油菜叶绿体16SrRNA基因的一级结构分析

本文报道了油菜叶绿体16S rRNA基因的全顺序及其5′端上游的156bp和3′端下游的101bp的核苷酸顺序。油菜叶绿体16s rRNA基因长为1491bp,和烟草、玉米相比,同源程度分别为98.5％、96.1％。油菜叶绿体16S rRNA基因5′端上游及3′端下游的顺序能互补而形成一个较大的茎环结构,但与烟草相比,由于3′端下游顺序有79bp的缺失,因此,该结构中的茎部分大小仅为烟草的二分之一。     

叶绿体4.5SrRNA——Ⅱ基因与起源

在植物叶绿体中,rRNA 基因的排列顺序与原核生物大肠杆菌和蓝绿藻的 rRNA 基因排列顺序相似:16S rDNA—间隔顺序—23S rDNA—间隔顺序—5 S rDNA。在高等植物叶绿体中,在23S rDNA 的3′下游端和5SrDNA的5′上游端之间的间隔顺序内,还存在着4.5 S     

蓖麻蚕18S rRNA基因3′末端的顺序特征

本文测定了蓖麻蚕18S rRNA基因(rDNA) 3′末端及其外侧的DNA顺序。将这一顺序与家蚕、果蝇、大鼠 18S rDNA 3′末端顺序以及大肠杆菌16 S rDNA 3′末端顺序作了比较,发现它们间有惊人的同源性。不仅如此,这些基因的3′末端所形成的茎环结构也十分相似,在3′末端还有保守的EcoRI切点。这些研究结果对了解18S rRNA 3′末端在蛋白质合成中的功能及在rRNA前体加工成熟中的作用;对于了解rRNA基因的进化打下了基础。     

蓖麻蚕5.8S rRNA基因的结构特点

利用计算机分析已知的蓖麻蚕(Attacus ricini)5.8S rRNA顺序,发现其上有一个PstⅠ位点。因此,将rDNA上PstⅠ位点两侧的DNA片段分别克隆在pWR 13质粒上。用末端终止法测定了蓖麻蚕5.8S rRNA基因全顺序及与之相邻的上、下游部分核苷酸顺序。发现5.8SrRNA基因3′端为pGGGCCGGCT_(OH)。这个结果与Feng,Y.X.等报道的蓖麻蚕5.8S rRNA顺序3′端是pGGGCCGAUUAA_(OH)有两个明显不同:第一,从共同顺序pGGGCCG算起,5.8S rRNA基因的3′端有九个核苷酸,比Feng Y.X.等报道的rRNA顺序3′端少两个核苷酸;第二,两者在3′末端共同顺序以后的两个核苷酸是不一样的。此外,还发现在蓖麻蚕5.8S rRNA基因上游有一个约30个核苷酸的poly(A)区。     

鲤鱼线粒体tRNA~(Cys)基因和轻链复制起始区的结构分析

我们测定了鲤鱼线粒体半胱氮酸tRNA 基因和轻链(L 链)复制起始区的核苷酸序列,绘制了半胱氨酸tRNA 三叶草形的二级结构以及L 链复制区的茎环结构。通过五种脊椎动物tRNA~(cya)基因的核苷酸序列分析发现,鲤鱼线粒体tRNA~(cya)基因有许多不同于细胞质tRNA~(cya)基因的不寻常的结构特点。鲤鱼线粒体L 链复制起始区含有36个碱基,复制起始区茎环结构中的茎含有11对碱基,而环则是由14个碱基组成。同其它10种脊椎动物L-链复制起始区的核苷酸序列比较发现,鲤鱼茎环结构中的茎序列是非常保守的,而环的序列及环的长度则变化较大。茎环结构可能在轻链复制中起着重要的作用。     

用S1核酸酶作图法测定蓖麻蚕18S rRNA基因的5′端位置

测定基因5′端位置是研究基因转录调控的一个重要前提。本文将蓖麻蚕18S rRNA基因DNA的5′端用~(32)P标记,然后与18S rRNA杂交,再用S1核酸酶水解掉非杂交区的DNA和RNA。分析放射自显影的结果,测出18S rRNA基因5′端的位置。在18S rRNA基因的BglⅡ_2位点向EcoRⅠ,方向延伸约220bp处,从这一结果,可知道蓖麻蚕rRNA基因的转录方向是5′EcoRⅠ_2→BglⅡ_23′。     

芹菜(Apium graveolens L.)叶绿体4.5S rRNA的序列分析及与其它植物4.5S rRNA的比较

 本文应用RNA序列分析直读技术测定了芹菜叶绿体核糖体4.5rRNA核苷酸顺序;5’_(OH)GAA GGUCACGGUGAGACGA GCCGUUUAUCA UUACGAUAGGUGUCUAGUGGAAGUGCAGU G AUGUAUGCA G CUGAGGCAUC CUAACAGACCGGCAGAUUU GAAC_(OH)3’。由103个核苷酸组成,5’-末端木磷酸化,与已知的几种植物叶绿体4.5S rRNA序列进行了同源性比较,发现不同植物4.5S rRNA序列之间有很大的保守性。我们在芹菜4.5S rRNA一级结构的基础上按碱基最大配对原则绘出了其二级结构。     

地山雀线粒体基因组全序列的测定和分析

基于长距PCR扩增及保守引物步移法测定并注释了地山雀(Pseudopodoces humilis)的线粒体基因组全序列.结果表明,地山雀线粒体基因组全长1.6 809万bp,A+T含量为52.9%,37个基因排列顺序与红原鸡一致.蛋白质基因的起始密码子中,除COI基因为GTG外,其余均为ATG.NDⅠ和ND5基因终止密码子为AGA:COⅡ基凶为AGG:COⅢ和ND4基因为不完全终止密码子T;其余基因均为典型的TAA或TAG.预测了22个tRNA基闪的二级结构,发现tRNAScr(AGN)缺少DHU臂,tRNAPhe的TψC臂存在一单核苷酸插入.预测的地山雀12S和16S rRNA二级结构分别包括3个结构域47个茎环和6个结构域60个茎环. 控制区位于tRNAGlu和tRNAPhe之间,长度1240 bp.控制区结构为高变Ⅰ区、中央保守Ⅱ区和保守序列Ⅲ区3个结构域.     

猪繁殖与呼吸综合征病毒S1株基因组序列测定和分析

应用RT-PCR方法分段扩增出PRRSV上海分离株S1毒株的4条基因大片段,扩增后的产物分别克隆于pCR-XL-TOPO载体鉴定后测序,同时应用RACE方法对S1毒株的3′和5′基因末端进行了成功的扩增并克隆于pMD-18T载体进行测序,按顺序将这些序列进行拼接得到PRRSVS1株全基因组cDNA序列。测序结果表明PRRSVS1株基因组全长15441bp,包含9个开放式阅读框,5′UTR含有189nt,3′端UTR含有181nt,其中包含30ntPoly(A)。基因组序列分析结果显示该病毒与ATCCVR-2332和BJ-4分离株的核苷酸同源性分别99.5%和99.6%。与另一国内分离株CH-1a的核苷酸同源性为90.8%。     

凡纳滨对虾DNaseⅠ基因的克隆及原核表达

利用RT-PCR和RACE技术,从凡纳滨对虾(Litopenaeus vannamei)肝胰腺中克隆了DNaseⅠ基因的全长cDNA序列。该序列全长1614bp,包含1209bp的开放阅读框,编码一个含403个氨基酸的蛋白;5′非翻译区为116bp,3′非翻译区为289bp。实时定量PCR分析结果表明,DNaseⅠ基因在肝胰腺的表达量是其他器官表达量的16～162倍,表明凡纳滨对虾DNaseⅠ基因属于胰腺型表达。本研究还利用酶切重组构建原核表达载体,并在大肠杆菌(Escherichia coli)中成功表达出了有活性的重组DNaseⅠ蛋白。     

Transposition of an intron in yeast mitochondria requires a protein encoded by that intron

The optional 1143 bp intron in the yeast mitochondrial 21S rRNA gene (omega +) is nearly quantitatively inserted in genetic crosses into 21S rRNA alleles that lack it (omega -). The intron contains an open reading frame that can encode a protein of 235 amino acids, but no function has been ascribed to this sequence. We previously found an in vivo double-strand break in omega - DNA at or close to the intron insertion site only in zygotes of omega + X omega - crosses that appears with the same kinetics as intron insertion. We now show that mutations in the intron open reading frame that would alter the translation product simultaneously inhibit nonreciprocal omega recombination and the in vivo double-strand break in omega - DNA. These results provide evidence that the open reading frame encodes a protein required for intron transposition and support the role of the double-strand break in the process.     

Characterization of the 23S and 5S rRNA genes of Coxiella burnetii and identification of an intervening sequence within the 23S rRNA gene.

Characterization of the rRNA operon from the obligate intracellular bacterium Coxiella burnetii has determined the order of the rRNA genes to be 16S-23S-5S. A 444-bp intervening sequence (IVS) was identified to interrupt the 23S rRNA gene beginning at position 1176. The IVS is predicted to form a stem-loop structure formed by flanking inverted repeats, and the absence of intact 23S rRNA molecules suggests that the loop is removed. An open reading frame in the IVS has been identified that shows 70% similarity at the amino acid level to IVS open reading frames characterized from four species of Leptospira.     

Nucleotide sequence and analysis of a gene encoding anthranilate synthase component I in Spirochaeta aurantia.

A Spirochaeta aurantia DNA fragment containing the trpE gene and flanking chromosomal DNA was cloned, and the sequence of the trpE structural gene plus 870 bp upstream and 1,257 bp downstream of trpE was determined. The S. aurantia trpE gene codes for a polypeptide of 482 amino acid residues with a predicted molecular weight of 53,629 that showed sequence similarity to TrpE proteins from other organisms. The S. aurantia TrpE polypeptide is not more closely related to the other published spirochete TrpE sequence (that of Leptospira biflexa) than to TrpE polypeptides of other bacteria. Two additional complete open reading frames and one partial open reading frame were identified in the sequenced DNA. One of the complete open reading frames and the partial open reading frame are upstream of trpE and are encoded on the DNA strand opposite that containing trpE. The other open reading frame is downstream of trpE and on the same DNA strand as trpE. On the basis of the results of a protein sequence data base search, it appears that trpE is the only tryptophan biosynthesis gene in the sequenced DNA. This is in contrast to L. biflexa, in which trpE is separated from trpG by only 64 bp.     

Molecular cloning and characterization of two lincomycin-resistance genes, ImrA and ImrB, from Streptomyces lincolnensls 78–11

Two different lincomycin-resistance determinants (lmrA and lmrB) from Streptomyces lincolnensis 78-11 were cloned in Streptomyces lividans 66 TK23. The gene lmrA was localized on a 2.16 kb fragment, the determined nucleotide sequence of which encoded a single open reading frame 1446 bp long. Analysis of the deduced amino acid sequence suggested the presence of 12 membrane-spanning domains and showed significant similarities to the methylenomycin-resistance protein (Mmr) from Streptomyces coelicolor, the QacA protein from Staphylococcus aureus, and several tetracycline-resistance proteins from both Gram-positive and Gram-negative bacteria, as well as to some sugar-transport proteins from Escherichia coli. The lmrB gene was actively expressed from a 2.7 kb fragment. An open reading frame of 837 bp could be localized which encoded a protein that was significantly similar to 23S rRNA adenine(2058)-N-methyltransferases conferring macrolide-lincosamide-streptogramin resistance. LmrB also had putative rRNA methyltransferase activity since lincomycin resistance of ribosomes was induced in lmrB-containing strains. Surprisingly, both enzymes, LmrA and LmrB, had a substrate specificity restricted to lincomycin and did not cause resistance to other lincosamides such as celesticetin and clindamycin, or to macrolides.     

DNA sequence and secondary structures of the large subunit rRNA coding regions and its two class I introns of mitochondrial DNA fromPodospora anserina

Summary DNA sequence analysis has shown that the gene coding for the mitochondrial (mt) large subunit ribosomal RNA (rRNA) fromPodospora anserina is interrupted by two class I introns. The coding region for the large subunit rRNA itself is 3715 bp and the two introns are 1544 (r1) and 2404 (r2) bp in length. Secondary structure models for the large subunit rRNA were constructed and compared with the equivalent structure fromEscherichia coli 23S rRNA. The two structures were remarkably similar despite an 800-base difference in length. The additional bases in theP. anserina rRNA appear to be mostly in unstructured regions in the 3 part of the RNA. Secondary structure models for the two introns show striking similarities with each other as well as with the intron models from the equivalent introns inSaccharomyces cerevisiae, Neurospora crassa, andAspergillus nidulans. The long open reading frames in each intron are different from each other, however, and the nucleotide sequence similarity diverges as it proceeds away from the core structure. Each intron is located within regions of the large subunit rRNA gene that are highly conserved in both sequence and structure. Computer analysis showed that the open reading frame for intron r1 contained a common maturase-like polypeptide. The open reading frames of intron r2 apeared to be chimeric, displaying high sequence similarity with the open reading frames in the r1 and ATPase 6 introns ofN. crassa.     

Nucleotide sequence of a novel kanamycin resistance gene, aphA-7, from Campylobacter jejuni and comparison to other kanamycin phosphotransferase genes

A novel kanamycin phosphotransferase gene, aphA-7, was cloned from a 14-kb plasmid obtained from a strain of Campylobacter jejuni and the nucleotide sequence of the gene was determined. The presumed open reading frame of the aphA-7 structural gene was 753 bp in length and encoded a protein of 251 amino acids with a calculated weight of 29,691 Da. A 29-kDa protein was demonstrated in Escherichia coli maxicells containing the cloned aphA-7 gene. A ribosomal binding site corresponding to 5 of 8 bases of the 3' end of the E. coli 16S rRNA was 8 bp upstream of the start codon. Sequences corresponding to the -35 and -10 regions of the consensus promoter sequences of E. coli were upstream of the presumed initiation codon of the gene. The DNA sequence was most closely related to the aphA-3 gene from Streptococcus faecalis, showing 55.4% sequence similarity. There was 45.6% identity at the amino acid level between the aphA-3 and the aphA-7 proteins. Of the three conserved regions noted previously in phosphotransferase genes, the aphA-7 amino acid sequence was identical to the six conserved amino acids in motif 3, but differed in one of the five conserved amino acids in motif 1 (if gaps are permitted) and 3 of the 10 conserved residues in motif 2. The 32.8% G + C ratio in the open reading frame of the aphA-7 kanamycin resistance gene, which is similar to that of the C. jejuni chromosome, suggests that the aphA-7 may be indigenous to Campylobacters.