大豆雄性不育系与其保持系不同器官蛋白质比较

采用双向凝胶电泳技术对大豆质核互作雄性不育系NJCMS2A及其保持系NJCMS2B的种子、叶片和花药等不同器官蛋白质进行比较分析.结果显示,不育系NJCMS2A与其保持系NJCMS2B的花药2-DE图谱间存在较多差异表达蛋白点,种子2-DE图谱间仅有少量差异表达蛋白点,而叶片2-DE图谱间基本没有差异表达蛋白点.结果表明,不育基因表达具有时空性和器官特异性,与育性有关的蛋白主要在花药中表达.     

转人端粒酶基因骨髓间充质干细胞的蛋白表达谱分析

通过外源表达人端粒酶基因,构建了具有长期传代能力的骨髓间充质干细胞系（hTERT-hMSC）,并在传代过程中尚未发现有丧失接触性生长抑制和转型现象.本文主要目的是采用双向凝胶电泳技术和MALDI-TOF-MS蛋白质谱技术分析hTERT-hMSC 细胞的蛋白差异表达图谱,研究表达外源端粒酶基因对骨髓间充质干细胞生物学特性影响的可能机制.通过分析原代第12代hMSC、第95代和275代hTERT-hMSC的蛋白凝胶图,获得原代第12代hMSC总共1543±145个蛋白点,第95代hTERT-hMSC 1 611±186个蛋白点、275代hTERT-hMSC 1451±126 个蛋白点.质谱分析鉴定100种蛋白质,其中有20种有显著差异表达.结果表明,膜联蛋白（ANX）和GSTP1表达的下调以及内质网钙结合蛋白1（RCN1）、伴侣素CCT、TUBA1B和ACTG1表达的上调可能提升了人骨髓间充质干细胞扩增的能力,而prohibitin 蛋白和p53 蛋白维持正常表达可能对hTERT-hMSC 维持细胞接触性生长抑制起着重要作用.     

小麦叶片胞间洗脱液的蛋白质组学检测分析

植物叶片胞间液蛋白主要是一些低丰度蛋白,其中某些种类在植物抗病反应中起着重要的作用.通过改进已有的技术方法,结合超滤和丙酮沉淀处理,从500 9抗条锈病近等基因系小麦Taichung29*6/Yr5的叶片中获得了1.5mg可溶性的胞间洗脱液蛋白.SDS-PAGE电泳分析显示,胞间洗脱液蛋白样品和总蛋白样品存在着明显的差异.进一步的双向电泳分析证实,两个样品在胶图上可分别检测到1 241±59(n ＝3)和1 849±138(n ＝3)个蛋白点,其中胞间洗脱液样品有1 042±47(n ＝3)个不同于总蛋白样品的蛋白点,与总蛋白样品共有的蛋白点仅198±13(n ＝3)个.随意取100个差异蛋白点进行MALDI-TOF质谱分析,鉴定到一些已被确证存在于小麦胞间液中的蛋白质,如β-1,3-萄聚糖酶、葡聚糖-β-D-1,3-葡萄糖苷内切酶、几丁质酶、过氧化物酶等.从蛋白质组学角度初步分析了小麦叶片胞间洗脱液的组成,为进一步探索小麦叶片胞间液中低丰度蛋白的抗病功能提供依据.     

食源性肥胖大鼠下丘脑差异表达蛋白的蛋白质组学分析

建立食源性肥胖大鼠模型,对正常大鼠和肥胖大鼠下丘脑全蛋白进行双向凝胶电泳,产生下丘脑蛋白双向凝胶电泳图谱.对图谱进行比对分析后,从凝胶上切取差异表达的蛋白点,经胶内酶解,通过基质辅助激光解吸/电离飞行时间质谱(MALDI-TOF-MS) 对酶解后的肽段进行分析,再经数据库（NCBInr）检索,对蛋白质进行鉴定.研究发现,正常组表达图谱可检测到1　160±15（n=5）个蛋白点,肥胖组表达图谱可检测到1　070±10 （n=5）个蛋白点,与对照组相比,匹配率大于80％.并且成功鉴定了17种差异表达蛋白质,其中有7 种在肥胖组表达上调,10种表达下调.它们分别属于代谢酶、细胞周期调控因子、抗氧化蛋白、信号传导蛋白、蛋白酶体相关蛋白、细胞骨架蛋白以及未知蛋白等. 与正常对照组相比,肥胖组的蛋白质表达存在着较大差异,通过对差异表达蛋白的分析,提示了在肥胖发生的过程中,下丘脑神经中枢经历了一个非常复杂的信号活动和特定改变,为深入认识肥胖的发病机制奠定了基础.     

快速老化小鼠额叶皮质的蛋白组学研究

目的:探讨快速老化过程中差异蛋白质及其与学习记忆的关系.方法:以13月龄和8月龄快速老化小鼠模型的快速老化亚系SAMP8和抗快速老化亚系SAMR1的额叶为研究对象,经双向电泳技术和考马斯亮兰G250染色,分别获取13月龄和8月龄SAMP8和同龄SAMR1额叶的2-DE考染图谱,用PDQuest 7.40图像分析软件,建立不同月龄蛋白质组的匹配差异图谱,分析图谱中SAMP8与SAMR1蛋白质的表达变化.结果:8月龄SAMP8额叶检测到579个蛋白点,同龄SAMR1额叶检测到612个蛋白点;13月龄SAMP8额叶检测到705个蛋白点,同龄SAMR1额叶检测到621个蛋白点.PDQuest7.40软件匹配差异分析显示,8月龄SAMP8与同龄SAMR1比较,SAMP8表达缺失33个蛋白,两者共有显著差异表达蛋白35个.13月龄SAMP8与同龄SAMR1比较,SAMR1中表达缺失84个蛋白,两者均有但表达有显著变化的蛋白质36个.13月龄和8月龄的SAMP8互相比较,13月龄组新增蛋白126个,二者共有差异表达蛋白58个.13月龄和8月龄的SAMR1比较,13月龄组新增9个蛋白,二者共有差异表达蛋白33个.结论:两组不同月龄小鼠额叶SAMP8和SAMR1存在差异表达蛋白质,进一步研究有助于了解衰老的发生机制,并为研发调节学习记忆蛋白的新药提供依据.     

拟南芥AtrbohD和AtrbohF缺失对叶蛋白质组的影响

拟南芥NADPH氧化酶AtrbohD和AtrbohF在脱落酸（abscisic acid,ABA）抑制主根伸长、ABA诱导气孔关闭以及植物应答干旱、盐及病菌侵染等逆境胁迫反应中发挥重要作用,但这2个蛋白亚基缺失对拟南芥（Arabidopsis thaliana）蛋白质组的影响还未见报道。我们以营养土中生长16 d的野生型及AtrbohD和AtrbohF双基因突变体atrbohD1/F1叶片为材料进行蛋白组学分析,在双向电泳图谱上可分辨出约1 000个蛋白点,且蛋白表达谱存在差异。选取42个显著差异蛋白点进行MALDI-TOF/TOF质谱鉴定,成功鉴定出20个差异蛋白,这些蛋白主要与氧化还原、能量代谢、蛋白代谢、转录和信号传导等相关,还有一些蛋白功能未知。     

巴豆醛对水稻悬浮培养细胞蛋白质表达的影响

对巴豆醛处理水稻悬浮培养细胞后蛋白质组水平的变化进行了研究,以期发现在调控水稻细胞周期活动中起重要作用的蛋白。采用双向电泳分离蛋白,PDQuest软件分析凝胶图谱确定差异蛋白点,LCQ-Fleet ion trap系统鉴定蛋白,相关数据库检索分析差异蛋白点,获得了45个差异蛋白点,经质谱鉴定和数据库分析得到26个可信蛋白,集中在胁迫反应、蛋白质命运,信号转导,物质与能量代谢和膜功能等。在这些蛋白中,小分子量热激蛋白、Skp1蛋白和26S蛋白酶,CDC48,6-磷酸葡萄糖胺乙酰基转移酶以及蔗糖合酶等蛋白已有文献报告其在植物细胞周期调控中的作用,其它一些鉴定的蛋白参与了细胞的生理活动,其与细胞周期间的相互关系需进一步的研究。巴豆醛处理影响了水稻悬浮培养细胞正常的细胞周期活动,鉴定出部分蛋白与细胞周期的调控具有密切关系,而一些与水稻细胞分化、发育相关蛋白也得到了鉴定,其在细胞周期上的作用尚未有文献报告,这些蛋白的进一步研究将有助于揭示水稻细胞周期的调控机制。     

高畸形率水牛精子与正常水牛精子差异表达蛋白的分离和鉴定

旨在分析高畸形率和正常水牛精子的差异表达蛋白.运用双向凝胶电泳以及基质辅助激光解吸电离飞行时间质谱(MALDI-TOF-MS/MS)分析鉴定出高畸形率和正常的水牛精子的差异表达蛋白,并对部分蛋白进行生物信息学分析.结果显示,高畸形率和正常水牛精子之间存在16个表达差异明显的蛋白点,与正常水牛精子相比,5个蛋白斑点表达量上调,6个蛋白斑点下调,3个蛋白斑点缺失,2个蛋白斑点在畸形率高的水牛精子特有.质谱鉴定16个差异蛋白,成功鉴定出6个差异蛋白斑点,对应4种蛋白:左旋天冬酰胺酶、热应激蛋白β-9、半乳糖激酶、β-微管蛋白-2C.研究表明,高畸形率和正常水牛精子蛋白质表达存在一定的差异.     

家兔肠系膜上动脉闭塞性休克前后的血清比较蛋白质组学初步研究

目的：探讨家兔肠系膜上动脉闭塞性（SMAO）休克前后血清蛋白质组学变化及其在SMAO休克发生中的作用。方法：应用家兔肠系膜上动脉夹闭法复制家兔SMAO休克模型,在此基础上通过双向电泳分离家兔SMAO休克前后血清中的蛋白,找出凝胶上的差异蛋白点,用基质辅助激光解吸/电离串联飞行时间质谱技术进行鉴定,并通过生物信息学对差异蛋白的功能进行分析。结果：在家兔SMAO休克前后血清双向电泳图谱中发现19个差异蛋白点,其中11个蛋白质点在SMAO休克后血清中表达明显上调;8个蛋白质点在SMAO休克后血清中表达明显下调。从中选取4个差异最明显的点经基质辅助激光解吸/电离串联飞行和数据库搜索共鉴定出符合条件的2个差异蛋白点,为对氧磷酶和触珠蛋白,均在SMAO休克后血清中含量增高。结论：家兔SMAO休克前后血清蛋白质组会发生明显变化,对氧磷酶和触珠蛋白可能参与了SMAO休克后机体的代偿调节。     

缺铁逆境胁迫下水稻叶片蛋白的双向电泳及其蛋白质组图谱分析

水稻幼苗经缺铁胁迫诱导分别处理1、3、5天后,用酚法和TCA/丙酮法提取叶片中的可溶性蛋白进行双向电泳分析,从而研究在缺铁条件下叶片中蛋白表达的动态变化规律.结果显示1.不同pH IPG胶条分离蛋白的效果不同.用pH3-10的IPG胶条进行双向电泳,经考马斯亮蓝染色后,可在胶面上检测到大约450个蛋白点,其中约有89%的蛋白是酸性蛋白.如果用pH4-7的IPG胶条进行双向电泳,则可检测到大约600个蛋白点,其中有29个蛋白是上调表达,1个蛋白是下调表达,5个蛋白是诱导特异表达.2.不同方法提取的可溶性蛋白质量不同.TCA法简单易操作,似乎对于碱性蛋白的抽提效果更好,在2-DE图像上,减性端显示的蛋白点多;但此方法所得蛋白的再溶性差.酚法提取的蛋白再溶性好,所抽提的蛋白量较大,纯度较高.     

Inhibition of auxin-induced ethylene production by salicylic acid in mung bean hypocotyls

Salicylic acid (SA), a common plant phenolic compound, influences diverse physiological and biochemical processes in plants. To gain insight into the mode of interaction between auxin, ethylene, and SA, the effect of SA on auxininduced ethylene production in mung bean hypocotyls was investigated. Auxin markedly induced ethylene production, while SA inhibited the auxin-induced ethylene synthesis in a dose-dependent manner. At 1 mM of SA, auxininduced ethylene production decreased more than 60% in hypocotyls. Results showed that the accumulation of ACC was not affected by SA during the entire period of auxin treatment, indicating that the inhibition of auxin-induced ethylene production by SA was not due to the decrease in ACC synthase activity, the rate-limiting step for ethylene biosynthesis. By contrast, SA effectively reduced not only the basal level of ACC oxidase activity but also the wound-and ethylene-induced ACC oxidase activity, the last step of ethylene production, in a dose-dependent manner. Northern and immuno blot analyses indicate that SA does not exert any inhibitory effect on the ACC oxidase gene expression, whereas it effectively inhibits both the in vivo and in vitro ACC oxidase enzyme activity, thereby abolishing auxin-induced ethylene production in mung bean hypocotyl tissue. It appears that SA inhibits ACC oxidase enzyme activity through the reversible interaction with Fe²⁺, an essential cofactor of this enzyme. These results are consistent with the notion that ethylene production is controlled by an intimate regulatory interaction between auxin and SA in mung bean hypocotyl tissue.     

Identification of proteins in leaf tissues of white clover using MALDI-TOF mass spectrometry

Protein extracts, made to leaves harvested from the stolons of the pasture legume white clover (Trifolium repens L.) at two developmental stages (newly initiated; onset of senescence) were purified further using reverse-phase and ionexchange chromatography. Fractions enriched with the ethylene biosynthetic enzyme 1-aminocyclopropane-1-carboxylate (ACC) oxidase were selected for each stage and the final, partially purified fraction was subjected to twodimensional gel electrophoresis (2DE). Antibodies raised against a recombinant ACC oxidase (ACO) from white clover (antiTR-ACO2) recognised a series of spots of differing pI suggesting that ACO undergoes post-translational modifications. Further, the pattern differed between the ACO proteins partially purified from newly initiated leaves with leaves at the onset of senescence suggesting that the environmental and developmental cues that operate in each tissue influences the type and/or degree of post-translational modifications of the ACO protein. MALDI-TOF mass spectrometry was used to identify protein spots associated with the ACO proteins. Protein with identities to an ACO isoform from Oryza sativa, and a phosphoribulokinase from Arabidopsis thaliana were identified in the 2DE separations from newly initiated leaves, while an isoflavone reductase from Medicago sativa was identified in the 2DE separation of the senescent leaf extract.     

Malus hupehensis NPR1 induces pathogenesis-related protein gene expression in transgenic tobacco

Most commercially grown apple cultivars are susceptible to fungal diseases. Malus hupehensis has high resistance to many diseases affecting apple cultivars. Understanding innate defence mechanisms would help to develop disease-resistant apple crops. Non-expressor of pathogenesis-related genes 1 (NPR1) plays a key role in regulating salicylic acid (SA)-mediated systemic acquired resistance (SAR). MhNPR1 cDNA, corresponding to genomic DNA and its 5' flanking sequences, was isolated from M. hupehensis. Sequence analysis showed that the regulatory mechanism for oligomer-monomer transition of the MhNPR1 protein in apple might be similar to that of GmNPR1 in soybean, but different from that of AtNPR1 in Arabidopsis. No significant differences in MhNPR1 expression were found in M. hupehensis after infection with Botryosphaeria berengeriana, showing that MhNPR1 might be regulated by pathogens at the protein level, as described for Arabidopsis and grapevine. SA treatment significantly induced MhNPR1 expression in leaves, stems and roots, while methyl jasmonate (MeJA) treatment induced MhNPR1 expression in roots, but not in leaves or stems. The expression of MhNPR1 was highly increased in roots, moderately in leaves, and did not change in stems after treatment with 1-aminocyclopropane-1-carboxylic acid (ACC). SAR marker genes (MhPR1 and MhPR5) were induced by SA, MeJA and ACC in leaves, stems and roots. Overexpression of MhNPR1 significantly induced the expression of pathogenesis-related genes (NtPR1, NtPR3 and NtPR5) in transgenic tobacco plants and resistance to the fungus Botrytis cinerea, suggesting that MhNPR1 orthologues are a component of the SA defence signalling pathway and SAR is induced in M. hupehensis.     

Benzothiadiazole affects the leaf proteome in arctic bramble (Rubus arcticus)

Benzothiadiazole (BTH) induces resistance to the downy mildew pathogen, Peronospora sparsa, in arctic bramble, but the basis for the BTH‐induced resistance is unknown. Arctic bramble cv. Mespi was treated with BTH to study the changes in leaf proteome and to identify proteins with a putative role in disease resistance. First, BTH induced strong expression of one PR‐1 protein isoform, which was also induced by salicylic acid (SA). The PR‐1 was responsive to BTH and exogenous SA despite a high endogenous SA content (20–25 µg/g fresh weight), which increased to an even higher level after treatment with BTH. Secondly, a total of 792 protein spots were detected in two‐dimensional gel electrophoresis, eight proteins being detected solely in the BTH‐treated plants. BTH caused up‐ or down‐regulation of 72 and 31 proteins, respectively, of which 18 were tentatively identified by mass spectrometry. The up‐regulation of flavanone‐3‐hydroxylase, alanine aminotransferase, 1‐aminocyclopropane‐1‐carboxylate oxidase, PR‐1 and PR‐10 proteins may partly explain the BTH‐induced resistance against P. sparsa. Other proteins with changes in intensity appear to be involved in, for example, energy metabolism and protein processing. The decline in ATP synthase, triosephosphate isomerase, fructose bisphosphate aldolase and glutamine synthetase suggests that BTH causes significant changes in primary metabolism, which provides one possible explanation for the decreased vegetative growth of foliage and rhizome observed in BTH‐treated plants.     

The climacteric-like behaviour of young, mature and wounded citrus leaves

Although leaves and other vegetative tissues are generally considered as non-climacteric, citrus leaves show a climacteric system II behaviour after detachment. Upon harvest, young, fully expanded 'Valencia' orange (Citrus sinensis) leaves ( approximately 60-d-old) exhibited two phases of ethylene production. The first phase, up to 6 d after detachment, was characterized by a low and constant ethylene production (system I pathway), associated with a constitutive expression of ACC synthase 2 (CsACS2), CsERS1, and CsETR1. ACC synthase 1 (CsACS1) was not expressed during this phase and autoinhibition of ethylene production was apparent following treatment with exogenous ethylene or propylene. The second phase, 7-12 d after detachment, was characterized by a climacteric rise in ethylene production, preceded by the induction of CsACS1 and ACC oxidase 1 (CsACO1) gene expression in the system II pathway. This induction was accelerated and augmented by exogenous ethylene or propylene, indicating an autocatalytic system II ethylene biosynthesis. Mature leaves (6-8-months-old) behaved similarly, except that the climacteric peak in ethylene production occurred earlier (day 5). Young and mature leaves varied in the timing of the climacteric ethylene rise and CsACS1 and CsACO1 induction. The two phases of ethylene production, system I and system II, were also detected in wounded leaf discs of both young and mature leaves. The first phase peaked 15 min after excision and the second phase peaked after 6 h.