人端粒酶逆转录酶（hTERT）基因第3内含子的克隆 …

从端粒酶活性呈性阳的水生细胞株人肺ＳＣＰ－Ａ－１中分离了总ＲＮＡ,以此为模板,结合ＲＴ－ＰＣＲ技术和长模板ＰＣＲ技术,用ｈＴＥＲＴ基因特异性引物扩增到一长约２．２ｋｂ的ｃＤＮＡ片段。将该片纯化后克隆到通用测序本Ｔ－ｅａｓｙ ｖｅｃｔｏｒ上得到重组质粒。用测引物ＳＰ６和Ｔ７对该片段进行部分双向测序。经序列分析和同源比较推测该片段包含了ｈＴＥＲＴ基因的第３内含子。该结果提示了ＲＴ－ＰＣＲ技术和长模板Ｐ     

小菜蛾酯酶基因的克隆

根据已知的酯酶基因的保守性氨基酸序列设计简并引物 ,通过逆转录 -聚合酶链反应 (RT PCR)扩增出小菜蛾PlutellaxylostellaL .酯酶基因片段 ,然后按照测序结果再设计 1对特异引物 ,利用PCR方法 ,筛选小菜蛾的cDNA文库。将RT PCR获得的 1条长度为 3 3 0bp的目的条带 ,亚克隆入T -载体 ,测序结果表明共得到了 1 0个不同的酯酶基因片段。利用特异引物对小菜蛾的cDNA文库进行初筛 ,显示文库中存在有小菜蛾的酯酶基因。     

人sTNFR1基因的克隆以及在NIH3T3细胞中的稳定表达

以He1a细胞的总RNA为模板,用RT—PCR方法扩增sTNFR1全编码区基因片段,构建含有目的片段的T载体克隆及真核表达载体pcDNA3．1（-）重组质粒亚克隆,将重组质粒和脂质体共同转染NIH3T3细胞系,G418筛选稳定转染细胞株．经核苷酸序列测序和酶切鉴定,成功构建了pcDNA3．1（-）-sTNFR1真核表达质粒,脂质体法建立了高效表达sTNFRI的稳定转染细胞系,并经RT—PCR和Western Blotting鉴定．人sTNFR1基因能在NIH3T3细胞系中稳定表达,为今后的研究打下了基础．     

一种单核苷酸多态性的单倍型分析技术

运用多步PCR和测序技术,完成基因组中相距较远的单核苷酸多态位点的单倍型构建。通过设计2条等位基因特异性引物,扩增大片段DNA(10kb左右),以此大片段DNA作为下一轮PCR反应的模板,再在该片段中设计待检测区域的PCR引物,进行第2轮PCR。对PCR产物进行测序分析,确定其多态位点处的等位基因。结合第1轮PCR中的等位基因特异性引物,即可确定该大片段DNA中不同单核苷酸多态性构成的单倍型。以脂蛋白脂酶基因为例,应用其启动子区以及第4外显子区的等位基因特异性引物扩增约16kb的DNA片段,然后检测位于该片段中第2、3外显子的多态性。在￡-尸￡-基因第2内含子中发现了 13557G→A多态性。经分析确定出-421G／ 13557G／ 15222A、-421A／ 13557G／ 15222A、-421G／ 13557G／ 15222G、-421G／ 13557A／ 15222A等4种单倍型。等位基因特异性PCR结合小片段测序是一种快捷高效的对相距较远的多个SNP进行单倍型构建的新策略。     

内含子中正筛选标记neo基因在转录中的剪切研究

目的:研究插入内含子中的正筛选标记基因neo在转录中的剪切情况。方法:克隆了猪血清白蛋白基因5'端调控序列,以猪基因组DNA为模板,P10/P11为引物,PCR扩增猪血清白蛋白基因翻译终止密码子后2.9kb的3'端调控序列;以pEGFP-1为模板,P400/P401为引物PCR扩增绿色荧光蛋白(EGFP)基因,插入猪血清白蛋白基因5'端调控区之后,在3'端调控序列的内含子中靠近N端的序列中插入正筛选标记基因neo,构建了表达EGFP的真核表达载体pEXp11。转染人肝癌细胞系HepG2,通过G418药物筛选获得稳定转染的抗药性细胞克隆。提取抗性细胞克隆基因组RNA并进行反转录,获得cDNA序列。结果:用引物D400/D401及分别位于neo基因和3'端调控序列上的一对引物D394/D357进行PCR检测,其中D394/D357并未扩增出目的条带。结论:插入内含子中的neo基因在转录过程中可随内含子一起被剪切。     

PCR-mtDNA技术鉴别检测不同动物肌肉组织和饲料中鸭源性成分

以鸭肌肉组织DNA为模板,利用PCR-mtDNA技术成功克隆出了鸭mtDNA COIII基因(GenBank Accession No.DQ655706).对所克隆的序列分析表明.其序列包括鸭细胞色素C氧化酶III(COIII)基因全序列784 bp,通过同源性分析可知,动物的线粒体DNA COIII基因是相对保守的,利用此特性设计PCR-mtDNA方法鉴别检测鸭源性成分的特异性引物;以各种动物肌肉组织及饲料DNA为模板进行PCR扩增、经反复验证筛选出只能扩增出鸭DNA的目的片段,而不能扩增出其他动物DNA片段的特异性强、稳定性好的引物P3、P4;利用此引物PCR扩增鸭DNA的特异性片段为226 bp,对PCR产物进行测序分析可知与已克隆的鸭mtDNA COIII基因同源性达到100%,证明了所筛选引物的准确性.通过对不同含量的DNA模板溶液进行PCR扩增的方法,对筛选出的特异性引物P3、P4进行灵敏度试验,结果分析表明灵敏度约为0.001%,证明该PCR方法具有特异性强、灵敏度高的特点,完全可作为鉴别不同动物肌肉组织和饲料中鸭源性成分的方法.     

鹅源新城疫病毒ZJI株基因组cDNA克隆的序列修饰

将鹅源新城疫病毒ZJI株全基因组cDNA克隆通过酶切切下包含T7启动子区域和转录载体的片段,将其自身环化后获得约6．5kb的质粒。设计引物,利用基因定点突变技术,在此质粒上T7启动子与NDV Leader序列之间突变插入额外的3个G碱基,将此突变最终引入到原基因组cDNA克隆中。应用RT—PCR技术从尿囊液中扩增NDV基因组F／HN基因区域部分片段,利用限制性内切酶BsmBI将扩增片段连接,最终将原cDNA克隆中相应片段替换下。测序结果表明,原基因组cDNA克隆中特定位置碱基插入突变成功,F／HN基因区域碱基突变均得以纠正。以上cDNA克隆的修饰与替换为该毒株的反向遗传研究打下了基础。     

基孔肯雅病毒非结构蛋白基因合成中多位点缺失突变的校正方法

目的:建立一种PCR方法,以快速校正基孔肯雅病毒非结构蛋白基因合成过程中发生的多位点缺失突变。方法:用PCR方法合成基孔肯雅病毒非结构蛋白基因;对测序的克隆进行序列比对,分析不同克隆上缺失突变发生的位置,以保守区域互相重叠的寡核苷酸为上下游引物、以该区域测序正确的克隆为模板进行PCR扩增,得到所需片段,再将这些片段用PCR方法进一步组装成完整的基因序列并进行测序。结果:测序结果表明,经过2次PCR扩增,校正了基孔肯雅病毒非结构蛋白基因合成过程中发生的5个位点缺失突变。结论:得到序列正确的基孔肯雅病毒非结构蛋白基因。在进行基因合成过程中如发生多位点缺失突变,可利用该方法同时对以上突变进行校正,无须再合成引物,降低了实验操作难度,并提高了实验效率。     

人癌细胞内质网分子伴侣Grp94基因近3′端的初步分析

采用PCR及RT－PCR方法结合核酸分子杂交技术,首次确定了与Grp94cDNA2231～2500碱基片段对应的Grp94基因序列上有内含子．含有内含子的扩增片段长约708bP．对三种癌细胞系进行了PCR和RT－PCR反应,电泳结果显示存在差异．研究结果为进一步探讨Grp94基因3'端精细结构及其在正常细胞和肿瘤细胞中表达的改变打下了基础．     

胰岛素样生长因子1(IGF-1)mRNA同源模板竞争性PCR定量方法的建立

胰岛素样生长因子 1(IGF 1)是一种多功能的细胞增殖调控因子 ,其表达水平受多种因素的影响 ,为了研究IGF 1基因在转录水平上的调控机制 ,建立了定量测定IGF 1mRNA的竞争性PCR方法 .同时 ,也建立了一种简便的制备同源性竞争模板的方法 .以构建好的重组pUC IGF 1质粒为基础 ,利用IGF 1mRNA序列上唯一存在 ,但是在pUC18质粒上多拷贝的MspⅠ酶切位点 ,以该限制性内切酶处理重组pUC IGF 1质粒 .在T4DNA连接酶作用下对酶切产物进行随机连接 ,以连接产物作为模板 ,用可扩增IGF 1cDNA的引物进行PCR ,由此得到因含有随机插入序列而与原IGF 1cDNA产生明显长度差别的重组IGF 1.以不同浓度的该DNA片段作为同源竞争模板与大鼠肝组织cDNA在同一反应体系中进行PCR ,对PCR产物进行分析 ,计算出样本中IGF 1cDNA的初始浓度 .成功地建立了IGF 1mRNA的竞争性PCR定量检测方法 ,为研究IGF 1基因的表达调控奠定了基础 ,同时也为对已克隆的基因进行mRNA定量测定提供了一种简便和灵敏的手段     

The human ribosomal protein S6 gene: isolation, primary structure and location in chromosome 9.

Using PCR cloning we isolated the first intron of the human ribosomal protein S6 gene (hRPS6). By screening the human HeLa cell cDNA library in lambda ZAPII vector (Stratagene, La Jolla, CA), we identified and sequenced a partially spliced pre mRNA copy of hRPS6. The complete hRPS6 gene was isolated from a lambda DASH library with an intron-specific probe. The gene and flanking regions were sequenced, and the mRNA 5' end was mapped by primer extension experiments. The hRPS6 gene has 6 exons and 5 introns and is 3.6 kb long. Using intron-specific primers in PCR and a panel of human-hamster cell lines we localized the hRPS6 gene in human chromosome 9.     

RT—PCR测定mRNA的荧光定量分析

利用反转录毛细管ＰＣＲ技术,可合成代表特异ｍＲＮＡ的双链ＤＮＡ。在一定循环数内,ＰＣＲ产物的量与其模板ｃＤＮＡ即反转录中相应ｍＲＮＡ的浓度有关。溴乙锭嵌入ＤＮＡ双螺旋后,其荧光量子产率大为增加,因此可通过利用处在适当ＰＣＲ循环数中的ｃＤＮＡ浓度与在优选的激发光谱发现射波长下其荧光强度的线性关系,计算出所检测的ｍＲＮＡ表达量。     

Apoptotic endonuclease EndoG regulates alternative splicing of human telomerase catalytic subunit hTERT

Human telomerase catalytic subunit hTERT is subjected to alternative splicing results in loss of its function and leads to decrease of telomerase activity. However, very little is known about the mechanism of hTERT pre-mRNA alternative splicing. Apoptotic endonuclease EndoG is known to participate this process. The aim of this study was to determine the role of EndoG in regulation of hTERT alternative splicing. Increased expression of β-deletion splice variant was determined during EndoG overexpression in CaCo-2 cell line, after EndoG treatment of cell cytoplasm and nuclei as well as after nuclei incubation with EndoG digested cell RNA. hTERT alternative splicing was induced by 47-mer RNA oligonucleotide in naked nuclei and in cells after transfection. Identified long non-coding RNA, that is the precursor of 47-mer RNA oligonucleotide. Its size is 1754 nucleotides. Based on the results the following mechanism was proposed. hTERT pre-mRNA is transcribed from coding DNA strand while long non-coding RNA is transcribed from template strand of hTERT gene. EndoG digests long non-coding RNA and produces 47-mer RNA oligonucleotide complementary to hTERT pre-mRNA exon 8 and intron 8 junction place. Interaction of 47-mer RNA oligonucleotide and hTERT pre-mRNA causes alternative splicing.     

TaqMan荧光定量RT-PCR检测水稻RAcl基因mRNA方法的建立

构建包含RAcl基因cDNA片段的质粒,作为水稻肌动蛋白基因RAcl之mRNA定量检测的标准品,建立检测方法,为水稻其他基因的定量建立内参。从水稻叶总RNA中逆转录扩增总cDNA,PCR扩增RAcl基因中设计的目的片段,将纯化的目的片段与pMD19-T Simple载体进行连接,转化宿主菌JM-109,提取重组质粒DNA,PCR鉴定并测序分析。纯化质粒并检测260nm吸光值,确定重组质粒原液的拷贝浓度并以此制备荧光定量PCR梯度浓度标准品,进行实时荧光定量PCR实验。建立了RAcl基因mRNA表达实时荧光定量PCR检测方法,特异性好,检测灵敏度达102拷贝,线性范围为102—1护拷贝,阈值循环数（Ct）与PCR体系中起始模板量的对数值之间有着良好的线性关系（r=1．000）,扩增效率高（E=98．2％）。建立了基因RAcl实时定量PCR的质粒标准品。     

Developmental Changes in the Differential Expression of Two Serotonin 5-HT3 Receptor Splice Variants in the Rat

Abstract: PCR was used to isolate identical partial cDNA clones encoding a serotonin 5-HT₃ receptor subunit from rat nodose and superior cervical ganglia. The amino acid sequence predicted from these clones, extending from the putative transmembrane domain I to the stop codon, demonstrated a 93% homology with the 5-HT₃ receptor A (R-A) subunit cloned from NCB 20 hybridoma mouse neuroblastoma/Chinese hamster embryonic brain cells. Comparison of the sequences of the rat gene and cDNA encoding this subunit revealed a five amino acid deletion, GSLLP, located within the putative second intracellular loop of the receptor subunit. This deletion was shown to occur at an intron/exon junction. Therefore, alternative splicing was probably responsible for the presence of short (5-HT₃ R-A_S) and long (5-HT₃ R-A_L) forms of 5-HT₃ R-A mRNA in these ganglia. PCR experiments, with specific primers located upstream and downstream of the GSLLP deletion, were used to detect reverse transcribed 5-HT₃ R-A mRNAs. A short fragment (92 bp), corresponding to the deleted form, and a long fragment (107 bp), corresponding to the nondeleted form, were amplified from various regions of the CNS and peripheral ganglia of the rat, as well as from NG108-15 hybridoma cells. In the adult rat, the ratio of the two forms varied very little from one tissue to another, the long form corresponding to only ～10% of the total 5-HT₃ R-A mRNA. Study of their respective distributions during ontogeny demonstrated a differential expression of the short and long forms in some tissues during late embryonic development, at embryonic day 17 (E17) or E20. In particular, the long form amounted to about one-third of the total 5-HT₃ R-A mRNA in the cerebral cortex and hippocampus at E17, and this proportion reached 50 and 75% in the superior cervical ganglion and nodose ganglion, respectively, at E20. These data indicate that alternative splicing of the 5-HT₃ R-A mRNA is regulated in the CNS and PNS during development in the rat.