MALDI-TOF/TOF和LC-MS/MS液质联用分析大鼠脑脉络丛的多肽组

脉络丛(choroid plexus,CP)位于血液与脑脊液(cerebrospinal fluid,CSF)之间,不仅是CSF的重要来源,而且是构成血液-脑脊液屏障(blood-cerebrospinal fluid barrier,BCB)的组织基础.CP参与脑组织中一些血源性多肽的输送以及自身多肽合成的生理过程,在维持脑微环境动态平衡和调节中枢神经系统的正常功能方面起到非常重要的作用.本研究分别运用MALDI-TOF/TOF和LC-MS/MS液质联用系统分析了成年SD大鼠血液-脑脊液屏障(即脉络丛组织)中的多肽组.共鉴定到163个多肽(P0.001),这些多肽为69种蛋白质的降解肽段,其中ATP合酶(ATP synthase),细胞色素c(cytochrome c),血红蛋白(hemoglobin),NADH-辅酶Q氧化还原酶(NADH-ubiquinone oxidoreductase),β珠蛋白(beta-globin)这5种蛋白质的肽段数占总肽段数的50%以上,并且部分多肽序列相似度高,类似其前体蛋白的逐步降解片段,而这些前体蛋白质的分子量多数在10kD至20kD之间.上述研究结果为SD大鼠脉络丛组织的生理功能研究及组织多肽组学的研究方法提供了有价值的科学资料.     

ΦC31位点特异性整合酶DNA结合功能域的鉴定

DNA结合功能域的确定是阐明位点特异性重组酶整合机制的关键,而对酶DNA结合功能域进行突变研究是提高酶整合效率和整合特异性的重要方法.为了鉴定ΦC31位点特异性整合酶的DNA结合功能域,依据对ΦC31整合酶序列的生物信息学分析结果,利用PCR和克隆技术在pET22b原核表达载体上构建ΦC31整合酶重组截短突变体表达质粒,将获得的表达质粒转化入大肠杆菌BL21(DE3)菌株扩大培养并用IPTG诱导融合蛋白的表达,经镍柱纯化获得了纯度达90%以上的重组蛋白,分子量也与预期大小一致,Western印迹确定了重组蛋白的特异性.凝胶迁移滞后实验显示野生型以及截短突变体蛋白ΦC311-528、ΦC311-472、ΦC311-413能与细菌附着位点DNAattB和噬菌体附着位点DNAattP结合的条带,而截短突变体ΦC311-353、ΦC311-279、ΦC311-120观察不到相应的结合条带.6个截短突变体质粒在体内重组活性蓝白斑实验中均表现为蓝斑,显示出皆丧失体内重组活性.研究证实,ΦC31整合酶半胱氨酸富集域(第353～413位氨基酸)具有DNA结合的功能,而C末端缬氨酸富集区(第528～613位氨基酸)也与其重组活性相关.这为进一步了解ΦC31整合酶的结构与功能,最终引导其结构进化,提高其特异性和整合效率奠定了基础.     

何首乌体细胞胚的诱导及植株再生研究

以何首乌茎尖、茎段为外植体,经体细胞胚发生途径,进行胚性愈伤组织诱导、体细胞胚的诱导、植株再生的研究.并采用临时压片法对体细胞胚的发育过程进行观察.结果表明愈伤组织诱导最适培养基为Ms＋6-BA 2.0 mg/L＋NAA 0.5 mg/L,体细胞胚诱导最适培养基为MS＋6-BA 1.0 mg/L＋NAA 0.2 mg/L.将产生的体细胞胚首先接种于MS基本培养基使其充分发育后转入MS＋6-BA 2.0 mg/L培养基中诱导出芽,出芽率高于直接采用Ms＋6-BA 2.0 mg/L培养基诱导.体细胞胚的发育过程是首先在愈伤组织表面形成许多瘤状突起即胚性细胞团,胚性细胞团继续发育成球形胚、盾形胚,球形胚、盾形胚成熟后发育成植株.     

脆性组氨酸三联体基因小干扰RNA的构建及干扰效果检测

目的:构建脆性组氨酸三联体(FHIT)基因的小干扰RNA(siRNA),并检测其对293T细胞内源性FHIT基因表达的干扰效果。方法:根据FHIT基因序列,通过生物信息学网站预测可能的siRNA,从中筛选出2条合理的FHIT-siRNA,将其克隆到siRNA表达载体pSilencer2.1-U6Hygro中,转化大肠杆菌DH5α,挑取阳性克隆进行测序鉴定;将构建成功的FHIT-siRNA重组载体转染人胚肾细胞293T,Western印迹检测siRNA对293T内源性FHIT表达的干扰效果。结果:构建了2个FHIT-siRNA重组质粒,2条siRNA都有干扰作用,其中一条的作用效果可达50%以上。结论:构建的FHIT-siRNA为进一步研究FHIT的功能提供了有利的工具。     

石蒜组织培养和植株再生的研究

以石蒜的双鳞片为外植体,MS为培养基,对石蒜组织培养适宜条件进行筛选,并对石蒜的植株再生进行了研究。结果表明：MS＋3mg/L6-BA＋0.3mg/L NAA是不定芽增殖的最佳激素组合,诱导率可达73.99%;石蒜生长旺盛期的11月是芽诱导率最高的时期,同时,MS＋0.5mg/L6-BA＋0.8mg/L NAA是较好的生根培养基,生根率可达95.00%;幼苗移栽至蛭石30%营养土中移栽成活率最高达91.67%。     

霍乱弧菌O139多糖抗原的提取方法及优化

目的:研究霍乱弧菌O139多糖抗原的提取方法,以获得高纯度的多糖抗原。方法:采用热酚水法提取霍乱弧菌O139的脂多糖(LPS),并增加了DNaseⅠ、RNase消化步骤,以去除DNA及RNA的污染;进一步采用酸水解法获得脱毒的O特异性多糖(O-SP)。结果:经生化方法检测,证实提纯的LPS和O-SP纯度较高,能满足进行霍乱免疫研究的要求。结论:该方法简便可行,值得推广。     

RNA干扰的研究进展及应用

RNA干扰(RNAi)是生物体的一种在进化上保持高度保守的,能抵御外源基因或外来病毒侵犯的重要防御机制,是一种序列特异性的转录后基因沉默现象。它由双链RNA引发,广泛存在于动、植物等各种生物体内。我们简要综述了RNAi发生的机制、特点、哺乳动物与RNAi现象,以及RNAi的应用等。     

Crystal Structure of Yeast FAD Synthetase (Fad1) in Complex with FAD

Flavin adenine dinucleotide (FAD) synthetase is an essential enzyme responsible for the synthesis of FAD by adenylation of riboflavin monophosphate (FMN). We have solved the 1.9 Å resolution structure of Fad1, the yeast FAD synthetase, in complex with the FAD product in the active site. The structure of Fad1 shows it to be a member of the PP-ATPase superfamily. Important conformational differences in the two motifs involved in binding the phosphate moieties of FAD compared to the Candida glabrata FMNT ortholog suggests that this loop is dynamic and undergoes substantial conformational changes during its catalytic cycle.     

Complete Genome Sequence of Staphylococcus lugdunensis Strain HKU09-01

Staphylococcus lugdunensis is a member of the coagulase-negative staphylococci and commonly found as part of the human skin flora. It is a significant cause of catheter-related bacteremia and also causes serious infections like native valve endocarditis in previously healthy individuals. We report the complete genome sequence of this medically important bacterium.Staphylococcus lugdunensis is a member of the coagulase-negative staphylococci (CoNS) commonly colonizing the human skin and mucosal membranes. While the genus Staphylococcus contains 48 named species currently, only a few species, notably S. aureus, are coagulase positive. Thus, the phenotypic characteristic is routinely tested in the medical microbiological laboratory for rapid differentiation of the highly pathogenic S. aureus from the other staphylococci. Among the CoNS, only a few species are known to cause human disease, usually in the form of opportunistic infections only (6). However, S. lugdunensis is an important exception (3). Besides causing catheter-related bacteremia similar to other CoNS, it causes a variety of severe nosocomial and community-acquired infections, including native valve endocarditis, a devastating and potentially fatal disease that can affect previously healthy individuals. Another unusual feature are the susceptibilities of S. lugdunensis isolates to multiple antimicrobial agents even when the incidence of multiple-drug-resistant CoNS and S. aureus occurrences are increasing in both hospital and community settings (4, 5).The genome sequence of S. lugdunensis strain HKU09-01 was determined by high-throughput sequencing performed on a GS FLX system (Roche Diagnostics, Basel, Switzerland), with approximately 45-fold coverage of the genome. This clinical strain was previously isolated from the culture of pus from a skin swab. Genome assembly was performed using the Newbler assembler, resulting in 30 large contigs (>500 bp in size). The contigs were then ordered and oriented into one scaffold using OSLay (11). The genome-finishing strategy for S. lugdunensis was similar to that employed for our previously sequenced Laribacter hongkongensis genome (12). Briefly, gap closures were performed by genomic PCR followed by DNA sequencing of amplification products on an ABI 3130xl sequencer (Applied Biosystems, CA). The finished sequence was validated by genome macrorestriction analysis using multiple rare-cutting enzymes and visualization by pulsed-field gel electrophoresis. Protein coding regions were predicted with Glimmer3 (2), and automatic genome annotation was performed on the RAST server (1). Additionally, annotation of tRNA and transfer-messenger RNA (tmRNA) genes was performed using tRNAScan-SE (10) and ARAGORN (9). Identification of rRNA genes was performed using RNAmmer (8).The genome of S. lugdunensis strain HKU09-01 consists of a circular 2,658,366-bp chromosome with G+C content of 33.87%, similar to those of other staphylococci. No plasmids are present in the sequenced strain. The genome contains 61 tRNA genes for all amino acids and 2,489 predicted protein-coding genes. Eight putative genomic islands were identified, and one actually consists of a pair of duplicated 32-kb genomic regions. Similar to Staphylococcus saprophyticus (7), but different from the other staphylococci, the genome contains 6 rRNA operons, one of them having the unusual organization 5S-16S-23S-5S.With the availability of the present genome sequence, S. lugdunensis now joins other staphylococcal species with human pathogenic potential, like S. aureus, S. epidermidis, S. haemolyticus, and S. saprophyticus, to have at least one reference genome available. Further in-depth analysis will be necessary to fully elucidate the genomic differences that may explain the variation in virulence of the staphylococcal species.     

Phosphorylation of mouse serine racemase regulates d-serine synthesis

Serine racemase (SR) catalyses the synthesis of the transmitter/neuromodulator d-serine, which plays a major role in synaptic plasticity and N-methyl d-aspartate receptor neurotoxicity. We now report that SR is phosphorylated at Thr71 and Thr227 as revealed by mass spectrometric analysis and in vivo phosphorylation assays. Thr71 phosphorylation was observed in the cytosolic and membrane-bound SR while Thr227 phosphorylation was restricted to the membrane fraction. The Thr71 site has a motif for proline-directed kinases and is the main phosphorylation site of SR. Experiments with a phosphorylation-deficient SR mutant indicate that Thr71 phosphorylation increases SR activity, suggesting a novel mechanism for regulating d-serine production.