人Elongator复合物Elp3亚基基因可显著补偿酵母elp3缺失菌株的生长缺陷

从HeLa细胞中分离的人的Elongator复合物在组成及与RNAPⅡ的作用方式上与酵母的E- longator复合物十分相似,但对其功能研究极少。为了研究人的Elongator复合物催化亚基Elp3的功能,将人elp3等基因转入酵母elp3基因缺失的突变菌株(elp3Δ菌株),并对转化菌株进行功能互补实验和ssa3和pho5基因表达分析,结果表明人elp3基因可显著恢复突变菌株对高温和Caffeine的敏感性,在低磷条件下显著补偿了突变株pho5基因表达延迟的缺陷,并可在热激条件下提高ssa3基因的表达。含酵母elp3非HAT区和人elp3 HAT区的融合yhelp3对上述缺陷有着更强的补偿能力。而HAT区催化结构域缺失的yhelp3HAT没有任何补偿能力,表明人Elp3亚基可能与酵母的该亚基功能相似,人Elp3的HAT活性也为其行使功能所必需。     

人Elongator复合物Elp4亚基基因可部分补偿酵母ELP4缺失菌株的生长缺陷

为研究人Elongator复合物EIp4亚基的功能,将人ELP4基因转入酵母ELP4基因缺失的突变菌株(elp4△菌株)中,并对转化菌株进行功能互补实验和SSA3和PHO5基因表达分析,结果表明人的ELP4基因不能恢复突变菌株对高盐的敏感性,但可以在一定程度上缓解突变菌株对高温、咖啡因(Caffeine)和6-氮尿嘧啶(6-AU)的敏感性,部分恢复低磷条件下PHO5基因表达延迟的缺陷,并可在热激条件下提高SSA3基因的表达,因此人的ELP4基因可以部分补偿酵母ELP4基因缺失所引起的生长缺陷,提示人的EIp4亚基可能与酵母的该亚基功能相似。     

酵母组蛋白乙酰转移酶Elp3多克隆抗体的制备、鉴定及应用

酵母Elp3(Yeast elongation protein 3,yElp3)是组蛋白乙酰转移酶复合物Elongator的催化亚基,通过组蛋白乙酰化参与基因转录延伸。近来证实胞质中也存在的Elp3还参与胞外分泌、tRNA修饰等重要生物学过程。为深入研究Elp3的复杂功能,PCR法克隆pYES2-yElp3质粒中编码yElp3N末端亲水区段(22~94aa),构建原核表达载体pMXB10-yElp3-219,经IPTG诱导表达和几丁质柱纯化后免疫兔制备多克隆抗体。ELISA检测显示该抗体有较高的效价(不低于1:2500),免疫印迹结果表明该抗体可特异性识别表达纯化及酵母细胞中的Elp3蛋白,运用该抗体进行的染色质免疫沉淀揭示转入elp3?菌株的酵母/人融合的yhElp3之所以可补偿突变株的基因表达延迟缺陷,是因其直接参与SSA3基因的转录延伸。     

一种快速筛选人目的基因反义片段的简单有效方法

本文选取人elp3基因三个不同的区段(基因全序列、5'端非HAT区、3'端HAT区)构建了反义质粒pRS313al 644、pRS314al 107、pRS314a450,通过与人elp3基因共转化酵母后的功能互补和基因表达检测,筛选出可显著抑制人Elp3表达的5'端非HAT区1107bp有效反义片段.该片段在随后的HeLa细胞转染实验中被检测出可显著抑制Elp3的mRNA水平.表明利用该方法可避开繁琐的细胞培养和转染步骤,快速筛选到人类兴趣基因的有效反义片段.     

Elongator复合物:一种新的参与转录延伸的组蛋白乙酰转移酶

由6个亚基组成的Elongator复合物是RNA聚合酶Ⅱ（RNA polymeraseⅡ．RNAPⅡ）全酶的一个重要组成部分,它可以与高度磷酸化的RNAPⅡ相结合,其Elp3亚基具有组蛋白乙酰转移酶（histone acetyltransferase,HAT）活性,在以染色质为模板的转录延伸中发挥重要作用。Elongator是目前发现的第一个参与转录延伸的HAT复合物。     

抗人Elp3 的N末端抗体制备及在染色质免疫沉淀中的应用

人 Elp3（human elongator protein 3, hElp3）具有组蛋白乙酰转移酶活性,是与延伸中的 RNA 聚合酶Ⅱ结合的 elongator 复合物的催化亚基,可参与组蛋白的乙酰化修饰与基因的转录延伸. Elp3 及其复合物功能异常与人类多种疾病相关. 为运用染色质免疫沉淀等手段深入研究 Elp3 功能,PCR 法克隆 pYES2-hElp3 质粒中编码 hElp3的N端亲水区段（1～69 氨基酸残基）,构建原核表达载体 pMXB10-hElp3-210,经 IPTG 诱导和几丁质柱纯化后,免疫兔制备多克隆抗体. ELISA 检测显示,该抗体有较高的效价(不低于1∶2　500).免疫印迹实验结果表明,该抗体可与纯化的及 HeLa 细胞中的 hElp3 蛋白特异性结合.运用该抗体对转入 elp3Δ菌株的人 Elp3 的染色质免疫沉淀实验结果表明,人 Elp3 可参与酵母 SSA3 基因的转录调控,这可能是人Elp3 能够部分补偿酵母 SSA3 基因延迟表达缺陷的原因.     

延伸因子复合物对真核生物tRNA的修饰作用

延伸因子复合物(Elongator complex, Elp)由6个亚基蛋白Elp1～6组成,在真核细胞生物中呈现高度的进化保守,提示其具有重要的生物学功能。研究表明,Elp涉及多种细胞行为如转录延伸、细胞外分泌、端粒基因沉默和DNA损伤修复、神经系统的发育和功能等。然而越来越多的证据显示,Elp通过介导tRNA修饰影响翻译过程,从而间接调控上述细胞行为。在人类,ELP1/IKBKAP突变可导致家族性植物神经功能障碍症,ELP2、ELP3和ELP4基因的遗传变异也可能与其他神经退行性病变相关。本文对Elp的结构、Elp修饰tRNA和Elp相关疾病等的研究现状及其进展进行综述。     

互作蛋白质与复合物亚基的基因表达相关性比较分析

利用在多种应激条件下酵母的基因表达谱数据 ,分别计算互作蛋白质及复合物亚基编码基因的表达相关性。结果发现 ,相对于随机对照组 ,互作蛋白质的编码基因与蛋白质复合物的编码基因表达相关性均显著 (P <0 .0 1) ,即互作蛋白质及复合物亚基有共表达的倾向。通过比较 ,进一步发现蛋白质复合物亚基的基因表达相关性显著高于互作蛋白质的基因表达相关性 (P <0 .0 1) ,这与复合物亚基之间功能联系强于定义不甚确切的互作蛋白之间功能联系现象吻合。     

产甘油假丝酵母胞浆3-磷酸甘油脱氢酶基因（CgGPD）功能分析

【目的】从高产甘油生产菌株产甘油假丝酵母（Candida glycerinogenes）基因组中克隆了NAD+依赖3-磷酸甘油脱氢酶编码基因（CgGPD）,但是该基因及其上游调控序列具体的功能还是未知的。本文研究了CgGPD基因及其上游调控序列的功能。【方法】本文以酿酒酵母（Saccharomyces cerevisiae）及其渗透压敏感型突变株为宿主,构建3种不同的酵母表达载体导入酵母细胞,研究了不同酵母转化子在渗透压胁迫条件下CgGPD基因表达对细胞的耐高渗透压胁迫应答及其细胞的甘油合成能力的影响。【结果】实验结果表明无论是以来源于S. cerevisiae 的TPI启动子还是来源于CgGPD基因的启动子,过量表达CgGPD基因的转化子均能够显著加速葡萄糖消耗速度和提高甘油合成能力,在gpd1/gpd2突变株中表达CgGPD基因能够消除细胞对外界高渗透压的敏感性,同时转化子胞内甘油大量积累。【结论】CgGPD基因在野生型酵母S. cerevisiae W303-1A表达显著提高细胞的甘油合成能力,在gpd/1gpd2突变株中能够互补GPD1基因的功能,CgGPD基因表达受渗透压诱导 调控。     

粗糙脉孢菌26 S蛋白酶体三个亚基缺失菌株的构建及表型分析

【目的】通过构建26S蛋白酶体的3个亚基RPN4、RPN7、RPN10的缺失突变菌株,研究这些缺失突变体的表型,进而探究这3个亚基在蛋白酶体中的作用。【方法】采用同源重组基因敲除技术、电转化、粗糙脉胞菌杂交、子囊孢子萌发及PCR鉴定等方法分别获得3个调节亚基的基因缺失突变体。利用racetube和平板生长法进行突变体表型检测。【结果】得到rpn4和rpn10的缺失突变纯合体及rpn7缺失突变异核体菌株。【结论】与野生型相比,rpn7KO(ku70RIP背景)突变体的菌丝生长及产生分生孢子的能力显著减弱;rpn4KO突变体在生长初期的菌丝生长缓慢,而后期的产孢能力与野生型无显著差异;rpn10KO突变菌株的表型介于上述两种突变体的表型之间。这些结果表明26S蛋白酶体的这3个亚基对脉胞菌的生长和发育至关重要。     

Subunit communications crucial for the functional integrity of the yeast RNA polymerase II elongator (gamma-toxin target (TOT)) complex

In response to the Kluyveromyces lactis zymocin, the gamma-toxin target (TOT) function of the Saccharomyces cerevisiae RNA polymerase II (pol II) Elongator complex prevents sensitive strains from cell cycle progression. Studying Elongator subunit communications, Tot1p (Elp1p), the yeast homologue of human IKK-associated protein, was found to be essentially involved in maintaining the structural integrity of Elongator. Thus, the ability of Tot2p (Elp2p) to interact with the HAT subunit Tot3p (Elp3p) of Elongator and with subunit Tot5p (Elp5p) is dependent on Tot1p (Elp1p). Also, the association of core-Elongator (Tot1-3p/Elp1-3p) with HAP (Elp4-6p/Tot5-7p), the second three-subunit subcomplex of Elongator, was found to be sensitive to loss of TOT1 (ELP1) gene function. Structural integrity of the HAP complex itself requires the ELP4/TOT7, ELP5/TOT5, and ELP6/TOT6 genes, and elp6Delta/tot6Delta as well as elp4Delta/tot7Delta cells can no longer promote interaction between Tot5p (Elp5p) and Tot2p (Elp2p). The association between Elongator and Tot4p (Kti12p), a factor that may modulate the TOT activity of Elongator, requires Tot1-3p (Elp1-3p) and Tot5p (Elp5p), indicating that this contact requires a preassembled holo-Elongator complex. Tot4p also binds pol II hyperphosphorylated at its C-terminal domain Ser(5) raising the possibility that Tot4p bridges the contact between Elongator and pol II.     

Elongator function in tRNA wobble uridine modification is conserved between yeast and plants

Based on studies in yeast and mammalian cells the Elongator complex has been implicated in functions as diverse as histone acetylation, polarized protein trafficking and tRNA modification. Here we show that Arabidopsis mutants lacking the Elongator subunit AtELP3/ELO3 have a defect in tRNA wobble uridine modification. Moreover, we demonstrate that yeast elp3 and elp1 mutants expressing the respective Arabidopsis Elongator homologues AtELP3/ELO3 and AtELP1/ELO2 assemble integer Elongator complexes indicating a high degree of structural conservation. Surprisingly, in vivo complementation studies based on Elongator‐dependent tRNA nonsense suppression and zymocin tRNase toxin assays indicated that while AtELP1 rescued defects of a yeast elp1 mutant, the most conserved Elongator gene AtELP3, failed to complement an elp3 mutant. This lack of complementation is due to incompatibility with yeast ELP1 as coexpression of both plant genes in an elp1 elp3 yeast mutant restored Elongator's tRNA modification function in vivo. Similarly, AtELP1, not ScELP1 also supported partial complementation by yeast–plant Elp3 hybrids suggesting that AtElp1 has less stringent sequence requirements for Elp3 than ScElp1. We conclude that yeast and plant Elongator share tRNA modification roles and propose that this function might be conserved in Elongator from all eukaryotic kingdoms of life.     

RNA polymerase II elongator holoenzyme is composed of two discrete subcomplexes.

Elongator is a histone acetyltransferase complex that associates with the elongating form of RNA polymerase II. We purified Elongator to virtual homogeneity via a rapid three-step procedure based largely on affinity chromatography. The purified factor, holo-Elongator, is a labile six-subunit factor composed of two discrete subcomplexes: one comprised of the previously identified Elp1, Elp2, and Elp3 proteins and another comprised of three novel polypeptides, termed Elp4, Elp5, and Elp6. Disruption of the yeast genes encoding the new Elongator proteins confers phenotypes indistinguishable from those previously described for the other elp mutants, and concomitant disruption of genes encoding proteins in either subcomplex does not confer new phenotypes. Taken together, our results indicate that holo-Elongator is a functional entity in vitro as well as in vivo. Metazoan homologues of Elp1 and Elp3 have previously been reported. We cloned the human homologue of yeast ELP4 and show that this gene is ubiquitously expressed in human tissues.