Structural and sequence elements important for recognition of Escherichia coli formylmethionine tRNA by methionyl-tRNA transformylase are clustered in the acceptor stem

We show that the structure and/or sequence of the first three base pairs at the end of the amino acid acceptor stem of Escherichia coli initiator tRNA and the discriminator base 73 are important for its formylation by E. coli methionyl-tRNA transformylase. This conclusion is based on mutagenesis of the E. coli initiator tRNA gene followed by measurement of kinetic parameters for formylation of the mutant tRNAs in vitro and function in protein synthesis in vivo. The first base pair found at the end of the amino acid acceptor stem in all other tRNAs is replaced by a C.A. "mismatch" in E. coli initiator tRNA. Mutation of this C.A. to U:A, a weak base pair, or U.G., a mismatch, has little effect on formylation, whereas mutation to C:G, a strong base pair, has a dramatic effect lowering Vmax/Kappm by 495-fold. Mutation of the second basepair G2:C71 to U2:A71 lowers Vmax/Kappm by 236-fold. Replacement of the third base-pair C3:G70 by U3:A70, A3:U70, or G3:C70 lowers Vmax/Kappm by about 67-, 27-, and 30-fold, respectively. Changes in the rest of the acceptor stem, dihydrouridine stem, anticodon stem, anticodon sequence, and T psi C stem have little or no effect on formylation.     

COMBINED EFFECTS OF MACRONUTRIENTS AND METALS ON THE ADRIATIC GREEN ALGA ULVA RIGIDA C.AG.

Over 400 nuclear SSU rRNA sequences representing all orders of the Rhodophyta were aligned and analyzed using comparative sequence analysis. Numerous nucleotide positions and structural elements were found that delineated various taxonomic groups. The 1245 region ( E. coli numbering) contained a loop that differed in size between two conserved helices and clearly separated the Florideophyceae [3 nt (>95% of 268 sequences)], Bangiales [13 to 14 nt (100% of 116 sequences)] and remaining Bangiophyceae including the Cryptophyta nucleomorphs [four to eight nt (100% of 32 sequences)]. In addition, members of the Thoreaceae were found to have additional helices in the 650 and 1139 region of which a corresponding structure was not present in any other red algal SSU rRNA gene sequence. Base-pair and nucleotide signatures differentiated the Bangiales, Florideophyceae, Bangiophyceae (not including Bangiales) and Hildenbrandiales at three levels of comparison: within the Rhodophyta (>400 sequences), the Eukaryota (not including Rhodophyta;> 1300 sequences) and three kingdom (Archaea, Bacteria, 2 organelles, Eukaryota;> 7000 sequences). For example, all members of the Hildenbrandiales have a change in the base-pair 512:539 that is a region of functional importance. Sequences from the Eukaryota, Archaea, Bacteria and two organelles have a C:G or a U:A in this position whereas the Hildenbrandiales have a C:A pair. This analysis raises the possibility of utilizing structural features of nuclear SSU rRNA and sequence signatures to support and delineate phylogenetic clades within the Rhodophyta.     

New information content in RNA base pairing deduced from quantitative analysis of high-resolution structures

Non-canonical base pairs play important roles in organizing the complex three-dimensional folding of RNA. Here, we outline methodology developed both to analyze the spatial patterns of interacting base pairs in known RNA structures and to reconstruct models from the collective experimental information. We focus attention on the structural context and deformability of the seven pairing patterns found in greatest abundance in the helical segments in a set of well-resolved crystal structures, including (i–ii) the canonical A·U and G·C Watson–Crick base pairs, (iii) the G·U wobble pair, (iv) the sheared G·A pair, (v) the A·U Hoogsteen pair, (vi) the U·U wobble pair, and (vii) the G·A Watson–Crick-like pair. The non-canonical pairs stand out from the canonical associations in terms of apparent deformability, spanning a broader range of conformational states as measured by the six rigid-body parameters used to describe the spatial arrangements of the interacting bases, the root-mean-square deviations of the base-pair atoms, and the fluctuations in hydrogen-bonding geometry. The deformabilties, the modes of base-pair deformation, and the preferred sites of occurrence depend on sequence. We also characterize the positioning and overlap of the base pairs with respect to the base pairs that stack immediately above and below them in double-helical fragments. We incorporate the observed positions of the bases, base pairs, and intervening phosphorus atoms in models to predict the effects of the non-canonical interactions on overall helical structure.     

Diversity of base-pair conformations and their occurrence in rRNA structure and RNA structural motifs

In addition to the canonical base-pairs comprising the standard Watson-Crick (C:G and U:A) and wobble U:G conformations, an analysis of the base-pair types and conformations in the rRNAs in the high-resolution crystal structures of the Thermus thermophilus 30S and Haloarcula marismortui 50S ribosomal subunits has identified a wide variety of non-canonical base-pair types and conformations. However, the existing nomenclatures do not describe all of the observed non-canonical conformations or describe them with some ambiguity. Thus, a standardized system is required to classify all of these non-canonical conformations appropriately. Here, we propose a new, simple and systematic nomenclature that unambiguously classifies base-pair conformations occurring in base-pairs, base-triples and base-quadruples that are associated with secondary and tertiary interactions. This system is based on the topological arrangement of the two bases and glycosidic bonds in a given base-pair. Base-pairs in the internal positions of regular secondary structure helices usually form with canonical base-pair groups (C:G, U:A, and U:G) and canonical conformations (C:G WC, U:A WC, and U:G Wb). In contrast, non-helical base-pairs outside of regular structure helices usually have non-canonical base-pair groups and conformations. In addition, many non-helical base-pairs are involved in RNA motifs that form a defined set of non-canonical conformations. Thus, each rare non-canonical conformation may be functionally and structurally important. Finally, the topology-based isostericity of base-pair conformations can rationalize base-pair exchanges in the evolution of RNA molecules.     

Sequence specificity in triple-helix formation: experimental and theoretical studies of the effect of mismatches on triplex stability

The specificity of a homopyrimidine oligonucleotide binding to a homopurine-homopyrimidine sequence on double-stranded DNA was investigated by both molecular modeling and thermal dissociation experiments. The presence of a single mismatched triplet at the center of the triplex was shown to destabilize the triple helix, leading to a lower melting temperature and a less favorable energy of interaction. A terminal mismatch was less destabilizing than a central mismatch. The extent of destabilization was shown to be dependent on the nature of the mismatch. Both single base-pair substitution and deletion in the duplex DNA target were investigated. When a homopurine stretch was interrupted by one thymine, guanine was the least destabilizing base on the third strand. However, G in the third strand did not discriminate between a C.G and an A.T base pair. If the stretch of purines was interrupted by a cytosine, the presence of pyrimidines (C or T) in the third strand yielded a less destabilizing effect than purines. This study shows that oligonucleotides forming triple helices can discriminate between duplex DNA sequences that differ by one base pair. It provides a basis for the choice of antigene oligonucleotide sequences targeted to selected sequences on duplex DNA.     

Small sequence insertions within the branch point region dictate alternative sites of lariat formation in a yeast intron.

The problem of intron recognition in S. cerevisiae appears to be in part solved by the strong conservation of intron encoded splicing signals, in particular the 5' GUAUGU and the branch point UACUAAC which interact via base pairing with the RNA components of U1 and U2 snRNPs respectively. Nevertheless, the mere presence of such signals is insufficient for splicing to occur. In the S. cerevisiae ACT1 intron, a silent UACUAAC-like sequence (UACUAAG) is located 7 nucleotides upstream of the canonical branch point signal. In order to investigate whether other factors, in addition to the U2-UACUAAC base-pair interactions, affect branch point selection in yeast, we created a cis-competition assay by converting the UACUAAG to a strong branch point signal (UACUAAC). If simply having a canonical UACUAAC sequence were sufficient for lariat formation, a 1:1 ratio in usage of the two signals should have been observed. In this double branch point intron, however, the downstream UACUAAC is utilized preferentially (4:1). Results obtained from the analyses of numerous sequence variants flanking the two UACUAAC sequences, demonstrate that non-conserved sequences in the branch point region are able to define lariat formation. Consequently, we conclude that U2 base-pairing is not the only requirement determining branch point selection in yeast, and local structure in the vicinity of the branch point could play a critical role in its recognition.     

Unique tertiary and neighbor interactions determine conservation patterns of Cis Watson-Crick A/G base-pairs

X-ray, phylogenetic and quantum chemical analysis of molecular interactions and conservation patterns of cis Watson-Crick (W.C.) A/G base-pairs in 16S rRNA, 23S rRNA and other molecules was carried out. In these base-pairs, the A and G nucleotides interact with their W.C. edges with glycosidic bonds oriented cis relative to each other. The base-pair is stabilised by two hydrogen bonds, the C1'-C1' distance is enlarged and the G(N2) amino group is left unpaired. Quantum chemical calculations show that, in the absence of other interactions, the unpaired amino group is substantially non-planar due to its partial sp(3) pyramidalization, while the whole base-pair is internally propeller twisted and very flexible. The unique molecular properties of the cis W.C. A/G base-pairs make them distinct from other base-pairs. They occur mostly at the ends of canonical helices, where they serve as interfaces between the helix and other motifs. The cis W.C. A/G base-pairs play crucial roles in natural RNA structures with salient sequence conservation patterns. The key contribution to conservation is provided by the unpaired G(N2) amino group that is involved in a wide range of tertiary and neighbor contacts in the crystal structures. Many of them are oriented out of the plane of the guanine base and utilize the partial sp(3) pyramidalization of the G(N2). There is a lack of A/G to G/A covariation, which, except for the G(N2) position, would be entirely isosteric. On the contrary, there is a rather frequent occurrence of G/A to G/U covariation, as the G/U wobble base-pair has an unpaired amino group in the same position as the cis W.C. G/A base-pair. The cis W.C. A/G base-pairs are not conserved when there is no tertiary or neighbor interaction. Obtaining the proper picture of the interactions and phylogenetic patterns of the cis W.C. A/G base-pairs requires a detailed analysis of the relation between the molecular structures and the energetics of interactions at a level of single H-bonds and contacts.     

A story: unpaired adenosine bases in ribosomal RNAs

In 1985 an analysis of the Escherichia coli 16 S rRNA covariation-based structure model revealed a strong bias for unpaired adenosines. The same analysis revealed that the majority of the G, C, and U bases were paired. These biases are (now) consistent with the high percentage of unpaired adenosine nucleotides in several structure motifs.An analysis of a larger set of bacterial comparative 16 S and 23 S rRNA structure models has substantiated this initial finding and revealed new biases in the distribution of adenosine nucleotides in loop regions. The majority of the adenosine nucleotides are unpaired, while the majority of the G, C, and U bases are paired in the covariation-based structure model. The unpaired adenosine nucleotides predominate in the middle and at the 3' end of loops, and are the second most frequent nucleotide type at the 5' end of loops (G is the most common nucleotide). There are additional biases for unpaired adenosine nucleotides at the 3' end of loops and adjacent to a G at the 5' end of the helix. The most prevalent consecutive nucleotides are GG, GA, AG, and AA. A total of 70 % of the GG sequences are within helices, while more than 70 % of the AA sequences are unpaired. Nearly 50 % of the GA sequences are unpaired, and approximately one-third of the AG sequences are within helices while another third are at the 3' loop.5' helix junction. Unpaired positions with an adenosine nucleotide in more than 50 % of the sequences at the 3' end of 16 S and 23 S rRNA loops were identified and arranged into the A-motif categories XAZ, AAZ, XAG, AAG, and AAG:U, where G or Z is paired, G:U is a base-pair, and X is not an A and Z is not a G in more than 50 % of the sequences. These sequence motifs were associated with several structural motifs, such as adenosine platforms, E and E-like loops, A:A and A:G pairings at the end of helices, G:A tandem base-pairs, GNRA tetraloop hairpins, and U-turns.     

Thermodynamics of unpaired terminal nucleotides on short RNA helixes correlates with stacking at helix termini in larger RNAs.

Free energies for stacking of unpaired nucleotides (dangling ends) at the termini of oligoribonucleotide Watson-Crick helixes (DeltaG(0)37,stack) depend on sequence for 3' ends but are always small for 5' ends. Here, these free energies are correlated with stacking at helix termini in a database of 34 RNA structures determined by X-ray crystallography and NMR spectroscopy. Stacking involving GA pairs is considered separately. A base is categorized as stacked by its distance from (相似文献   

Exploration of pairing constraints identifies a 9 base-pair core within box C/D snoRNA-rRNA duplexes

2'-O-ribose methylation of eukaryotic ribosomal RNAs is guided by RNA duplexes consisting of rRNA and box C/D small nucleolar (sno)RNA sequences, the methylated sites invariably mapping five positions apart from the D box. Here we have analyzed the RNA duplex pairing constraints by investigating the features of 415 duplexes from the fungus, plant and animal kingdoms, and the evolution of those duplexes within the 124 sets they group into. The D-box upstream 1st and >or=15th positions consist of Watson-Crick base-pairs, G:U base-pairs and mismatched bases with ratios close to random assortments; these positions display single base differences in >60% of the RNA duplex sets. The D-box upstream 2nd to 11th positions have >90% Watson-Crick base-pairs; they display single base mutations with a U-shaped distribution of lower values of 0% and 1.6% at the methylated site 5th and 4th positions, and double compensatory mutations leading to new Watson-Crick base-pairs with an inverted U-shaped distribution of higher values at the 8th to 11th positions. Half of the single mutations at the 3rd to 11th positions resulted in G:U base-pairing, mainly through A-->G mutations in the rRNA strands and C-->T mutations in the snoRNA strands. Double compensatory mutations at the 3rd to 11th positions are extremely frequent, representing 36% of all mutations; they frequently arose from an A-->G mutation in the rRNA strands followed by a T-->C mutation in the snoRNA strands. Differences in the mutational pathways through which the rRNA and snoRNA strand evolved must be related to differences in the rRNA and snoRNA copy number and gene organization. Altogether these data identify the D-box upstream 3rd to 11th positions as box C/D snoRNA-rRNA duplex cores. The impact of the pairing constraints on the evolution of the 9 base-pair RNA duplex cores is discussed.     

Demonstration of the GC-rich common arm in yeast ribosomal 5.8S RNA via 500-MHz proton nuclear magnetic resonance and Overhauser enhancements

In this paper we report the first 1H NMR study of the base-paired secondary structure of yeast 5.8S RNA. On the basis of a combination of homonuclear Overhauser enhancements and temperature dependence of the proton 500-MHz NMR spectrum, we are able to identify and assign eight of the nine base pairs in the most thermally stable helical arm: G116.C137-C117.G136-C118.G135- C119.G134-C120.G133-U121.G132- U122.A131-G123.C130. This arm contains an unusually temperature-stable (to 71 degrees C) segment of four consecutive G.C base pairs. This work constitutes the most direct evidence to date for the existence and base-pair sequence of the GC-rich helix, which is common to most currently popular secondary structural models for eukaryotic 5.8S ribosomal RNA.     

Contribution of opening and bending dynamics to specific recognition of DNA damage

Guanine-uracil (G.U) wobble base-pairs are a detrimental lesion in DNA. Previous investigations have shown that such wobble base-pairs are more prone to base-opening than the normal G.C base-pairs. To investigate the sequence-dependence of base-pair opening we have performed 5ns molecular dynamics simulations on G.U wobble base-pairs in two different sequence contexts, TGT/AUA and CGC/GUG. Furthermore, we have investigated the effect of replacing the guanine base in each sequence with a fluorescent guanine analogue, 6-methylisoxanthopterin (6MI). Our results indicate that each sequence opens spontaneously towards the major groove in the course of the simulations. The TGT/AUA sequence has a greater proportion of structures in the open state than the CGC/GUG sequence. Incorporation of 6MI yields wobble base-pairs that open more readily than their guanine counterparts. In order of increasing open population, the sequences are ordered as CGC相似文献   

Morpholino spin-labeling for base-pair sequencing of a 3'-terminal RNA stem by proton homonuclear Overhauser enhancements: yeast ribosomal 5S RNA

Base-pair sequences for 5S and 5.8S RNAs are not readily extracted from proton homonuclear nuclear Overhauser enhancement (NOE) connectivity experiments alone, due to extensive peak overlap in the downfield (11-15 ppm) proton NMR spectrum. In this paper, we introduce a new method for base-pair proton peak assignment for ribosomal RNAs, based upon the distance-dependent broadening of the resonances of base-pair protons spatially proximal to a paramagnetic group. Introduction of a nitroxide spin-label covalently attached to the 3'-terminal ribose provides an unequivocal starting point for base-pair hydrogen-bond proton NMR assignment. Subsequent NOE connectivities then establish the base-pair sequence for the terminal stem of a 5S RNA. Periodate oxidation of yeast 5S RNA, followed by reaction with 4-amino-2,2,6,6-tetramethylpiperidinyl-1-oxy (TEMPO-NH2) and sodium borohydride reduction, produces yeast 5S RNA specifically labeled with a paramagnetic nitroxide group at the 3'-terminal ribose. Comparison of the 500-MHz 1H NMR spectra of native and 3'-terminal spin-labeled yeast 5S RNA serves to identify the terminal base pair (G1 . C120) and its adjacent base pair (G2 . U119) on the basis of their proximity to the 3'-terminal spin-label. From that starting point, we have then identified (G . C, A . U, or G . U) and sequenced eight of the nine base pairs in the terminal helix via primary and secondary NOE's.     

The ribosome binding sites recognized by E. coli ribosomes have regions with signal character in both the leader and protein coding segments.

Oligonucleotide analysis, by a novel computerized procedure, was first applied to determine the sequence of an ideal E. coli promoter (Scherer et al., Nucl. Acids Res. 1978, 5:3759-3773) and has now been used to obtain the sequence of nucleotides that should be present in a messenger RNA for optimum binding to the E. coli ribosome. This sequence is: UU.UUAAAAAUUAAGGAGGUAUAUUAUGAAAAAAAUUAAAAAACUCAA AA U A AUA A CUC G. Comparison of this sequence with each of the 68 ribosome binding site sequences used to generate it shows a preference rather than an absolute requirement for a specific base in any given position. The preference for certain bases persists along the whole length of the RNA within the ribosome binding domain even though nearly half of that length includes translated codons. Thus messages without leader sequences (like lambda CI mRNA) can still have some affinity for the ribosome. Part of the model sequence is complementary to the 3'end of 16S rRNA.     

The tmRNA database (tmRDB).

This first release of the tmRNA database (tmRDB) contains 19 tmRNA sequences, a tmRNA sequence alignment with emphasis of base pairs that are supported by comparative sequence analysis, and a tabulation of tmRNA-encoded tag peptides. The tmRNADB also offers an RNA secondary structure diagram of the Escherichia coli tmRNA, as well as PDB-formatted coordinates for three-dimensional modeling. The data are available on the World Wide Web at http://www.uthct. edu/tmRDB/tmRDB.html     

RNA Sequence Determinants for Aminoglycoside Binding to an A-site rRNA Model Oligonucleotide

The codon-anticodon interaction on the ribosome occurs in the A site of the 30 S subunit. Aminoglycoside antibiotics, which bind to ribosomal RNA in the A site, cause misreading of the genetic code and inhibit translocation. Biochemical studies and nuclear magnetic resonance spectroscopy were used to characterize the interaction between the aminoglycoside antibiotic paromomycin and a small model oligonucle otide that mimics the A site ofEscherichia coli16 S ribosomal RNA. Upon chemical modification, the RNA oligonucleotide exhibits an accessibility pattern similar to that of 16 S rRNA in the 30 S subunit. In addition, the oligonucleotide binds specifically aminoglycoside antibiotics. The anti biotic binding site forms an asymmetric internal loop, caused by non-canonical base-pairs. Nucleotides that are important for binding of paromomycin were identified by performing quantitative footprinting on oligonucleotide sequence variants and include the C1407·G1494 base-pair, and A·U base-pair at positions 1410/1490, and nucleotides A1408, A1493 and U1495. The asymmetry of the internal loop, which requires the presence of a nucleotide in position 1492, is also crucial for antibiotic binding. Introduction into the oligonucleotide of base changes that are known to confer aminoglycoside resistance in 16 S rRNA result in weaker binding of paromomycin to the oligonucleotide. Oligonucleotides homologous to eukaryotic rRNA sequences show reduced binding of paromomycin, suggesting a physical origin for the species-specific action of aminoglycosides.     

Inferring the conformation of RNA base pairs and triples from patterns of sequence variation.

The success of comparative analysis in resolving RNA secondary structure and numerous tertiary interactions relies on the presence of base covariations. Although the majority of base covariations in aligned sequences is associated to Watson-Crick base pairs, many involve non-canonical or restricted base pair exchanges (e.g. only G:C/A:U), reflecting more specific structural constraints. We have developed a computer program that determines potential base pairing conformations for a given set of paired nucleotides in a sequence alignment. This program (ISOPAIR) assumes that the base pair conformation is maintained through sequence variation without significantly affecting the path of the sugar-phosphate backbone. ISOPAIR identifies such 'isomorphic' structures for any set of input base pair or base triple sequences. The program was applied to base pairs and triples with known structures and sequence exchanges. In several instances, isomorphic structures were correctly identified with ISOPAIR. Thus, ISOPAIR is useful when assessing non-canonical base pair conformations in comparative analysis. ISOPAIR applications are limited to those cases where unusual base pair exchanges indeed reflect a non-canonical conformation.     

The spacing between functional Cis-elements of U3 snoRNA is critical for rRNA processing

The sequences and structural features of Xenopus laevis U3 small nucleolar RNA (snoRNA) necessary for pre-rRNA cleavage at sites 1 and 2 to form 18 S rRNA were assayed by depletion/rescue experiments in Xenopus oocytes. Mutagenesis results demonstrated that the putative stem of U3 domain I is unnecessary for 18 S rRNA processing. A model consistent with earlier experimental data is proposed for the structure of domain I when U3 is not yet bound to pre-rRNA. For its function in rRNA processing, a newly discovered element (5' hinge) was revealed to be important but not as critical as the 3' hinge region in Xenopus U3 snoRNA for 18 S rRNA formation. Base-pairing is proposed to occur between the U3 5' hinge and 3' hinge and complementary regions in the external transcribed spacer (ETS); these interactions are phylogenetically conserved, and are homologous to those previously described in yeast (5' hinge-ETS) and trypanosomes (3' hinge-ETS). A model is presented where the base-pairing of the 5' hinge and 3' hinge of U3 snoRNA with the ETS of pre-rRNA helps to correctly position U3 boxes A'+A for their function in rRNA processing. Like an earlier proposal for yeast, boxes A' and A of Xenopus may base-pair with 18 S sequences in pre-rRNA. We present the first direct experimental evidence in any system that box A' is essential for U3 snoRNA function in 18 S rRNA formation. The analysis of insertions and deletions indicated that the spacing between the U3 elements is important, suggesting that they base-pair with the ETS and 18 S regions of pre-rRNA at the same time.     

Sequence specificity of in vivo reverse splicing of the Tetrahymena group I intron.

Reverse splicing of group I introns is proposed to be a mechanism by which intron sequences are transferred to new genes. Integration of the Tetrahymena intron into the Escherichia coli 23S rRNA via reverse splicing depends on base pairing between the guide sequence of the intron and the target site. To investigate the substrate specificity of reverse splicing, the wild-type and 18 mutant introns with different guide sequences were expressed in E. coli. Amplification of intron-rRNA junctions by RT-PCR revealed partial reverse splicing at 69 sites and complete integration at one novel site in the 23S rRNA. Reverse splicing was not observed at some potential target sites, whereas other regions of the 23S rRNA were more reactive than expected. The results indicate that the frequency of reverse splicing is modulated by the structure of the rRNA. The intron is spliced 10-fold less efficiently in E. coli from a novel integration site (U2074) in domain V of the 23S rRNA than from a site homologous to the natural splice junction of the Tetrahymena 26S rRNA, suggesting that the forward reaction is less favored at this site.