Modified oligoribonucleotides as site-specific probes of RNA structure and function

Modified nucleotides can be incorporated site specifically into RNA by the use of total chemical synthesis as well as by use of a variety of recombinant RNA techniques. The range of nucleotide analogues includes modifications to base, sugar, and phosphate for structure–function analysis and for cross-linking studies as well as to answer specific mechanistic questions in RNA catalysis. We describe how RNA containing site-specific modifications are prepared, concentrating in particular on routes involving chemically synthesized oligoribonucleotides, and give examples of their application in studies of the hammerhead and hairpin ribozymes. © 1998 John Wiley & Sons, Inc. Biopoly 48: 39–55, 1998     

Long-lived southern blots using RNA probes

Conditions for preparation and hybridization of Southern blots are described which assure reusability through 15 to 25 cycles. The procedure relies on the use of charge-modified nylon membranes and^[32P]-labelled RNA probes.     

Transfer RNA shields specific nucleotides in 16S ribosomal RNA from attack by chemical probes

Binding of tRNAPhe to ribosomes shields a set of highly conserved nucleotides in 16S rRNA from attack by a combination of structure-specific chemical probes. The bases can be classified according to whether or not their protection is strictly poly(U)-dependent (G529, G530, U531, A1408, A1492, and A1493) or poly(U)-independent (A532, G693, A794, C795, G926, 2mG966, G1338, A1339, U1381, C1399, C1400, and G1401). A third class (A790, G791, and A909) is shielded by both tRNA and 50S ribosomal subunits. Similar results are obtained when the protecting ligand is tRNAPhe E. Coli, tRNAPhe yeast, tRNAPhe E. Coli lacking its 3' terminal CA, or the 15 nucleotide anticodon stem-loop fragment of tRNAPhe yeast. Implications for structural correlates of the classic ribosomal A- and P-sites and for the possible involvement of 16S rRNA in translational proofreading are discussed.     

Hybridization and detection of digoxigenin probes on RNA blots

This article describes nonradioactive probing of a Northern blot. The method employs digoxigenin-labeled probes. Antidigoxigenin antibody/alkaline phosphate conjugate, and a chemiluminescent substrate are subsequently used in the detection system.     

Crystal structure of the 30 S ribosomal subunit from Thermus thermophilus: structure of the proteins and their interactions with 16 S RNA

We present a detailed analysis of the protein structures in the 30 S ribosomal subunit from Thermus thermophilus, and their interactions with 16 S RNA based on a crystal structure at 3.05 A resolution. With 20 different polypeptide chains, the 30 S subunit adds significantly to our data base of RNA structure and protein-RNA interactions. In addition to globular domains, many of the proteins have long, extended regions, either in the termini or in internal loops, which make extensive contact to the RNA component and are involved in stabilizing RNA tertiary structure. Many ribosomal proteins share similar alpha+beta sandwich folds, but we show that the topology of this domain varies considerably, as do the ways in which the proteins interact with RNA. Analysis of the protein-RNA interactions in the context of ribosomal assembly shows that the primary binders are globular proteins that bind at RNA multihelix junctions, whereas proteins with long extensions assemble later. We attempt to correlate the structure with a large body of biochemical and genetic data on the 30 S subunit.     

16S rRNA序列分析法在医学微生物鉴定中的应用

１６Ｓ ｒＲＮＡ序列分析作为微生物系统分类的主要依据已得到了广泛认同,随着微生物核糖体数据库的日益完善,该技术成为细菌分类和鉴定的一个有力工具。本文概述了 １６５ ｒＲＮＡ序列分析法的技术步骤以及该技术在医学微生物研究中的应用,总结了目前文献报导的各种致病微生物种属特异性 １６５ ｒＲＮＡ引物和探针序列,同时分析了该技术在应用中存在的一些问题。     

Probing the structure of 16 S ribosomal RNA from Bacillus brevis

A majority (approximately 89%) of the nucleotide sequence of Bacillus brevis 16 S rRNA has been determined by a combination of RNA sequencing methods. Several experimental approaches have been used to probe its structure, including (a) partial RNase digestion of 30 S ribosomal subunits, followed by two-dimensional native/denatured gel electrophoresis, in which base-paired fragments were directly identified; (b) identification of positions susceptible to cleavage by RNase A and RNase T1 in 30 S subunits; (c) sites of attack by cobra venom RNase on naked 16 S rRNA; and (d) nucleotides susceptible to attack by bisulfite in 16 S rRNA. These data are discussed with respect to a secondary structure model for B. brevis 16 S rRNA derived by comparative sequence analysis.     

小鲵科线粒体16S rRNA基因序列分析及其系统发育

To study the phylogeny of Hynobiidae, we amplified DNA fragments of 470 bp 16S ribosomal RNA (16S rRNA) gene on mitochondrial DNA from Ranodon sibiricus and Ranodon tsinpaensis. PCR products were cloned into PMD18 T vector after purification. These sequences were determined and deposited in the GenBank (accession numbers: AY373459 for Ranodon sibiricus, AY372534 for Ranodon tsinpaensis). By comparing the nucleotide differences of 16S ribosomal RNA sequences among Liua shihi, Pseudohynobius flavomaculatus and Batrachuperus genus from GenBank database, we analyzed the divergences and base substitution among these sequences with the MEGA software. The molecular results support that B. tibetanus, B. pinchonii and B. karlschmidti are classified into three valid species. Liua shihi has closer phylogenetic relationships to Ranodon tsinpaensis than to other species. More our results reveal that Pseudohynobius flavomaculatus is not a synonym of Ranodon tsinpaensis. [Acta Zoologica Sinica 50 (3) : 464 - 469,2004].     

Mutations in ribosomal proteins S4 and S12 influence the higher order structure of 16 S ribosomal RNA

We have studied the effects of protein mutations on the higher order structure of 16 S rRNA in Escherichia coli ribosomes, using a set of structure-sensitive chemical probes. Ten mutant strains were studied, which contained alterations in ribosomal proteins S4 and S12, including double mutants containing both altered S4 and S12. Two ribosomal ambiguity (ram) S4 mutant strains, four streptomycin resistant (SmR) S12 mutant strains, one streptomycin pseudodependent (SmP) S12 mutant strain, one streptomycin dependent (SmD) S12 mutant strain and two streptomycin independent (Sm1) double mutants (containing both-SmD and ram mutations) were probed and compared to an isogenic wild-type strain. In ribosomes from strains containing S4 ram mutations, nucleotides A8 and A26 become more reactive to dimethyl sulfate (DMS) at their N-1 positions. In ribosomes from strains bearing the SmD allele, A908, A909, A1413 and G1487 are significantly less reactive to chemical probes. These same effects are observed when the S4 and S12 mutations are present simultaneously in the double mutants. An interesting correlation is found between the reactivity of A908 and the miscoding potential of SmR, SmD, SmP and wild-type ribosomes; the reactivity of A908 increases as the translational error frequency of the ribosomes increases. In the case of ram ribosomes, the reactivity of A908 resembles that of wild-type, unless tRNA is bound, in which case it becomes hyper-reactive. Similarly, streptomycin has little effect on A908 in wild-type ribosomes unless tRNA is bound, in which case its reactivity increases to resemble that of ram ribosomes with bound tRNA. Finally, interaction of streptomycin with SmP and SmD ribosomes causes the reactivity of A908 to increase to near-wild-type levels. A simple model is proposed, in which the reactivity of A908 reflects the position of an equilibrium between two conformational states of the 30 S subunit, one of which is DMS-reactive, and the other DMS-unreactive. In this model, the balance between these two states would be influenced by proteins S4 and S12. Mutations in S12 generally cause a shift toward the unreactive conformer, and in the case of SmD and SmP ribosomes, this shift can be suppressed phenotypically by streptomycin, ram mutations in protein S4 cause a shift toward the reactive conformer, but only when tRNA is bound. This suggests that the opposing effects of these two classes of mutations influence the proof-reading process by somewhat different mechanisms.     

Sequence studies on 16S ribosomal RNA from a blue-green alga

Summary The 16S ribosomal RNA of the blue green algaAnacystis nidulans has been characterized in terms of the oligomers generated by digestion with T1 ribonuclease.A. nidulans by this criterion is definitely a procaryote; being no more distant from Bacilli or Enterics than the latter two are from one another.A. nidulans appears to be somewhat more closely related to the Bacilli than to the Enterics.This is contribution III in a series entitled Procaryote phylogeny.     

Questionable 16S ribosomal RNA gene annotations are frequent in completed microbial genomes

According to recent reports, many ribosomal RNA gene annotations are still questionable, and the use of inappropriate tools for annotation has been blamed. However, we believe that the abundant 16S rRNA partial sequence in the databases, mainly created by culture-independent PCR methods, is another main cause of the ambiguous annotations of 16S rRNA. To examine the current status of 16S rRNA gene annotations in complete microbial genomes, we used as a criterion the conserved anti-SD sequence, located at the 3′ end of the 16S rRNA gene, which is commonly overlooked by culture-independent PCR methods. In our large survey, 859 16S rRNA gene sequences from 252 different species of the microbial complete genomes were inspected. 67 species (234 genes) were detected with ambiguous annotations. The common anti-SD sequence and other conserved 16S rRNA sequence features could be detected in the downstream-intergenic regions for almost every questionable sequence, indicating that many of the 16S rRNA genes were annotated incorrectly. Furthermore, we found that more than 91.5% of the 93,716 sequences of the available 16S rRNA in the main databases are partial sequences. We also performed BLAST analysis for every questionable rRNA sequence, and most of the best hits in the analysis were rRNA partial sequences. This result indicates that partial sequences are prevalent in the databases, and that these sequences have significantly affected the accuracy of microbial genomic annotation. We suggest that the annotation of 16S rRNA genes in newly complete microbial genomes must be done in more detail, and that revision of questionable rRNA annotations should commence as soon as possible.     

Secondary structure model for bacterial 16S ribosomal RNA: phylogenetic, enzymatic and chemical evidence.

We have derived a secondary structure model for 16S ribosomal RNA on the basis of comparative sequence analysis, chemical modification studies and nuclease susceptibility data. Nucleotide sequences of the E. coli and B. brevis 16S rRNA chains, and of RNAse T1 oligomer catalogs from 16S rRNAs of over 100 species of eubacteria were used for phylogenetic comparison. Chemical modification of G by glyoxal, A by m-chloroperbenzoic acid and C by bisulfite in naked 16S rRNA, and G by kethoxal in active and inactive 30S ribosomal subunits was taken as an indication of single stranded structure. Further support for the structure was obtained from susceptibility to RNases A and T1. These three approaches are in excellent agreement. The structure contains fifty helical elements organized into four major domains, in which 46 percent of the nucleotides of 16S rRNA are involved in base pairing. Phylogenetic comparison shows that highly conserved sequences are found principally in unpaired regions of the molecule. No knots are created by the structure.     

Conformational change of 23S RNA in 50S ribosome is responsible for translocation in protein synthesis

Since the recognition of the ‘translocation’ phenomenon during protein synthesis several theories have been proposed, without much success, to explain the translocation of peptidyl tRNA from the aminoacyl site to the peptidyl site. The involvement of L7/L12 proteins and therefore the L7/L12 stalk region of 50S ribosomes in the translocation process has been widely accepted. The mobility of the stalk region, as recognised by many workers, must be of physiological significance. It has recently been shown in this laboratory that 50S ribosomes derived from tight and loose couple 70S ribosomes differ markedly in quite a few physical and biological properties and it appears that these differences are due to the different conformations of 23S RNAs. It has also been possible to interconvert tight and loose couple 50S ribosomes with the help of the agents, elongation factor -G, GTP (and its analogues) which are responsible for translocation. Thus loose couple 70S ribosomes so long thought to be inactive ribosomes are actually products of translocation. Further, the conformational change of 23S RNA appears to be responsible for the interconversion of tight and loose couple 50S ribosomes and thus the process of translocation. A model has been proposed for translocation on the basis of the direct experimental evidences obtained in this laboratory.     

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)。     

Refined secondary structure models for the 16S and 23S ribosomal RNA of Escherichia coli

The complete range of published sequences for ribosomal RNA (or rDNA), totalling well over 50,000 bases, has been used to derive refined models for the secondary structures of both 16S and 23S RNA from E. coli. Particular attention has been paid to resolving the differences between the various published secondary structures for these molecules. The structures are described in terms of 133 helical regions (45 for 16S RNA and 88 for 23S RNA). Of these, approximately 20 are still tentative or unconfirmed. A further 20 represent helical regions which definitely exist, but where the detailed base-pairing is still open to discussion. Over 90 of the helical regions are however now precisely established, at least to within one or two base pairs.     

A novel method for determining microflora composition using dynamic phylogenetic analysis of 16S ribosomal RNA deep sequencing data

Deep sequencing of the 16S rRNA gene provides a comprehensive view of bacterial communities in a particular environment and has expanded our ability to study the impact of the microflora on human health and disease. Current analysis methods rely on comparisons of the sequences generated with an expanding but limited set of annotated 16S rRNA sequences or phylogenic clustering of sequences based on arbitrary similarity cutoffs. We describe a novel approach to characterize bacterial composition using deep sequencing of 16S rRNA gene. Our method defines operational taxonomic units based on phylogenetic tree reconstruction and dynamic clustering of sequences using solely sequencing data. These OTUs can be used to identify differences in bacteria abundance between environments. This approach can perform better than previous phylogenetic methods and will significantly improve our understanding of the microfloral role on human diseases by providing a comprehensive analysis of the microbial composition from various bacterial communities.