Organization of the mitochondrial ribosomal RNA genes of maize.

The organisation of the mitochondrial ribosomal RNA genes in maize is described. Each of the rRNAs is encoded by a single gene. The 5S and 18S rRNA genes are close together, and separated from the 26S rRNA gene by 16 kb of DNA. There is no evidence of heterogeneity in this gene arrangement.     

Molecular structures of mitochondrial-DNA-like sequences in human nuclear DNA.

Two lambda phage clones carrying mitochondrial-DNA-like (mtDNA-like) sequences isolated from a human gene library were named Lm E-1 and Lm C-2, and their DNA structures were characterized. Lm E-1 contains about 0.4 kb DNA homologous to the 5' portion of the mitochondrial 16S ribosomal RNA (rRNA) gene and Lm C-2, a 1.6 kb DNA homologous to the 3' portion of the 12S rRNA gene and to almost all of the 16S rRNA gene. Comparisons of their nucleotide sequences with those of the corresponding regions of the human mtDNA revealed no detectable DNA rearrangement and their homologies to the human mtDNA are 84% and 80%, respectively. There are neither terminal repeats in the nuclear mtDNA-like sequences nor duplications of the nuclear DNAs flanking the mtDNA-like sequences. Evolutionary relationship between these two human nuclear mtDNA-like sequences and the human and bovine mtDNAs is discussed.     

基于18S rRNA和线粒体16S rRNA基因序列的柳蚕进化分析

为探讨柳蚕Actias selene Hübner与鳞翅目昆虫的系统发育关系,本研究利用PCR扩增获得了柳蚕核糖体18S rRNA和线粒体16S rRNA基因的部分序列,长度分别为391bp和428bp。并采用邻近距离法(NJ)、最大简约法(MP)、类平均聚类法(UPGMA)构建系统进化树。结果表明,柳蚕线粒体16SrRNA基因序列与大蚕蛾科昆虫的16SrRNA基因序列均表现出偏好于碱基AT的倾向。柳蚕与所研究的其它蚕类的遗传距离介于0.016至0.140之间,其中与温带柞蚕Antheraea roylii的遗传距离最小,与野桑蚕Bombyx mandarina的遗传距离最大。而基于鳞翅目昆虫18S rRNA基因部分序列的进化分析显示,柳蚕与柞蚕Antheraea pernyi之间的遗传距离最小(0.010),与蓖麻蚕Samia ricini的遗传距离最大(0.017)。     

Nucleotide sequence and evolution of the 18S ribosomal RNA gene in maize mitochondria.

The nucleotide sequence of the gene coding for the 18S ribosomal RNA of maize mitochondria has been determined and a model for the secondary structure is proposed. Dot matrix analysis has been used to compare the extent and distribution of sequence similarities of the entire maize mitochondrial 18S rRNA sequence with that of 15 other small subunit rRNA sequences. The mitochondrial gene shows great similarity to the eubacterial sequences and to the maize chloroplast, and less similarity to mitochondrial rRNA genes in animals and fungi. We propose that this similarity is due to a slow rate of nucleotide divergence in plant mtDNA compared to the mtDNA of animals. Sequence comparisons indicate that the evolution of the maize mitochondrial 18S, chloroplast 16S and nuclear 17S ribosomal genes have been essentially independent, in spite of evidence for DNA transfer between organelles and the nucleus.     

Sequence of the chloroplast 16S rRNA gene and its surrounding regions of Chlamydomonas reinhardii.

The sequence of a 2 kb DNA fragment containing the chloroplast 16S ribosomal RNA gene from Chlamydomonas reinhardii and its flanking regions has been determined. The algal 16S rRNA sequence (1475 nucleotides) and secondary structure are highly related to those found in bacteria and in the chloroplasts of higher plants. In contrast, the flanking regions are very different. In C. reinhardii the 16S rRNA gene is surrounded by AT rich segments of about 180 bases, which are followed by a long stretch of complementary bases separated from each other by 1833 nucleotides. It is likely that these structures play an important role in the folding and processing of the precursor of 16S rRNA. The primary and secondary structures of the binding sites of two ribosomal proteins in the 16SrRNAs of E. coli and C. reinhardii are considerably related.     

Paramecium mitochondrial genes. II. Large subunit rRNA gene sequence and microevolution

Mature Paramecium mitochondrial large subunit rRNA consists of two stable segments: a 20 S segment described previously and a unique 283-base segment similar to 5.8 S rRNAs typically found in eucaryotic cytoplasmic RNA. pBR325 clones of both gene regions from both Paramecium primaurelia and Paramecium tetraurelia were sequenced and aligned. The gene segments lie adjacent to each other very near the replicative terminal end of the linear Paramecium mitochondrial genome and are transcribed from a common 23 S precursor. The precise gene ends were determined using nuclease S1 protection; the large subunit rRNA gene complex (consisting of "5.8 S-like" rRNA, a 19-26-base excised region, and 20 S rRNA) spans about 2654 base pairs. The gene complex is preceded by a 15-base poly(T) tract and terminates randomly within a 20-base A + T-rich segment immediately preceding the tRNATyr gene. The sequences from the two species were 4% divergent, the changes consisting of 59% transitions, 38% transversions, and 3% insertions or deletions. The sequences were aligned with Escherichia coli 23 S rRNA, and a secondary structure model is presented for the entire molecule based on structures proposed for E. coli 23 S rRNA.     

Isolation of cDNA clones coding for mitochondrial 16S ribosomal RNA from the crustacean Artemia

cDNA clones coding for Artemia mitochondrial 16S ribosomal RNA (rRNA) have been isolated. The clones cover from nucleotide 650 of the RNA molecule to its 3' end. The comparison of Artemia sequence with both vertebrate and invertebrate mitochondrial 16S rRNA sequences has shown the existence of regions of high similarity between them. A model for the secondary structure of the 3' half of Artemia mitochondrial 16S rRNA is proposed. The size of the rRNA molecule has been estimated at 1.35 kb. Despite the similarity of the Artemia gene to insect rRNA in size, sequence and secondary structure, the G + C content of the Artemia gene (42%) is closer to that of mammals than to the insect genes. The number of mitochondria in Artemia has been estimated at 1500 per diploid genome in the cyst and 4000 in the nauplius. In contrast, the amount of mt 16S rRNA is constant at all stages of Artemia development.     

Horizontal transfer of segments of the 16S rRNA genes between species of the Streptococcus anginosus group

The nature in variation of the 16S rRNA gene of members of the Streptococcus anginosus group was investigated by hybridization and DNA sequencing. A collection of 708 strains was analyzed by reverse line blot hybridization. This revealed the presence of distinct reaction patterns representing 11 different hybridization groups. The 16S rRNA genes of two strains of each hybridization group were sequenced to near-completion, and the sequence data confirmed the reverse line blot hybridization results. Closer inspection of the sequences revealed mosaic-like structures, strongly suggesting horizontal transfer of segments of the 16S rRNA gene between different species belonging to the Streptococcus anginosus group. Southern blot hybridization further showed that within a single strain all copies of the 16S rRNA gene had the same composition, indicating that the apparent mosaic structures were not PCR-induced artifacts. These findings indicate that the highly conserved rRNA genes are also subject to recombination and that these events may be fixed in the population. Such recombination may lead to the construction of incorrect phylogenetic trees based on the 16S rRNA genes.     

Corrections to the human mitochondrial ribosomal RNA sequences

Two new errors and one consensus change were identified in the human mitochondrial Cambridge consensus sequence. The errors are an A to G substitution at nucleotide 750 in the 12S rRNA gene and a single nucleotide deletion at nt 3107 in the 16S rRNA gene. The consensus change is nt 2706 AG in the 16S rRNA gene.     

黑尾地鸦线粒体基因组序列测定与分析

采用长PCR扩增的线粒体DNA和引物步移法, 测定并注释了中国特有鸟类-黑尾地鸦(Podoces hendersoni)的线粒体基因组全序列。黑尾地鸦的mtDNA序列全长16 867 bp, GenBank登录号GU592504。基因含量和排列次序与原鸡的一致, 包含13个蛋白编码基因、22个tRNA、2个rRNA和1个控制区(D-loop)。除COI基因以GTG作为起始密码子外, 其余12个蛋白质编码基因均以典型ATG密码子起始。11个蛋白编码基因以完全终止密码子TAA、AGG或AGA终止, COIII和ND4基因终止密码子为不完整的T。tRNA^Ser(AGY)的DHU臂缺失, tRNA^Leu(CUN)的反密码子环由9个碱基构成, 而不是标准的7个碱基。其余的20个tRNA基因的二级结构均属典型的三叶草结构。预测了rRNA的二级结构, 其中, 12S rRNA二级结构包含4个结构域, 43个茎环结构; 16S rRNA的二级结构包含6个结构域, 55个茎环结构。此外, 在其他鸟类控制区中所发现的F-box、D-box、C-box、B-box、Bird similarity-box和CSB1-box也同样存在于黑尾地鸦中。     

Organization and expression of the mitochondrial genome of plants I. The genes for wheat mitochondrial ribosomal and transfer RNA: evidence for an unusual arrangement.

We show here that mitochondrial-specific ribosomal and transfer RNAs of wheat (Triticum vulgare Vill. [Triticum aestivum L.] var. Thatcher) are encoded by the mitochondrial DNA (mtDNA). Individual wheat mitochondrial rRNA species (26S, 18S, 5S) each hybridized with several mtDNA fragments in a particular restriction digest (Eco RI, Xho I, or Sal I). In each case, the DNA fragments to which 18S and 5S rRNAs hybridized were the same, but different from those to which 26S rRNA hybridized. From these results, we conclude that the structural genes for wheat mitochondrial 18S and 5S rRNAs are closely linked, but are physically distant from the genes for wheat mitochondrial 26S rRNA. This arrangement of rRNA genes is clearly different from that in prokaryotes and chloroplasts, where 23S, 16S and 5S rRNA genes are closely linked, even though wheat mitochondrial 18S rRNA has previously been shown to be prokaryotic in nature. The mixed population of wheat mitochondrial 4S RNAs (tRNAs) hybridized with many large restriction fragments, indicating that the tRNA genes are broadly distributed throughout the mitochondrial genome, with some apparent clustering in regions containing 18S and 5S rRNA genes.     

Copy number of the 16S rRNA gene in Rickettsia prowazekii.

The obligate intracellular parasite, Rickettsia prowazekii, is a slowly growing bacterium with a doubling time of 8 to 12 h. The copy number of the 16S rRNA gene in the rickettsial chromosome was determined to be one. Genomic DNA from R. prowazekii was digested either by a variety of restriction enzymes known not to cut at any site in the rickettsial 16S rRNA gene or by a combination of these noncutting enzymes and SmaI, which cuts the gene only once. Only one DNA fragment in these digests hybridized to a biotinylated probe containing a portion of the rickettsial 16S rRNA gene. Moreover, the density of the rickettsial 16S rRNA gene fragment after hybridization was equal to the density of each of the seven 16S rRNA gene fragments in Escherichia coli.     

Paramecium mitochondrial genes. I. Small subunit rRNA gene sequence and microevolution

The sequences of the small subunit mitochondrial rRNA genes from two divergent species of Paramecium (primaurelia and tetraurelia) were determined. The gene lies near the center of the linear mitochondrial genome, on the same strand as are all other currently identified genes. The sequences generally resemble their counterparts found in cytoplasmic, procaryotic, and other mitochondrial sources. The rDNA gene boundaries were located by nuclease S1 protection. Small subunit rDNA spans about 1680 nucleotides, including an extraneous 83-base pair sequence very near the 3' end which is unique to Paramecium mitochondria. This "insert" occurs at the apex of the highly variable in length penultimate helix, according to proposed models for small subunit rRNA secondary structure. A discontinuity occurs in isolated rRNA near the start of the insert, resulting in a stable 13 S RNA species and a small segment containing the remaining 3' portion of the gene. The overall rRNA gene sequence was 94% conserved between the two species, and the nucleotide differences consisted of 53% transitions, 37% transversions, and 9% insertions plus deletions. These substitutions were somewhat clustered, and the two most divergent regions coincided with the gene boundaries. The sequence was aligned with Escherichia coli 16 S rRNA for direct comparison of sequence and structure.     

Genomic variation in the mitochondrially encoded cytochrome b (MT-CYB) and 16S rRNA (MT-RNR2) genes: characterization of eight endangered Pecoran species

In an effort to develop species-specific identification markers, we examined genetic variants and molecular signatures within genes encoding mitochondrial cytochrome b and 16S rRNA in eight endangered Pecoran species endemic to the Indian peninsula. Our results revealed that the cytochrome b gene exhibited higher sequence diversity than the 16S rRNA gene, both between and within species. However, the 16S rRNA gene harboured a larger number of species-specific mutation sites compared with the cytochrome b gene, suggesting that it could be useful for species identification. Indeed, we successfully used 'forensically informative nucleotide sequencing' (FINS) analysis of the 16S rRNA gene to identify two previously unknown biological specimens.     

Multigene Barcoding and Phylogeny of Geographically Widespread Muricids (Gastropoda: Neogastropoda) Along the Coast of China

The identification and phylogeny of muricids have been in a state of confusion for a long time due to the morphological convergence and plasticity. DNA-based identification and phylogeny methods often offer an analytically powerful addition or even an alternative. In this study, we employ a DNA barcoding method to identify 17 known and easily confused muricid species (120 individuals) from the whole China coast based on mitochondrial cytochrome c oxidase subunit I (COI) and 16S rRNA sequences, and nuclear ITS-1 and 28S rRNA sequences. The phylogeny of muricid subfamilies is also analysed based on all mitochondrial and nuclear sequences. The universal COI and 16S rRNA primers did not work broadly across the study group, necessitating the redesign of muricid specific COI and 16S rRNA primers in this paper. Our study demonstrates that COI gene is a suitable marker for barcoding muricids, which can distinguish all muricid species studied. Phylogenetic analysis of 16S rRNA, ITS-1 and 28S rRNA data also provide good support for the species resolution observed in COI data. The relationships of muricid subfamilies are resolved based on the separate and combined gene data that showed the monophyly of each the subfamilies Ergalataxinae, Rapaninae, Ocenebrinae and Muricinae, especially that Ergalataxinae did not fall within Rapaninae.     

油菜叶绿体16S rRNA基因前导顺序的一级结构

质粒pBN119的3.2kb BamHI片段的PvuⅡ-BglⅡ片段全顺序长为840bp,其中含油菜叶绿体16S rRNA基因5′端的140bp。通过寻找GTTC顺序,发现在395至468位核苷酸之间是tRNA~(Val)基因;在73至118位核苷酸之间是一个蛋白阅读框。和已发表的玉米叶绿体16S rRNA前导顺序进行比较,同样存在三个相应的大肠杆菌RNA聚合酶的结合位点。和大肠杆菌的启动子及相应基因作比较,表明叶绿体基因组具有很明显的原核性,但其tRNA~(Val)基因没有CCA3′顺序。在16S rRNA基因、tRNA~(Val)基因及蛋白阅读框的5′端附近均能找到一个比较稳定的茎环结构。我们推测这些茎环结构可能和位于反问重复顺序上的某些基因的转录调节有关。     

3'-Terminal sequence of wheat mitochondrial 18S ribosomal RNA: further evidence of a eubacterial evolutionary origin.

We have determined the sequences of the 3'-terminal approximately 100 nucleotides of [5' -32P]pCp-labeled wheat mitochondrial, wheat cytosol, and E. coli small sub-unit rRNAs. Sequence comparison demonstrates that within this region, there is a substantially greater degree of homology between wheat mitochondrial 18S and E. coli 16S rRNAs than between either of these and wheat cytosol 18S rRNA. Moreover, at a position occupied by 3-methyluridine in E. coli 16S rRNA, the same (or a very similar) modified nucleoside is present in wheat mitochondrial 18S rRNA but not in wheat cytosol 18S rRNA. Further, E. coli 16S and 23S rRNAs hybridize extensively to wheat mitochondrial 18S and 26S rRNA genes, respectively, but wheat cytosol 18S and 26S rRNAs do not. No other mitochondrial system studies to date has provided comparable evidence that a mitochondrial rRNA is more closely related to its eubacterial homolog than is its counterpart in the cytoplasmic compartment of the same cell. The results reported here provide additional support for the view that plant mitochondria are of endosymbiotic, specifically eubacterial, origin.