PSA启动子中RFA调节序列结合蛋白的初步研究

为了确定前列腺特异抗原(PSA)启动子中与雄激素调节相关的序列, 发现PSA启动子ARE上游一段15 bp的区域(-396～-382 bp), 是雄激素受体(AR)对PSA启动子激活所必需的, 将其命名为RFA. 转染和CAT分析显示该序列中某些核苷酸置换可显著降低雄激素对PSA基因启动子的诱导活性, 体外竞争结合实验证实某些前列腺细胞核内的非受体蛋白因子可与其特异结合, 但其突变型则丧失了这种能力, 该序列可能是一个新的辅助性顺式元件. 以RFA为探针, 利用亲和层析分离纯化了RFA结合蛋白, SDS-PAGE和蛋白质初步鉴定结果表明, 该蛋白与已知的多功能蛋白hnRNPA1, A2高度同源. RFA结合蛋白可能作为辅激活因子协同AR对PSA启动子的反式激活作用. 研究结果有助于深入理解PSA启动子的作用机制和组织特异性.     

雄激素通过雄激素受体途径调控垂体肿瘤转化基因(PTTG1)的表达

雄激素能上调大鼠前列腺中垂体肿瘤转化基因1(PTTG1)的表达,在前列腺癌标本中,发现PTTG1的表达明显高于正常组织.因此,用雄激素依赖的前列腺癌细胞LNCaP来研究雄激素调控PTTG1表达的分子机制.在LNCaP细胞中,通过雄激素刺激后,PTTG1的表达明显升高.根据序列分析以及5-缺失体实验(deletion)和突变实验(mutation),发现PTTG1的启动子上游-950到-933的序列上有1个雄激素受体反应元件(ARE),染色体免疫共沉淀实验(CHIP)也证实了雄激素能促进雄激素受体与PTTG1启动子上ARE结合,从而在转录水平调控PTTG1的表达.     

雄激素应答元件假冒DNA对PSA基因启动子的抑制作用

研究雄激素应答元件假冒DNA(AREdecoy)对前列腺特异抗原 (PSA)基因启动子的抑制作用 .联合运用报告基因和假冒DNA策略 ,构建了含PSA基因 5′侧启动子区 6 40bpDNA的萤光素酶表达载体pGL3 PSA ,与人工合成的双链硫代ARE假冒DNA共转染前列腺癌细胞株PC3 M并作用不同的时间 (2 4h、4 8h、72h) .应用双萤光素酶测定系统 ,检测萤光素酶的表达活性 .结果显示 :AREdecoyDNA显著抑制报告基因萤光素酶的表达 ,抑制率可达 95 % ,而对照decoyDNA无此作用 .作用不同的时间对萤光素酶活性的抑制无显著性差异     

mRNA稳定机制在低氧反应基因表达调控中的作用

几乎所有生物的信使RNA稳定性都影响基因表达。而mRNA的稳定性除了由其本身的序列和识别该序列的结合蛋白共同决定外,还受特异性的顺式作用元件和mRNA结合蛋白的影响。真核细胞中有3个独特的顺式作用元件：富AU元件（ARE）、茎环结构和富嘧啶结构,在mRNA稳定性调节中发挥重要作用。本文着重论述mRNA稳定机制在低氧诱导的一系列基因表达调控中的作用。     

西瓜果实AGPL1基因启动子的序列分析

利用PCR技术从西瓜嫩叶中扩增出1.2 kb AGPL1基因启动子,通过PlantCARE和PLACE数据库对启动子序列进行生物信息学分析。结果表明,AGPL1启动子具有多个典型的TATA-Box和CAAT-Box等基本元件,以及高水平转录顺式作用元件5UTR Py-rich stretch,光响应元件ACE、ATCC-motif、Box 4、I-Box、Sp1、TCCC-motif、GAG-motif、MNF1,2个赤霉素响应元件GARE-motif、P-box,参与蛋白代谢调节的顺式作用元件O2-site,参与水杨酸反应的顺式作用元件TCA-element,厌氧诱导所需的顺式作用元件ARE、逆境胁迫响应元件TC-rich repeats、生理昼夜节律控制元件circadian等,为研究外源基因在果实中的特异表达提供参考。     

p53负调控前列腺癌细胞中PC-1基因的表达

在前列腺癌进展中发生的PC-1基因表达失调和p53基因突变,提示这两个事件之间可能存在的联系.用依托泊苷处理前列腺癌LNCaP细胞后,PC-1蛋白的表达受抑制;瞬时转染分析表明野生型p53负调控PC-1启动子的转录活性;缺失突变分析将PC-1基因启动子上受p53负调控的区域定位在翻译起始位点上游757 bp～323 bp之间.缺失PC-1启动子上的雄激素受体反应元件并没有消除p53对其转录活性的抑制作用;无论p53是否存在,组蛋白去乙酰化酶抑制剂TSA处理LNCaP细胞后可以导致PC-1启动子转录活性升高.因此,p53和去乙酰化酶可以独立抑制PC-1启动子活性.这些研究结果表明,野生型p53负调控PC-1基因启动子的转录活性,而前列腺癌进展过程中p53突变可能和PC-1基因的表达失调有关.     

拟南芥非生物胁迫应答基因表达的调节子研究概况

分子生物学研究表明,植物中由诸如干旱、高盐和低温等环境胁迫因子诱导的几个基因具有多种功能。大多数干旱应答基因是由植物激素脱落酸（ABA）诱导的,但也有少数基因例外。对模式植物拟南芥基因表达中的干旱应答基因的分析表明,至少存在4个独立调节系统（调节子）。对典型胁迫诱导表达的一些基因中启动子的顺势作用元件和影响这些基因表达的转录子也已进行了分析。已经分离出与脱水效应元件/C重复序列（DRE/CRT）顺势作用元件结合的转录因子,并命名为DRE结合蛋白1/C重复序列结合因子（DREB1/CBF）和DRE结合蛋白2（DREB2）。在转基因拟南芥植株中,DREB1/CBF过量表达可增加其抗寒、抗旱和抗盐碱的能力。DREB1/CBF基因已成功地在许多不同作物中得到应用,从而提高作物对非生物胁迫的耐受性。与胁迫反应相关的其他转录因子的研究也正在取得进展。     

缺氧反应基因及调控机制研究进展

细胞在缺氧情况下,可诱导缺氧反应基因转录增加,维持血氧稳定。缺氧诱导因子－１和包含有启动子、增强子序列的顺序作用元件为转录调控的关键环节,缺氧诱导因子－１可通过顺式作用元件内的缺氧诱导因子－１结合位点与之相结合,二者通过复杂的相互作用来实现转录调控。     

PC-1增强受体酪氨酸激酶家族成员EphA3在前列腺癌细胞中的转录

为了研究前列腺癌相关基因(prostate and colon gene 1, PC-1）对受体酪氨酸激酶家族分子EphA3表达的影响,用RT-PCR、实时PCR和Western印迹检测表达不同水平PC-1的前列腺癌细胞系LNCaP和C4-2中EphA3的表达情况. 发现PC-1可诱导EphA3基因表达上调. 采用荧光素酶实验检测PC-1对于EphA3启动子转录活性的影响,结果显示,PC-1对转录起始位点上游916 bp的启动子活性没有影响,而可增强转录起始位点上游2011 bp启动子的活性.对EphA3启动子－916 bp～－2　011 bp区域进行生物信息学分析,结果显示,此区域包含HSF、NF-1、Nkx-2、SP1和GATA-1等多种转录因子结合位点.实验结果表明,PC-1可通过影响EphA3启动子诱导EphA3基因高表达,其调控区域位于转录起始位点上游－2　011　bp至－916 bp之间,提示PC-1可能通过影响一些结合于此区域的转录因子来影响EphA3启动子的转录活性.     

Gene Duplication and Gene Conversion in the Caenorhabditis elegans Genome

A comprehensive analysis of duplication and gene conversion for 7394 Caenorhabditis elegans genes (about half the expected total for the genome) is presented. Of the genes examined, 40% are involved in duplicated gene pairs. Intrachromosomal or cis gene duplications occur approximately two times more often than expected. In general the closer the members of duplicated gene pairs are, the more likely it is that gene orientation is conserved. Gene conversion events are detectable between only 2% of the duplicated pairs. Even given the excesses of cis duplications, there is an excess of gene conversion events between cis duplicated pairs on every chromosome except the X chromosome. The relative rates of cis and trans gene conversion and the negative correlation between conversion frequency and DNA sequence divergence for unconverted regions of converted pairs are consistent with previous experimental studies in yeast. Three recent, regional duplications, each spanning three genes are described. All three have already undergone substantial deletions spanning hundreds of base pairs. The relative rates of duplication and deletion may contribute to the compactness of the C. elegans genome. Received: 30 July 1998 / Accepted: 12 October 1998     

MADS-box基因家族基因重复及其功能的多样性

基因的重复(duplication)及其功能的多样性(diversification)为生物体新的形态进化提供了原材料。MADS-box基因在植物(特别是被子植物)的进化过程中发生了大规模的基因重复事件而形成一个多基因家族。MADS-box基因家族的不同成员在植物生长发育过程中起着非常重要的作用,在调控开花时间、决定花分生组织和花器官特征以及调控根、叶、胚珠及果实的发育中起着广泛的作用。探讨MADS-box基因家族的进化历史有助于深入了解基因重复及随后其功能分化的过程和机制。本文综述了MADS-box基因家族基因重复及其功能分化式样的研究进展。     

Gene targeting in the mouse

Mice with alterations to specific endogenous genes can be produced by gene targeting in embryonic stem cells. The field has developed rapidly over the past decade, so that large numbers of mice with different gene deficiencies have been generated. Knockout mice provide an ideal opportunity to analyse the function of individual mammalian genes and to model a range of human inherited disorders. This powerful approach has also identified numerous examples of gene redundancy and has highlighted the need to consider metabolic differences between man and mouse in disease modelling. More sophisticated gene-targeting methods are now being used to introduce subtle gene alterations. In the future, more refined genetic analysis and genome, rather than individual gene, alterations will be achieved by incorporating site-specific recombination into targeting strategies. Gene targeting could also make a contribution to improved protocols for gene therapy.     

Transient Gene Expression in Tobacco using Gibson Assembly and the Gene Gun

In order to target a single protein to multiple subcellular organelles, plants typically duplicate the relevant genes, and express each gene separately using complex regulatory strategies including differential promoters and/or signal sequences. Metabolic engineers and synthetic biologists interested in targeting enzymes to a particular organelle are faced with a challenge: For a protein that is to be localized to more than one organelle, the engineer must clone the same gene multiple times. This work presents a solution to this strategy: harnessing alternative splicing of mRNA. This technology takes advantage of established chloroplast and peroxisome targeting sequences and combines them into a single mRNA that is alternatively spliced. Some splice variants are sent to the chloroplast, some to the peroxisome, and some to the cytosol. Here the system is designed for multiple-organelle targeting with alternative splicing. In this work, GFP was expected to be expressed in the chloroplast, cytosol, and peroxisome by a series of rationally designed 5’ mRNA tags. These tags have the potential to reduce the amount of cloning required when heterologous genes need to be expressed in multiple subcellular organelles. The constructs were designed in previous work¹¹, and were cloned using Gibson assembly, a ligation independent cloning method that does not require restriction enzymes. The resultant plasmids were introduced into Nicotiana benthamiana epidermal leaf cells with a modified Gene Gun protocol. Finally, transformed leaves were observed with confocal microscopy.     

Gene transfer in the marine environment

Abstract This review summarises the literature on bacterial gene transfer in marine ecosystems. Relevant experiments carried out in model systems are also included. Prerequisites for the main gene transfer mechanisms, transformation, transduction and conjugation are discussed, such as concentrations of extracellular DNA in marine waters, numbers of bacteriophages in sea water and frequency of plasmids in marine bacteria. Transfer of chromosomal genes as well as plasmids are considered. We also discuss the possibility that gene transfer is more frequent in surface-associated bacterial communities. Examples of relevant studies using various solid surfaces and from the air-water interface are summarized. We suggest that there is a higher ‘flow-rate’ of genetic information through surface-associated communities compared to bulk water communities.     

Multiple Inter-Kingdom Horizontal Gene Transfers in the Evolution of the Phosphoenolpyruvate Carboxylase Gene Family

Pepcase is a gene encoding phosphoenolpyruvate carboxylase that exists in bacteria, archaea and plants,playing an important role in plant metabolism and development. Most plants have two or more pepcase genes belonging to two gene sub-families, while only one gene exists in other organisms. Previous research categorized one plant pepcase gene as plant-type pepcase (PTPC) while the other as bacteria-type pepcase (BTPC) because of its similarity with the pepcase gene found in bacteria. Phylogenetic reconstruction showed that PTPC is the ancestral lineage of plant pepcase, and that all bacteria, protistpepcase and BTPC in plants are derived from a lineage of pepcase closely related with PTPC in algae. However, their phylogeny contradicts the species tree and traditional chronology of organism evolution. Because the diversification of bacteria occurred much earlier than the origin of plants, presumably all bacterialpepcase derived from the ancestral PTPC of algal plants after divergingfrom the ancestor of vascular plant PTPC. To solve this contradiction, we reconstructed the phylogeny of pepcase gene family. Our result showed that both PTPC and BTPC are derived from an ancestral lineage of gamma-proteobacteriapepcases, possibly via an ancient inter-kingdom horizontal gene transfer (HGT) from bacteria to the eukaryotic common ancestor of plants, protists and cellular slime mold. Our phylogenetic analysis also found 48other pepcase genes originated from inter-kingdom HGTs. These results imply that inter-kingdom HGTs played important roles in the evolution of the pepcase gene family and furthermore that HGTsare a more frequent evolutionary event than previouslythought.     

Gene flow in the Pleistocene.

Previous estimates by Weiss and Maruyama (1976) and Rouhani (1989) of the time that an advantageous gene would take to disperse throughout hominid populations in the Pleistocene were considered to support the multiregional and single origin theories of the origin of modern humans, respectively. With the addition of some long-range gene flow, current simulations indicate that this dispersal could occur in 4000 generations, or in about 80,000 years. However, with a mutation rate of 10(-7) to mutants with the same selective advantage, such mutants would occur in populations before the 1 original mutant could disperse over this large area. The importance of gene flow in maintaining the species seems to be overemphasized.