Structure-function relations in E. coli 16S RNA

Experimental Evolution of Anticipatory Regulation in Escherichia coli

Environmental cues in an ecological niche are often temporal in nature. For instance, in temperate climates, temperature is higher in daytime compared to during night. In response to these temporal cues, bacteria have been known to exhibit anticipatory regulation, whereby triggering response to a yet to appear cue. Such an anticipatory response in known to enhance Darwinian fitness, and hence, is likely an important feature of regulatory networks in microorganisms. However, the conditions under which an anticipatory response evolves as an adaptive response are not known. In this work, we develop a quantitative model to study response of a population to two temporal environmental cues, and predict variables which are likely important for evolution of anticipatory regulatory response. We follow this with experimental evolution of Escherichia coli in alternating environments of rhamnose and paraquat for ∼850 generations. We demonstrate that growth in this cyclical environment leads to evolution of anticipatory regulation. As a result, pre-exposure to rhamnose leads to a greater fitness in paraquat environment. Genome sequencing reveals that this anticipatory regulation is encoded via mutations in global regulators. Overall, our study contributes to understanding of how environment shapes the topology of regulatory networks in an organism.

Dinoflagellate 17S rRNA sequence inferred from the gene sequence: Evolutionary implications

We present the complete sequence of the nuclear-encoded small-ribosomal-subunit RNA inferred from the cloned gene sequence of the dinoflagellate Prorocentrum micans. The dinoflagellate 17S rRNA sequence of 1798 nucleotides is contained in a family of 200 tandemly repeated genes per haploid genome. A tentative model of the secondary structure of P. micans 17S rRNA is presented. This sequence is compared with the small-ribosomal-subunit rRNA of Xenopus laevis (Animalia), Saccharomyces cerevisiae (Fungi), Zea mays (Planta), Dictyostelium discoideum (Protoctista), and Halobacterium volcanii (Monera). Although the secondary structure of the dinoflagellate 17S rRNA presents most of the eukaryotic characteristics, it contains sufficient archaeobacterial-like structural features to reinforce the view that dinoflagellates branch off very early from the eukaryotic lineage.

Probing the function of conserved RNA structures in the 30S subunit of Escherichia coli ribosomes

Ribosomes play an active role in protein biosynthesis. Ribosomal RNA conformation in ribosomal subunits, intramolecular interactions between different rRNA sequences within the confinement of the particles, and intermolecular interactions are presumed necessary to support efficient and accurate protein synthesis. Here we report an analysis of the disposition of 16S rRNA conserved zones centered about positions 525, 1400, and 1500 in 30S subunits. Complementary oligodeoxyribonucleotides in conjunction with nuclease S1 digestion were used to do this. All of the sequences examined in 30S subunits are accessible to DNA probes of 9 to 12 nucleotide residues in length. However, the kinetic characteristics of the respective DNA interactions with 30S particles vary significantly. In addition to the investigation of normal 30S particles, a four base deletion within the 1400 region of 16S rRNA was analyzed. The deletion was made by using synthetic DNAs to target the deletion site for RNase H digestion. The direct in vitro procedure for manipulating rRNA conserves nucleotide modifications. The alteration causes a significant change in the disposition of 16S rRNA in 30S subunits, suggesting a reduction in the freedom of movement of the altered zone in the particle. In a factor-dependent in vitro protein synthesis system primed with MS2 mRNA and altered 30S subunits, there was a 50% decrease in phage coat protein synthesis. The reduction could be due to a decrease in the rate of translation or premature termination of translation. We present evidence here, based on isotopic studies, which supports the latter possibility.

Intermolecular hybridization of 5S rRNA with 18S rRNA: identification of a 5'-terminally-located nucleotide sequence in mouse 5S rRNA which base-pairs with two specific complementary sequences in 18S rRNA

Eukaryotic 5S rRNA hybridizes specifically with 18S rRNA in vitro to form a stable intermolecular RNA:RNA hybrid. We have used 5S rRNA/18S rRNA fragment hybridization studies coupled with ribonuclease digestion and primer extension/chain termination analysis of 5S rRNA:18S rRNA hybrids to more completely map those mouse 5S rRNA and 18S rRNA sequences responsible for duplex formation. Fragment hybridization analysis has defined a 5'-terminal region of 5S rRNA (nucleotides 6-27) which base-pairs with two independent sequences in 18S rRNA designated Regions 1 (nucleotides 1157-1180) and 2 (nucleotides 1324-1339). Ribonuclease digestion of isolated 5S rRNA:18S rRNA hybrids with both single-strand- and double-strand-specific nucleases supports the involvement of this 5'-terminal 5S rRNA sequence in 18S rRNA hybridization. Primer extension/chain termination analysis of isolated 5S rRNA:18S rRNA hybrids confirms the base-pairing of 5S rRNA to the designated Regions 1 and 2 of 18S rRNA. Using these results, 5S rRNA:18S rRNA intermolecular hybrid structures are proposed. Comparative sequence analysis revealed the conservation of these hybrid structures in higher eukaryotes and the same but smaller core hybrid structures in lower eukaryotes and prokaryotes. This suggests that the 5S rRNA:16S/18S rRNA hybrids have been conserved in evolution for ribosome function.

An additional ribosome-binding site on mRNA of highly expressed genes and a bifunctional site on the colicin fragment of 16S rRNA from Escherichia coli: important determinants of the efficiency of translation-initiation

For various genes of E. coli, three regions (-55 to -1; -35 to -1; -21 to -1) 5' to AUG codon on mRNA were searched for sites of interaction with colicin fragment of 16S rRNA. The detailed sequence comparison points out that apart from Shine-Dalgarno base pairing, an additional ribosome-binding site, a subsequence of 5'-UGAUCC-3' invariably exists in mRNA for highly expressed genes. Poorly expressed genes appear to be controlled by only Shine-Dalgarno base pairing. The analysis indicates that in the initiator region, the -55 to -1 region contains the signal which decides the efficiency of the translation-initiation. The site on 16S rRNA, 5'-GGAUCA-3' at position 1529, that can base pair to the above site, has a recognition site on 23S rRNA at position 2390. In the light of the conserved nature and accessibility of these sites, it is proposed that the site on 16S rRNA plays a bifunctional role--initially it binds to mRNA from highly expressed genes to form a stable 30S initiation complex, and upon association with 50S subunit it exchanges base pairing with 23S rRNA, thus leaving the site on mRNA free.

Conformational analysis of 16 S ribosomal RNA from Escherichia coli by scanning transmission electron microscopy

Digitized images of molecules of 16 S rRNA from Escherichia coli, obtained by scanning transmission electron microscopy (STEM), provide quantitative structural information that is lacking in conventional electron micrographs. We have determined the morphology, total molecular mass, mass distribution within individual rRNA molecules and apparent radii of gyration. From the linear density (M/L) we have assessed the number of strands in the structural backbone of rRNA and studied the pattern of branching and folding related to the secondary and tertiary structure of rRNAs under various buffer conditions. Even in reconstitution buffer 16 S RNA did not show any resemblance to the native 30 S subunit.

Antibody-nucleic acid interactions. Antibodies to psoralen-modified RNA as probes of RNA structure

Antisera elicited by immunization of rabbits with 4'-aminomethyl-trioxsalen (AMT)-modified poly(A,U) complexed with methylated bovine serum albumin was characterized in competition radioimmunoassays (RIA) and enzyme-linked immunosorbent assays (ELISA). AMT-poly(A,U) was over 10,000-fold more reactive than unmodified poly(A,U) or AMT alone. The antiserum cross-reacted to varying extents with AMT-modified-RNA's and -DNA's. The presence of AMT-uridine usually assured strong reactivity. The amino group of AMT contributed to antibody binding to a small degree. Binding was not significantly affected by high ionic strength, suggesting that binding does not involve ion pair formation. Murine encephalomyocarditis virus replicative intermediates, as well as cellular RNA and DNA were modified by psoralen in intact cells, suggesting that EMCV RNA and cellular RNA's in intact cells possess detectable stretches of base pairs. The antibodies described here will be useful in studying the secondary and tertiary structure of RNA's in vitro and in intact cells.

Homologous ribosomal proteins in bacteria, yeast, and humans

We describe sequences of two human ribosomal proteins, S14 and S17, and messenger RNAs that encode them. cDNAs were used as molecular hybridization probes to recognize complementary genes in rodent, Drosophila, and yeast chromosomal DNAs. Human ribosomal protein sequences are compared to analogous Chinese hamster, yeast, and bacterial genes. Our observations suggest that some ribosomal protein genes have been conserved stringently in the several phylogenetic lines examined. These genes apparently were established early in evolution and encode products that are fundamental to the translational apparatus. Other ribosomal protein genes examined, although similar enough to heterologous DNA sequences to indicate their structural relationships, appear to have diverged substantially during evolution, probably reflecting adaptations to different genetic environments.

GTPase center of elongation factor Tu is activated by occupation of the second tRNA binding site

Interaction of the elongation factor EF-Tu with the antibiotic kirromycin results in activation of the GTPase center of the factor and in induction of an additional tRNA binding site (tRNA binding site II to distinguish it from the classical tRNA binding site I). Activation of the GTPase center under these conditions is stimulated by addition of tRNA. Two-fold evidence is presented that this stimulation is due to tRNA binding to site II rather than to site I. First, a strong correlation is observed between stimulation of the GTPase activity and enhancement of the reactivity of Cys-81 of EF-Tu toward N-ethylmaleimide at various concentrations of aminoacyl-tRNA, deacylated tRNA, and N-acetylaminoacyl-tRNA. The latter effects signal tRNA binding to site II. Stimulation of the kirromycin-induced GTPase activity by tRNA binding to the factor also occurs when binding to site I is completely abolished. Such an abolishment was achieved by treating EF-Tu extensively with the thiol reagent L-1-tosylamido-2-phenylethyl chloromethyl ketone. EF-Tu X GTP thus treated has lost its ability to protect the ester bond of aminoacyl-tRNA. The relevance of these data for the sequence of events during protein synthesis and for control of translational fidelity is discussed.

The evolution of eukaryotic ribosomal DNA

Mutations occur randomly throughout the ribosomal DNA (rDNA) sequence. Molecular drive (unequal crossing-over, gene conversion, and transposition) spreads these variations through the multiple copies of rDNA. Forces of selection act upon the variants to favor and fix them or disfavor and eliminate them. Selection has not permitted changes in regions within rRNA vital for its function; these sequences are evolutionarily conserved between diverse species. Possible functions for some of these conserved sequences are discussed. The secondary structure of rRNA is also highly conserved during evolution. However, eukaryotic rRNA is larger than prokaryotic rRNA due to blocks of "expansion segments". Arguments are put forward that expansion segments might not play any functional role. Other examples are reviewed of rDNA sequence insertion or deletion, including introns and the internal transcribed spacer 2.

tRNA nuclear transport: defining the critical regions of human tRNAimet by point mutagenesis

We recently described a carrier-mediated nuclear transport system for tRNA in Xenopus laevis oocytes. A natural human tRNAimet variant with a G to T transversion in position 57 is defective in transport across the nuclear membrane. In addition, processing of the primary transcript of the variant gene is much less efficient than the wild type. We now describe the nuclear transport and processing phenotypes of 30 different point mutants generated by in vitro mutagenesis of a wild-type human tRNAimet gene. The effects of each nucleotide change on processing and transport were analyzed in X. laevis oocytes following nuclear microinjection of each mutant gene. Mutants exhibiting transport-defective behavior were further characterized by measuring transport kinetics of the purified mature tRNA. Our studies demonstrate that many mutations affect tRNAimet nuclear transport, although those with the most deleterious effects are clustered in the highly conserved D stem-loop and T stem-loop regions.

Structure of the Escherichia coli 16 S ribosomal RNA. Psoralen crosslinks and N-acetyl-N'-(p-glyoxylylbenzoyl)cystamine crosslinks detected by electron microscopy

Escherichia coli 16 S ribosomal RNA in reconstitution buffer has been photochemically crosslinked with aminomethyltrimethylpsoralen and chemically crosslinked with N-acetyl-N'-(p-glyoxylylbenzoyl)cystamine. The positions of crosslinking have been detected by viewing the molecules in the electron microscope. DNA restriction fragments that contain psoralen mono-adducts were hybridized and crosslinked to the samples so that the orientations of the crosslinked molecules were seen directly. A two-dimensional histogram method has been used to classify the different types of looped crosslinked molecules. These methods allow the identification of 13 distinct types of loops in the photochemically crosslinked molecules and 31 distinct types of loops in the chemically crosslinked molecules. The psoralen experiments are a reinvestigation of some of our earlier results. Some of the crosslinks were previously reported in the incorrect orientation; with the corrected orientation, seven of the psoralen crosslinks can now be correlated with complementarities in the proposed secondary-structure models. However, there are still six other psoralen crosslinks that indicate additional contacts not found in the current models. The chemical crosslinks indicate pairs of single-stranded regions that must be close in the folded molecule. Many of these crosslinks occur between regions that are distant in the secondary structure; these crosslinks indicate part of the three-dimensional form of the folded molecule.

Initiator tRNA may recognize more than the initiation codon in mRNA: a model for translational initiation

A special methionine tRNA (tRNAi) is universally required to initiate translation. Amongst species a tRNAi structural conservation is most apparent in the anticodon and T arms of the molecule but extends into the variable loop and the 3' strand of the D stem. This suggested that they could share a similar ancestral or current function in initiation of translation. We report that the sequence of bases neighboring the translational start codons of many eubacterial genes are complementary not only to the extended anticodon but also to the D and T loops of tRNAi. Study of the coding properties of tRNAi and of mutations that affect translation suggests that the translational start domain can be a mosaic of signals complementary to the loops of tRNAi. The hypothesis of multiple loop recognition suggests that unusual triplets can start prokaryotic and mitochondrial genes and predicts the occurrence of other reading frames. Furthermore, it suggests a unifying model for chain initiation based on RNA contacts and displacements.

The sequence of 16S rRNA from Mycoplasma strain PG50

The DNA sequence of one of the 16S rRNA genes (cistron rrnA) of Mycoplasma strain PG50 was determined. It is 1523 bp long and has about 70% homology to the sequence of Escherichia coli 16S rRNA (rrnB). The G + C content of the sequence is 48% compared with 56% G + C in the E. coli sequence. The secondary structure is formed and it is determined that most of the differences between the two sequences are seen in stems while loops in the secondary structure are conserved. A detailed description of differences and similarities to known sequences and rRNA oligonucleotide catalogues is given, and this information is used to discuss functional properties and phylogenetic relations of mycoplasma 16S rRNA.

Photochemistry of the furan-side 8-methoxypsoralen-thymidine monoadduct inside the DNA helix. Conversion to diadduct and to pyrone-side monoadduct

We have studied the photochemical reactions of 8-methoxypsoralen (8-MOP) with calf thymus DNA. Analysis of the photoproducts formed was carried out by enzymatic digestion of the 8-MOP-modified DNA, followed by HPLC separation of photoadducts by high-pressure liquid chromatography (HPLC). The 4',5' (furan-side) monoadduct of 8-MOP bound to thymidine is converted to cross-linked thymidine-8-MOP-thymidine diadduct by 341.5 nm light with a quantum yield of 0.028 +/- 0.004. This is 4 times greater than the quantum yield for initial adduct formation (0.0065 +/- 0.0004). When low levels of 8-MOP are covalently bound to DNA by using 397.9 nm light, less than 10% of the adducts formed are diadducts yet nearly 70% are in 5'-TpA cross-linkable sites. The furan-side monoadducts in these sites can subsequently be converted to diadduct or to a lesser extent 3,4 (pyrone-side) monoadduct.

Detection of a 16S rRNA . initiator-tRNA complex by a new selective labelling method

Cupric-ion induced hydrolysis of [35S]Met-tRNA but not of N-formyl-Met-tRNAMetf permitted the specific terminal labelling of initiator tRNA. Initiator tRNA, labeled in this way, was suitable for sequence analysis without the need for further purification. By probing labeled initiator tRNA with specific RNases, changes in this molecule during its interaction with the 30S particle or with 16S rRNA were investigated. Initiation complexes were resistant to the action of single-strand, base-specific nucleases Bc and Phy M and, except for one base of the anticodon stem, were also resistant to digestion by the double-strand-specific V1 nuclease of Naja venom. In contrast, T1 RNase digestion of the initiator tRNA in the presence of 16S rRNA enhanced cleavage of bases in the T stem of the molecule.

Structural and functional analysis of Escherichia coli ribosomes containing small deletions around position 1760 in the 23S ribosomal RNA

Three different small deletions were produced at a single Pvu 2 restriction site in E. coli 23S rDNA of plasmid pKK 3535 using exonuclease Bal 31. The deletions were located around position 1760 in 23S rRNA and were characterized by DNA sequencing as well as by direct fingerprinting and S1-mapping of the rRNA. Two of the mutant plasmids, Pvu 2-32 and Pvu 2-33, greatly reduced the growth rate of transformed cells while the third mutant, Pvu 2-14 grew as fast as cells containing the wild-type plasmid pKK 3535. All three mutant 23S rRNAs were incorporated into 50S-like particles and were even found in 70S ribosomes and polysomes in vivo. The conformation of mutant 23S rRNA in 50S subunits was probed with a double-strand specific RNase from cobra venom. These analyses revealed changes in the accessibility of cleavage sites near the deletions around position 1760 and in the area around position 800 in all three mutant rRNAs. We suggest, that an altered conformation of the rRNAs at the site of the deletion is responsible for the slow growth of cells containing mutant plasmids Pvu 2-32 and Pvu 2-33.

Electron microscopy of secondary structure in partially denatured Escherichia coli 16S rRNA and 30S subunits

Loops observed in partially denatured 16S rRNA lie within three domains, each about 500 nucleotides long. The loops observed in the 5' and central domains agree well with features of the model proposed by Woese et al. [Woese, C. R., Gutell, R., Gupta, R., & Noller, H. F. (1983) Microbiol. Rev. 47, 621-669]. The structure in the 3' domain is more complex and variable but is still consistent with the model. Published psoralen cross-linking studies have reported one of the observed loops but have also identified loops other than those observed here or predicted by any secondary structure model. These loops are stabilized by increasing concentrations of Mg2+ ions and by bound ribosomal proteins. For example, protein S4 in LiCl core particles stabilizes a loop of 370 nucleotides which forms part of its putative binding site on rRNA. The loop structures are characteristic enough to permit an overall comparison of the most stable of the predicted and observed loops in 16S and 23S rRNAs. Both rRNAs show a stable 5'-terminal loop and a set of subterminal nested loops near the 3' end.

Comparison of the nucleotide sequence of soybean 18S rRNA with the sequences of other small-subunit rRNAs

We present the sequence of the nuclear-encoded ribosomal small-subunit RNA from soybean. The soybean 18S rRNA sequence of 1807 nucleotides (nt) is contained in a gene family of approximately 800 closely related members per haploid genome. This sequence is compared with the ribosomal small-subunit RNAs of maize (1805 nt), yeast (1789 nt), Xenopus (1825 nt), rat (1869 nt), and Escherichia coli (1541 nt). Significant sequence homology is observed among the eukaryotic small-subunit rRNAs examined, and some sequence homology is observed between eukaryotic and prokaryotic small-subunit rRNAs. Conserved regions are found to be interspersed among highly diverged sequences. The significance of these comparisons is evaluated using computer simulation of a random sequence model. A tentative model of the secondary structure of soybean 18S rRNA is presented and discussed in the context of the functions of the various conserved regions within the sequence. On the basis of this model, the short base-paired sequences defining the four structural and functional domains of all 18S rRNAs are seen to be well conserved. The potential roles of other conserved soybean 18S rRNA sequences in protein synthesis are discussed.

Use of psoralen monoadducts to compare the structure of 16S rRNA in active and inactive 30S ribosomal subunits

E. coli 30S ribosomes in the inactive conformation were irradiated at 390 nm in the presence of 4'-aminomethyl-4,5',8-trimethylpsoralen (AMT). This produces monoadducts in which AMT is attached to only one strand of an RNA duplex region. After unbound AMT was removed, some ribosomes were activated and then subjected to 360 nm irradiation; others were reirradiated without activation. Electron microscopic examination of 16S rRNA extracted from these two samples showed covalent rRNA loops indicative of rRNA crosslinks. The general pattern of loops closely matched that seen previously after direct psoralen crosslinking of 30S particles. However, the frequency of occurrence of one major class of loops formed by crosslinks between residues near position 500 and the 3' end was substantially lower for the activated samples, implying that the structure of the 16S rRNA in active and inactive 30S particles is different.

Detailed analysis of the higher-order structure of 16S-like ribosomal ribonucleic acids

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Structure of E. coli 16S RNA elucidated by psoralen crosslinking

E. coli 16S RNA in solution was photoreacted with hydroxymethyltrimethylpsoralen and long wave ultraviolet light. Positions of crosslinks were determined to high resolution by partially digesting the RNA with T1 RNase, separating the crosslinked fragments by two-dimensional gel electrophoresis, reversing the crosslink, and sequencing the separated fragments. This method yielded the locations of crosslinks to +/- 15 nucleotides. Even finer placement has been made on the basis of our knowledge of psoralen reactivity. Thirteen unique crosslinks were mapped. Seven crosslinks confirmed regions of secondary structure which had been predicted in published phylogenetic models, three crosslinks discriminated between phylogenetic models, and three proved the existence of new structures. The new structures were all long range interactions which appear to be in dynamic equilibrium with local secondary structure. Because this technique yields direct information about the secondary structure of large RNAs, it should prove invaluable in studying the structure of other RNAs of all sizes.