素a和类胡萝卜素含量降低,从而使螺旋藻的生长发育受到一定程度的抑制,而细胞浆蛋白质含量增加,这可能是螺旋藻对逆境胁迫的一种适应性反应。增强UV-B胁迫下,螺旋藻细胞内MDA含量增加,与之相对应,活性氧的产生速率也增加,进一步证实了逆境胁迫下,植物细胞内叶绿素含量的下降、MDA的积累主要与UV-B胁迫下活性氧的产生及其对细胞的氧化损伤有关。     

番茄幼苗盐胁迫响应蛋白质组分析

采用营养液栽培,以盐敏感型番茄品种M82为试材,利用双向电泳(2-DE)研究盐胁迫处理下幼苗叶片蛋白质的表达谱,并采用基质辅助激光解析飞行时间串联质谱(MALDI-TOF/TOF-MS)技术进行差异蛋白质的分离及质谱鉴定。结果表明:(1)盐胁迫处理下,利用2-DE获得差异显著蛋白点20个,其中17个蛋白质点丰度上调表达,3个蛋白质点丰度下调表达。(2)通过质谱分析和蛋白质NCBInr数据库检索,共鉴定出19个差异蛋白,分别为果糖-二磷酸醛缩酶、S-腺苷甲硫氨酸合成酶、甘油醛-3-磷酸脱氢酶等及3个功能未知蛋白;这些鉴定出的差异蛋白质与能量代谢、光合作用、蛋白合成、氧化还原平衡等过程相关,暗示所分离鉴定的蛋白可能参与了番茄的盐胁迫响应,为进一步研究番茄抗逆机制奠定基础。     

基于TMT质谱分析技术筛选水稻根尖响应汞胁迫差异表达蛋白

稻米是人群汞暴露的最主要途径之一,为了从蛋白质水平上揭示水稻(Oryza sativa L.)适应重金属汞胁迫的分子机制,本研究以拔节期金优431水稻品种为材料,对比分析对照组和50、150、300 mg·kg~(-1)氯化汞胁迫组,采用同位素相对标记与绝对定量TMT(Tandem Mass Tag)技术,结合定量蛋白质组平行反应监测(parallel reaction monitoring,PRM)技术,鉴定水稻根尖部位响应汞胁迫差异表达蛋白,对所获得差异蛋白进行生物信息学分析,从而筛选出汞胁迫响应显著的潜在靶标蛋白。同时,选择20个差异表达蛋白通过平行反应监测试验进行了蛋白验证。结果表明,在变化倍数≥1.3、P0.05条件下,共鉴定5253种定量蛋白,包含364种差异蛋白,其中258种表达上调,106种表达下调。基因本体分子功能提示,这些差异性蛋白主要参与催化活性、绑定转运活性和抗氧化活性。京都基因与基因组百科全书(Kyoto Encyclopedia of Genes and Genomes,KEGG)通路显著性富集于代谢途径、次生代谢产物生物合成、苯丙烷类生物合成等,错误发现率(false discovery rate,FDR)0.05。成功鉴定并验证到的差异蛋白分别涉及抗氧化还原蛋白、金属螯合肽合成蛋白、金属硫蛋白相关蛋白等。差异表达蛋白中,与抗氧化、重金属胁迫防御响应和信号通路等相关的蛋白总体上调,而与代谢和能量产生与转运相关蛋白表达量总体下调。     

水稻叶片对镉胁迫响应的蛋白质差异表达

为揭示水稻镉抗性的分子机理,以抗镉水稻品种P1312777和镉敏感水稻品种IR24为材料,在镉离子浓度为0(对照)、50和100 μmol·L-1条件下水培处理7 d,应用蛋白质组学方法分析了2种水稻叶片对镉胁迫响应的蛋白质差异表达.结果表明:镉胁迫下水稻PI312777叶片中共检测到差异表达蛋白质点31个,通过MALDI-TOF/MS分析,鉴定了其中的24个蛋白质(包括20个不同蛋白质,4个重复检出蛋白质);IR24叶片中共检测到差异表达蛋白质点19个,其中15个蛋白质得到鉴定.PI312777叶片鉴定出的20个蛋白质覆盖了IR24叶片鉴定的15个蛋白质,前者有4个与光合作用相关,11个与细胞防御代谢相关,3个与其他代谢相关,2个为功能未知蛋白.与对照相比,不同浓度镉胁迫下,抗镉水稻PI312777叶片中热激蛋白、谷胱甘肽还原酶、蛋白酶体α亚基6型、果糖1,6-二磷酸醛缩酶、硫氧还蛋白和DNA重组修复蛋白均上调表达;镉敏感水稻IR24叶片中热激蛋白、谷胱甘肽还原酶、蛋白酶体α亚基6型的表达无显著差异,果糖1,6-二磷酸醛缩酶和硫氧还蛋白则下调表达.此外,DNA重组修复蛋白仅在镉胁迫的PI312777叶片中表达.水稻PI312777比IR24具有更强的镉抗性与这些差异表达的蛋白质密切相关.     

低温胁迫下烤烟幼苗叶片光合作用和抗氧化能力基因差异表达谱

对低温(5—7℃)胁迫下烤烟"K326"幼苗叶片光合指标、膜氧化水平及其抗氧化指标进行测定,并利用数字化基因表达谱技术进行基因差异表达分析。低温胁迫后烤烟幼苗叶绿素含量、光合能力显著下降,脯氨酸含量、丙二醛含量上升,超氧化物歧化酶活性、过氧化氢酶活性、抗坏血酸含量和谷胱甘肽含量均显著上升。低温胁迫后有2357个基因发生了显著差异表达,其中1673个基因表达上调、684个基因表达下调,其分子功能、细胞位置和主要代谢过程均涉及光系统、膜氧化系统和抗氧化系统。对涉及到的代谢过程进行分析,结果表明:光合天线蛋白调控基因表达量均显著下降、光合作用的主要调控基因表达量多数表现为显著下调、而与氧化能力相关的谷胱甘肽代谢差异表达基因大多数显著上调。基因差异表达谱分析结果和低温胁迫后叶片光合能力、抗氧化能力生理生态指标测定结果基本一致,为进一步研究低温胁迫对作物的生态影响和研究基因克隆与功能提供基础。     

枇杷果皮响应高温强光胁迫的蛋白质组分析

为探讨枇杷[Eriobotrya japonica(Thunb.)Lindl.]果皮在高温强光胁迫下的蛋白质组分变化,采用蛋白质组学方法分析了果实日灼抗性差的枇杷种质‘WDYDB’果皮蛋白质对高温强光胁迫的应答反应。结果表明,在自然高温强光胁迫与遮光处理(对照)下,枇杷果皮蛋白质双向电泳图谱中表达量差异在2倍以上的蛋白点共有31个;通过MALDI-TOF-TOF/MS质谱分析成功鉴定出26个差异蛋白点,包括11个下调蛋白和15个上调蛋白。根据这些蛋白功能,可将其分为防御应答、碳水化合物和能量代谢、光合作用、其它等4类蛋白。同时,对这些蛋白质在高温强光胁迫下的功能和作用进行了讨论。这些差异蛋白质参与了枇杷对高温强光胁迫的响应。     

Differential Expression of Proteins in Response to Molybdenum Deficiency in Winter Wheat Leaves Under Low-Temperature Stress

Molybdenum (Mo) is an essential micronutrient for plants. To obtain a better understanding of the molecular mechanisms of cold resistance enhanced by molybdenum application in winter wheat, we applied a proteomic approach to investigate the differential expression of proteins in response to molybdenum deficiency in winter wheat leaves under low-temperature stress. Of 13 protein spots that were identified, five spots were involved in the light reaction of photosynthesis, five were involved in the dark reaction of photosynthesis, and three were highly involved in RNA binding and protein synthesis. Before the application of cold stress, four differentially expressed proteins between the Mo deficiency (?Mo) vs. Mo application (+Mo) comparison are involved in carbon metabolism and photosynthetic electron transport. After 48 h of cold stress, nine differentially expressed proteins between the ?Mo vs. +Mo comparison are involved in carbon metabolism, photosynthetic electron transport, RNA binding, and protein synthesis. Under ?Mo condition, cold stress induced a more than twofold decrease in the accumulation of six differential proteins including ribulose bisphosphate carboxylase large-chain precursor, phosphoglycerate kinase, cp31BHv, chlorophyll a/b-binding protein, ribulose bisphosphate carboxylase small subunit, and ribosomal protein P1, whereas under +Mo condition cold stress only decreased the expression of RuBisCO large subunit, suggesting that Mo application might contribute to the balance or stability of these proteins especially under low-temperature stress and that Mo deficiency has greater influence on differential protein expression in winter wheat after low-temperature stress. Further investigations showed that Mo deficiency decreased the concentrations of chlorophyll a, chlorophyll b, and carotenoids; the maximum net photosynthetic rate; the apparent quantum yield; and carboxylation efficiency, even before the application of the cold stress, although the decrease rates were greater after 48 h of cold treatment, which is consistent with changes in the expressions of differential proteins in winter wheat under low-temperature stress. These findings provide some new evidence that Mo might be involved in the light and dark reaction of photosynthesis and protein synthesis.     

Proteomic approach of adaptive response to arsenic stress in Exiguobacterium sp. S17, an extremophile strain isolated from a high-altitude Andean Lake stromatolite

The North-Western part of Argentina is particularly rich in wetlands located in the Puna in an altitude between 3,600 and 4,600 m above sea level. Most of these high-altitude Andean lakes are inhospitable areas due to extreme habitat conditions such as high contents of toxic elements, particularly arsenic. Exiguobacterium sp. S17, isolated from stromatolites in Laguna Socompa, exhibited remarkable tolerance to high arsenic concentration, i.e., it tolerated arsenic concentration such as 10 mM of As(III) and 150 mM of As(V). A proteomics approach was conducted to reveal the mechanisms that provide the observed outstanding resistance of Exiguobacterium sp. S17 against arsenic. A comparative analysis of S17, exposed and unexposed to arsenic revealed 25 differentially expressed proteins. Identification of these proteins was performed by MALDI-TOF/MS revealing upregulation of proteins involved in energy metabolism, stress, transport, and in protein synthesis being expressed under arsenic stress. To our knowledge, this work represents the first proteomic study of arsenic tolerance in an Exiguobacterium strain.     

Proteomic analysis of the response to high-salinity stress in <Emphasis Type="Italic">Physcomitrella patens</Emphasis>

Physcomitrella patens is well known because of its importance in the study of plant systematics and evolution. The tolerance of P. patens for high-salinity environments also makes it an ideal candidate for studying the molecular mechanisms by which plants respond to salinity stresses. We measured changes in the proteome of P. patens gametophores that were exposed to high-salinity (250, 300, and 350 mM NaCl) using two-dimensional gel electrophoresis (2-DE) via liquid chromatography-tandem mass spectrometry (LC-MS/MS). Sixty-five protein spots were significantly altered by exposure to the high-salinity environment. Among them, 16 protein spots were down-regulated and 49 protein spots were up-regulated. These proteins were associated with a variety of functions, including energy and material metabolism, protein synthesis and degradation, cell defense, cell growth/division, transport, signal transduction, and transposons. Specifically, the up-regulated proteins were primarily involved in defense, protein folding, and ionic homeostasis. In summary, we outline several novel insights into the response of P. patens to high-salinity; (1) HSP70 is likely to play a significant role in protecting proteins from denaturation and degradation during salinity stress, (2) signaling proteins, such as 14-3-3 and phototropin, may work cooperatively to regulate plasma membrane H(+)-ATPase and maintain ion homeostasis, (3) an increase in photosynthetic activity may contribute to salinity tolerance, and (4) ROS scavengers were up-regulated suggesting that the antioxidative system may play a crucial role in protecting cells from oxidative damage following exposure to salinity stress in P. patens.     

Proteomic characterization of the Rhodobacter sphaeroides 2.4.1 photosynthetic membrane: identification of new proteins

The Rhodobacter sphaeroides intracytoplasmic membrane (ICM) is an inducible membrane that is dedicated to the major events of bacterial photosynthesis, including harvesting light energy, separating primary charges, and transporting electrons. In this study, multichromatographic methods coupled with Fourier transform ion cyclotron resonance mass spectrometry, combined with subcellular fractionation, was used to test the hypothesis that the photosynthetic membrane of R. sphaeroides 2.4.1 contains a significant number of heretofore unidentified proteins in addition to the integral membrane pigment-protein complexes, including light-harvesting complexes 1 and 2, the photochemical reaction center, and the cytochrome bc(1) complex described previously. Purified ICM vesicles are shown to be enriched in several abundant, newly identified membrane proteins, including a protein of unknown function (AffyChip designation RSP1760) and a possible alkane hydroxylase (RSP1467). When the genes encoding these proteins are mutated, specific photosynthetic phenotypes are noted, illustrating the potential new insights into solar energy utilization to be gained by this proteomic blueprint of the ICM. In addition, proteins necessary for other cellular functions, such as ATP synthesis, respiration, solute transport, protein translocation, and other physiological processes, were also identified to be in association with the ICM. This study is the first to provide a more global view of the protein composition of a photosynthetic membrane from any source. This protein blueprint also provides insights into potential mechanisms for the assembly of the pigment-protein complexes of the photosynthetic apparatus, the formation of the lipid bilayer that houses these integral membrane proteins, and the possible functional interactions of ICM proteins with activities that reside in domains outside this specialized bioenergetic membrane.     

The Comparatively Proteomic Analysis in Response to Cold Stress in Cassava Plantlets

Cassava (Manihot esculenta Crantz) is a tropical root crop and sensitive to low temperature. However, it is poorly to know how cassava can modify its metabolism and growth to adapt to cold stress. An investigation aimed at a better understanding of cold-tolerant mechanism of cassava plantlets was carried out with the approaches of physiology and proteomics in the present study. The principal component analysis of seven physiological characteristics showed that electrolyte leakage (EL), chlorophyll content, and malondialdehyde (MDA) may be the most important physiological indexes for determining cold-resistant abilities of cassava. The genome-wide proteomic analysis showed that 20 differential proteins had the same patterns in the apical expanded leaves of cassava SC8 and Col1046. They were mainly related to photosynthesis, carbon metabolism and energy metabolism, defense, protein synthesis, amino acid metabolism, signal transduction, structure, detoxifying and antioxidant, chaperones, and DNA-binding proteins, in which 40 % were related with photosynthesis. The remarkable variation in photosynthetic activity and expression level of peroxiredoxin is closely linked with expression levels of proteomic profiles. Moreover, analysis of differentially expressed proteins under cold stress is an important step toward further elucidation of mechanisms of cold stress resistance.     

Intermittent low temperatures constrain spring recovery of photosynthesis in boreal Scots pine forests

During winter and early spring, evergreen boreal conifers are severely stressed because light energy cannot be used when photosynthesis is pre‐empted by low ambient temperatures. To study photosynthetic performance dynamics in a severe boreal climate, seasonal changes in photosynthetic pigments, chloroplast proteins and photochemical efficiency were studied in a Scots pine forest near Zotino, Central Siberia. In winter, downregulation of photosynthesis involved loss of chlorophylls, a twofold increase in xanthophyll cycle pigments and sustained high levels of the light stress‐induced zeaxanthin pigment. The highest levels of xanthophylls and zeaxanthin did not occur during the coldest winter period, but rather in April when light was increasing, indicating an increased capacity for thermal dissipation of excitation energy at that time. Concomitantly, in early spring the D1 protein of the photosystem II (PSII) reaction centre and the light‐harvesting complex of PSII dropped to their lowest annual levels. In April and May, recovery of PSII activity, chloroplast protein synthesis and rearrangements of pigments were observed as air temperatures increased above 0°C. Nevertheless, severe intermittent low‐temperature episodes during this period not only halted but actually reversed the physiological recovery. During these spring low‐temperature episodes, protective processes involved a complementary function of the PsbS and early light‐induced protein thylakoid proteins. Full recovery of photosynthesis did not occur until the end of May. Our results show that even after winter cold hardening, photosynthetic activity in evergreens responds opportunistically to environmental change throughout the cold season. Therefore, climate change effects potentially improve the sink capacity of boreal forests for atmospheric carbon. However, earlier photosynthesis in spring in response to warmer temperatures is strongly constrained by environmental variation, counteracting the positive effects of an early recovery process.     

Enhanced photosynthesis and redox energy production contribute to salinity tolerance in Dunaliella as revealed by homology-based proteomics

Salinity is a major limiting factor for the proliferation of plants and inhibits central metabolic activities such as photosynthesis. The halotolerant green alga Dunaliella can adapt to hypersaline environments and is considered a model photosynthetic organism for salinity tolerance. To clarify the molecular basis for salinity tolerance, a proteomic approach has been applied for identification of salt-induced proteins in Dunaliella. Seventy-six salt-induced proteins were selected from two-dimensional gel separations of different subcellular fractions and analyzed by mass spectrometry (MS). Application of nanoelectrospray mass spectrometry, combined with sequence-similarity database-searching algorithms, MS BLAST and MultiTag, enabled identification of 80% of the salt-induced proteins. Salinity stress up-regulated key enzymes in the Calvin cycle, starch mobilization, and redox energy production; regulatory factors in protein biosynthesis and degradation; and a homolog of a bacterial Na(+)-redox transporters. The results indicate that Dunaliella responds to high salinity by enhancement of photosynthetic CO(2) assimilation and by diversion of carbon and energy resources for synthesis of glycerol, the osmotic element in Dunaliella. The ability of Dunaliella to enhance photosynthetic activity at high salinity is remarkable because, in most plants and cyanobacteria, salt stress inhibits photosynthesis. The results demonstrated the power of MS BLAST searches for the identification of proteins in organisms whose genomes are not known and paved the way for dissecting molecular mechanisms of salinity tolerance in algae and higher plants.     

Transgenic expression of fern Pteris vittata glutaredoxin PvGrx5 in Arabidopsis thaliana increases plant tolerance to high temperature stress and reduces oxidative damage to proteins

A glutaredoxin of the fern Pteris vittata PvGRX5 was previously implicated in arsenic tolerance. Because of possible involvements of glutaredoxins in metabolic adaptations to high temperature stress, transgenic Arabidopsis lines constitutively expressing PvGRX5 were evaluated for thermotolerance. Homozygous lines expressing PvGRX5 exhibited significantly greater tolerance to high temperature stress than the vector control and wild-type, based upon growth during stress and during recovery from stress, and this was related to leaf glutaredoxin specific activities. Measurements of tissue ion leakage, thiobarbituric acid reactive substances and protein carbonyl content showed that PvGRX5-expressors were significantly (P < 0.05) less affected by the high temperature treatment compared to wild-type and vector control lines for damage to membranes and proteins. Immunoblots indicated that specific protein bands, carbonylated during the stress treatment in the control lines, were protected in PvGRX5-expressors, thus implicating PvGRX5 in heat tolerance, likely mediated through cellular protection against oxidative stress.