用PCR扩增和克隆鸡传染性贫血病毒全基因组DNA

根据已发表的序列,分别在鸡贫血病毒（ＣＡＶ）环形基因组ＤＮＡ（全长２．３ｋｂ）的ＥｃｏＲＩ位点和ＢａｍＨＩ位点的两侧选择适当序列合成两对引物,用ＰＣＲ技术,从斑点杂交检测到病毒核酸的ＣＡＶ感染的ＭＤＣＣＲＰ１细胞基因组ＤＮＡ中,分别扩增出包含ＥｃｏＲＩ和ＢａｍＨＩ分割开的病毒基因组两部分（１．５ｋｂ和０．８ｋｂ）约１．５ｋｂ和约１．２５ｋｂ的两个片段。再将其中相应序列拼接克隆进ｐＵＣ１８载体,获得包含ＣＡＶ全基因组序列ＤＮＡ片段的克隆质粒ｐＣＡＶ２．４。酶切分析表明,该质粒具有预期的ＢａｍＨＩ位点、ＰｓｔＩ位点、ＨｉｎｄⅢ位点,而预期的ＥｃｏＲＩ位点消失。重组质粒插入ＤＮＡ片段的两端序列分析表明,质粒ｐＣＡＶ２．４是包含ＣＡＶ全基因组序列的重组质粒,插入ＤＮＡ片段序列中的ＥｃｏＲＩ位点序列发生了一个碱基突变。     

黄瓜线粒体类质粒pC1,pC4在品种间的分布及同源性研究

在黄瓜（津研四号）线粒体中存在4种线粒体类质粒（pCl,pC2,pC3,pC4),对14个黄瓜品种的线粒体类质分布情况进行了研究,发现在津春二号,津春五号,津新密刺,津绿四号和津研四吃5个品种中存在线粒体类质粒,其余9个品种无线粒体类质粒,类质粒的存在有一定随机性,不同品种中的同一种类质粒间具有同源性,pC4类质粒不仅与自身的核DNA同源,也与其他品种的核基因组有同源性,pC4同源序列在黄瓜核基因组中为多拷贝的,拷贝之间是不连续的,在丝瓜和西葫芦的核基因组中也有pC4的同源序列,因此,推测pC4可能在葫芦科分化的早期就已存在并整合于核中,某些品种缺乏类质粒是由于在进化过程中发生的类质粒的丢失。     

丙型肝炎病毒E2基因DNA免疫实验动物研究

将编码丙型肝炎病毒（ＨＣＶ）Ｅ２蛋白４１７～７５０位氨基酸的ＤＮＡ片段　克隆到真核表达载体ｐｃＤＮＡ　３．１（－）中的ＣＭＶ　ＩＥ启动子下游,构建成ＨＣＶ　Ｅ２重组真核表达质粒　ｐｃＥ２。ＥＬＩＳＡ法检测ｐｃＥ２　ＤＮＡ免疫兔血清中的Ｅ２抗体变化和维持规律,结果显示免疫２０ｄ已有　抗体产生,３０ｄ后开始进入高峰,４０ｄ时达到最高值,至第９０ｄ抗体水平保持平稳,抗体滴度　达到１∶１６００左右。流式细胞计数仪（ＦＡＣＳ）检测ｐｃＥ２　ＤＮＡ免疫鼠ＣＤ４＋、ＣＤ８＋Ｔ淋巴细胞变　化情况,与注射空载体ｐＣＤＮＡ３．１（－）的阴性鼠相比,ＣＤ４＋淋巴细胞水平略有上升,ＣＤ８＋　细胞水平有较大升高,增幅达３５．４６％。免疫组化检测结果显示注射ｐｃＥ２的小鼠组织中有明显　的阳性着色,而注射ｐｃＤＮＡ３．１（－）的对照组小鼠免疫组化结果为阴性。以上结果表明：ｐｃＥ２　在实验动物内表达出的ＨＣＶ　Ｅ２蛋白可以引起免疫动物的体液免疫应答和细胞免疫应答,尤其　是ＭＨＣ－１限制性杀伤性ＣＤ８＋Ｔ淋巴细胞水平的提高对清除　病毒是十分有利的,因此ＨＣＶ　Ｅ２　ＤＮＡ免疫有可能成为预防和治疗ＨＣＶ感染的一条新途径。     

破伤风霉素C片段基因克隆,重组表达及免疫原性研究

应用ＰＣＲ技术从破伤风梭状芽孢杆菌ＤＮＡ中扩增出１．４ｋｂ ＤＮＡ基因,将其克隆到ｐＣＵ１８质粒中,经测序证明该ＤＮＡ片段为破伤风片段Ｃ的基因,并将此基因片段亚克隆到时ｐＧＥＸ－４５－２,构建成表达质粒ｐＧＥＸ－ＴＣ,在Ｅ．ｃｏｌｉ中进行表达。     

柯萨奇B3病毒结构和非结构蛋白基因重组质粒的构建及其在体外真核细胞中的

制备ＣＶＢ３结构蛋白和非结构蛋白重组质粒ＤＮＡ疫苗时,采用ＲＴ－ＰＣＲ从ＣＶＢ感染的ＨｅＬａ细胞中扩增ＶＰ１、ＶＰ２、２Ａ和３Ｄ基因,重组入真核表达质粒ｐｃＤＮＡ３中,构建ｐｃＤＮＡ３／ＶＰ２、ｐｃＤＮＡ３／ＶＰ１、ｐｃＤＮＡ３／２Ａ和ｐｃＤＮＡ３／３Ｄ重组质粒,经酶切和测下实扩增的序列并将各重组质粒体外转染真核细胞ＣＯＳ－７,用ＲＴ－ＰＣＲ检测ｍＲＮＡ的转录,用Ｗｅｓｔｅｒｎ－ｂｌｏｔ检测表达产物。结果４种重组质粒酶切出相应大小的目的片段,经测序证实为ＣＶＢ３相应序列,Ｗｅｓｔｅｒｎ－ｂｌｏｔ证实能够在体外真核细胞中表达。本文成功构建ＣＶＢ３结构与非结构蛋白的重组质粒ＤＮＡ疫苗,为进一步研究其免疫效果奠定了基础。     

绿色木霉纤维素酶CBHⅡ基因的结构研究

实验经限制性酶切和双向Ｓｏｕｔｈｅｒｎ杂交将重组质粒ｐＣＢＨＩＩ－１４的１４ｋｂ外源片段上的绿色木霉纤维素酶ＣＢＨＩＩ基因定位于４．４ｋｂ的ＥｃｏＲＩ片段上,将该片段克隆于质粒ｐＵＣ１９,获得重组质粒ｐＣＢＨＩＩ。通过限制性分析构建了ｐＣＢＨＩＩ上４．４ｋｂＥｃｏＲＩ片段的物理图谱。在此基础上用质粒制作该片段的亚克隆,采用Ｓａｎｇｅｒ双脱氧链终止法测定了含绿色木霉纤维素酶ＣＢＨＩＩ基因的４０７４ｂｐ的ＤＮＡ序列,由ＧＴ－ＡＧ规则和ｃＤＮＡ序列推知该结构基因由４个外显子和３个内含子组成,总长１６１３ｂｐ,５′端存在与一般真核基因类似的两个特征性调控序列,但３′端不存在真核基因通常具有的特征序列而存在功能未明的短重复序列和嘧啶富集区。并对纤维素酶基因间的同源性和可能的功能作了初步的探讨。     

Ti质粒介导的磷酸烯醇式丙酮酸羧化酶cDNA转化烟草植株

将玉米Ｃ４－磷酸烯醇式丙酮酸羧化酶（ＰＥＰ羧化酶）ｃＤＮＡ亚克隆至穿梭质粒ｐＢｉｎ１９,通过在杆菌Ｔｉ质粒（ＬＢＡ４４０４）介导的时圆片共培养法将其转入Ｃ３植物烟草中。在获得的抗性转化植株中,８０％具有较强的ＮＰＴⅡ报道基因表达。Ｓｏｕｔｈｅｒｎ杂交表明Ｃ４－ＰＥＰ羧化酶ｃＤＮＡ已被整合到了烟草核基因组中。     

人vigilin基因5'端调控区域的研究

在克隆了人基因组全长ｖｉｇｉｌｉｎ基因的基础上,对其５端转录调控区域再克隆,获得Ｖｉｇ－ＣＧ５－７Ｅ克隆,再用限制酶ＡｐａⅠ和ＥｃｏＲⅠ切除３端约４ｋｂ部分,得到Ｖｉｇ－ＣＧ５－７Ｅ３ＡＥ克隆,并对该克隆进行双向测序分析．结果表明：克隆Ｖｉｇ－ＣＧ５－７Ｅ用ＡｐａⅠ酶消化后,用ｃＤＮＡ上游开始的２０个碱基组成的寡聚核苷酸做探针进行分子杂交,可见一条小于０．１ｋｂ杂交带,根据物理图谱分析,位于Ｖｉｇ－ＣＧ５－７Ｅ３ＡＥ克隆的ＡｐａⅠ端,从而推断该克隆含有转录调控元件,５端序列分析得到二个ＴＡＴＡ盒,一个ＣＡＡＴ盒和一个ＧＣ盒以及二个可能的Ａｐ－１和Ａｐ－２结合位点．认为ＧＣ盒可能为人ｖｉｇｉｌｉｎ基因启动子的组成部分     

水稻齿叶矮缩病毒Segment 9 dsRNA的序列分析及其在大肠杆菌DE3中的表达

通过有机试剂抽提,ＣＦ－１１纤维素柱层析,从感染水稻齿叶矮缩病毒菲律宾分离株（ＲｉｃｅＲａｇｇｅｄＳｔｕｎｔＶｉｒｕｓ,Ｐｈｉｌｉｐｐｉｎｅｉｓｏｌａｔｅ,简称ＲＲＳＶ－Ｐ）的水稻植株中获取该病毒的全基因组,即获得从Ｓｅｇｍｅｎｔ１到Ｓｅｇｍｅｎｔ１０（Ｓ１－Ｓ１０）的１０条双链ＲＮＡ（ｄｓＲＮＡ）,然后设计合适的引物,用ＲＴ－ＰＣＲ方法得到Ｓ９的ｃＤＮＡ并将其克隆到ｐＵＣ１１９质粒上扩增,以双链测序法测定该ｃＤＮＡ的全序列。同时又将此ｃＤＮＡ克隆到大肠杆菌表达质粒ｐＧＥＸ－３Ｘ上,在大肠杆菌菌株ＤＥ３中用ＩＰＴＧ诱导表达,经超声波破菌、离心、Ｇｌｕｔａｔｈｉｏｎｅ－ｓｅｐｈａｒｏｓｅ４Ｂ亲和层析,得到纯化的分子量为６４ｋＤ的融合蛋白。     

耐热芽孢杆菌E2菌株纤维素酶基因克隆的研究

用质粒ｐＢＲ３２２作载体,大肠杆菌Ｅ．ｃｏｌｉ ＤＨ５αＦ’作受体,克隆到耐热孢杆菌Ｅ２菌株的羧甲基纤维素酶基因。重组质粒ＰＢＧ３从产生ＣＭＣａｓｅ的转化子中分离得到。克隆到的ＣＭＣａｓｅ基因位于４．０ｋｂＨｉｎｄⅠⅠⅠ片段上。功能状态ＣＭＣａｓｅ基因被亚克隆到２．４ｋｂＤＮＡ片段上。     

Properties of the Circular Plasmid-like DNA Bl from Mitochondria of Cytoplasmic Male-sterile Rice

Mitochondrial DNA from suspension-cultured cells of the cytoplasmicmale-sterile rice line, A-58 CMS, was shown to contain fourminicircular DNAs. We chose for further examination the largestminicircular DNA, designated Bl. A molecular clone containingthe complete sequence of Bl was constructed and used to probemitochondrial and nuclear genomes by Southern hybridization.No evidence was found for the existence of integrated copiesof Bl in the main mitochondrial genomes of either male-sterileor fertile rice. Sequences homologous to Bl, however, were foundin nuclear genomes of both the male-sterile and the fertilerice. The complete nudeotide sequence of Bl (2,135 bp) was determined,and found to contain sequences homologous to those in the 1,913bp plasmid-like DNA of maize. (Received May 15, 1987; Accepted July 20, 1987)     

Small, repetitive DNAs contribute significantly to the expanded mitochondrial genome of cucumber

Closely related cucurbit species possess eightfold differences in the sizes of their mitochondrial genomes. We cloned mitochondrial DNA (mtDNA) fragments showing strong hybridization signals to cucumber mtDNA and little or no signal to watermelon mtDNA. The cucumber mtDNA clones carried short (30-53 bp), repetitive DNA motifs that were often degenerate, overlapping, and showed no homology to any sequences currently in the databases. On the basis of dot-blot hybridizations, seven repetitive DNA motifs accounted for >13% (194 kb) of the cucumber mitochondrial genome, equaling >50% of the size of the Arabidopsis mitochondrial genome. Sequence analysis of 136 kb of cucumber mtDNA revealed only 11.2% with significant homology to previously characterized mitochondrial sequences, 2.4% to chloroplast DNA, and 15% to the seven repetitive DNA motifs. The remaining 71.4% of the sequence was unique to the cucumber mitochondrial genome. There was <4% sequence colinearity surrounding the watermelon and cucumber atp9 coding regions, and the much smaller watermelon mitochondrial genome possessed no significant amounts of cucumber repetitive DNAs. Our results demonstrate that the expanded cucumber mitochondrial genome is in part due to extensive duplication of short repetitive sequences, possibly by recombination and/or replication slippage.     

A putative gene of tobacco chloroplast coding for ribosomal protein similar to E. coli ribosomal protein S19.

A partial sequence of a cloned 3.2 Md BamHI fragment from tobacco chloroplast DNA revealed the occurrence of a putative gene for ribosomal protein. The putative gene is located on the left margin of the large single-copy region in the chloroplast DNA. The coding region contains 276 bp (92 codons). The amino acid sequence deduced from the DNA sequence shows 55% homology with that of E. coli S19 (91 amino acid residues).     

Terminal protein association and sequence homology in linear mitochondrial plasmid-like DNAs of sorghum and maize

The linear extrachromosomal mitochondrial plasmid-like DNAs from the Ru cytoplasm of maize, and M35-1 and IS1112C cytoplasms of sorghum, possess 5 terminally-attached proteins. These molecules required proteinase K treatment for mobility in agarose gels and were susceptible to exonuclease III but not lambda exonuclease cleavage. Hybridizations, under stringent conditions, indicated that the sorghum plasmid-like DNAs, N1 and N2, did not possess DNA sequence homology to cloned central regions of S1 and S2, the linear mitochondrial plasmid-like DNAs present in S cytoplasm of maize. In addition, a novel 4.2kb, DNAase sensitive, RNAase insensitive band, exhibiting homology to internal sequences from maize S2, was observed in the sorghum IS1112C cytoplasm only.     

Nuclear genes encoding the yeast mitochondrial ATPase complex. Analysis of ATP1 coding the F1-ATPase alpha-subunit and its assembly

Mitochondria prepared from the yeast nuclear pet mutant N9-84 lack a detectable F1-ATPase activity. Genetic complementation of this mutant with a pool of yeast genomic DNA in the yeast Escherichia coli shuttle vector YEp13 restored its growth on a nonfermentable carbon source. Mitochondria prepared from the transformed host contained an 8-fold higher than normal level of the F1 alpha-subunit and restored ATPase activity to 50% that of the wild-type strain. Deletion and nucleotide sequence analysis of the complementing DNA on the plasmid revealed a coding sequence designated ATP1 for a protein of 544 amino acids which exhibits 60 and 54% direct protein sequence homology with the proton-translocating ATPase alpha-subunits from tobacco chloroplast and E. coli, respectively. In vitro expression and mitochondrial import experiments using this ATP1 sequence showed that additional amino-terminal sequences not present in the comparable plant and bacterial subunits function as transient sequences for import.     

A yeast nuclear gene, MRS1, involved in mitochondrial RNA splicing: nucleotide sequence and mutational analysis of two overlapping open reading frames on opposite strands.

We have cloned a 1.6-kb fragment of yeast nuclear DNA, which complements pet- mutant MK3 (mrs1). This mutant was shown to be defective in mitochondrial RNA splicing: the excision of intron 3 from the mitochondrial COB pre-RNA is blocked. The DNA sequence of the nuclear DNA fragment revealed two open reading frames (ORF1 with 1092 bp; ORF2 with 735 bp) on opposite strands, which overlap by 656 bp. As shown by in vitro mutagenesis, ORF1, but not ORF2, is responsible for complementation of the splice defect. Hence, ORF1 represents the nuclear MRS1 gene. Disruption of the gene (both ORFs) in the chromosomal DNA of the respiratory competent yeast strain DBY747 (long form COB gene) leads to a stable pet- phenotype and to the accumulation of the same mitochondrial RNA precursors as in strain MK3. The amino acid sequence of the putative ORF1 product does not exhibit any homology with other known proteins, except for a small region of homology with the gene product of another nuclear yeast gene involved in mitochondrial RNA splicing, CBP2. The function of the MRS1 (ORF1) gene in mitochondrial RNA splicing and the significance of the overlapping ORFs in this gene are discussed.     

Novel structure of the recA locus of Mycobacterium tuberculosis implies processing of the gene product.

A fragment of Mycobacterium tuberculosis DNA containing recA-like sequences was identified by hybridization with the Escherichia coli recA gene and cloned. Although no expression was detected from its own promoter in E. coli, expression from a vector promoter partially complemented E. coli recA mutants for recombination, DNA repair, and mutagenesis, but not for induction of phage lambda. This clone produced a protein which cross-reacts with antisera raised against the E. coli RecA protein and was approximately the same size. However, the nucleotide sequence of the cloned fragment revealed the presence of an open reading frame for a protein about twice the size of other RecA proteins and the cloned product detected by Western blotting (immunoblotting). The predicted M. tuberculosis RecA protein sequence was homologous with RecA sequences from other bacteria, but this homology was not dispersed; rather it was localized to the first 254 and the last 96 amino acids, with the intervening 440 amino acids being unrelated. Furthermore, the junctions of homology were in register with the uninterrupted sequence of the E. coli RecA protein. Identical restriction fragments were found in the genomic DNAs of M. tuberculosis H37Rv and H37Ra and of M. bovis BCG. It is concluded that the ancestral recA gene of these species diversified via an insertional mutation of at least 1,320 bp of DNA. Possible processing mechanisms for synthesizing a normal-size RecA protein from this elongated sequence are discussed.     

Isolation and Characterization of Two Saccharomyces Cerevisiae Genes Encoding Homologs of the Bacterial Hexa and Muts Mismatch Repair Proteins

Homologs of the Escherichia coli (mutL, S and uvrD) and Streptococcus pneumoniae (hexA, B) genes involved in mismatch repair are known in several distantly related organisms. Degenerate oligonucleotide primers based on conserved regions of E. coli MutS protein and its homologs from Salmonella typhimurium, S. pneumoniae and human were used in the polymerase chain reaction (PCR) to amplify and clone mutS/hexA homologs from Saccharomyces cerevisiae. Two DNA sequences were amplified whose deduced amino acid sequences both shared a high degree of homology with MutS. These sequences were then used to clone the full-length genes from a yeast genomic library. Sequence analysis of the two MSH genes (MSH = mutS homolog), MSH1 and MSH2, revealed open reading frames of 2877 bp and 2898 bp. The deduced amino acid sequences predict polypeptides of 109.3 kD and 109.1 kD, respectively. The overall amino acid sequence identity with the E. coli MutS protein is 28.6% for MSH1 and 25.2% for MSH2. Features previously found to be shared by MutS homologs, such as the nucleotide binding site and the helix-turn-helix DNA binding motif as well as other highly conserved regions whose function remain unknown, were also found in the two yeast homologs. Evidence presented in this and a companion study suggest that MSH1 is involved in repair of mitochondrial DNA and that MSH2 is involved in nuclear DNA repair.