Investigation of the tertiary folding of<i>Escherichia coli</i>16s RNA by<i>in situ</i>intra-RNA crosslinking within 30S ribosomal subunits

Atmadja, Johannes; Brimacombe, Richard; Blöcker, Helmut; Frank, Ronald

doi:10.1093/nar/13.19.6919

Cited by 39 publications

(18 citation statements)

References 26 publications

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“…refs. [10][11][12][13]. Cross-linking is a purely topographical approach, which serves to pinpoint sites of contact or neighbourhood within the RNA or between the individual proteins and the RNA, whereas the protection studies indicate RNA regions where an extensive physical interaction with the proteins occurs.…”

Section: Introductionmentioning

confidence: 99%

Protein binding sites onEscherichia coli16S RNA; RNA regions that are protected by proteins S7, S14 and S19 in the presence or absence of protein S9

Wiener

Brimacombe

1987

Nucl Acids Res

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14C-labelled proteins from E. coli 30S ribosomal subunits were isolated by HPLC, and selected groups of these proteins were reconstituted with 32P-labelled 16S RNA. The isolated reconstituted particles were partially digested with ribonuclease A, and the RNA fragments protected by the proteins were separated by gel electrophoresis and subjected to sequence analysis. Protein S7 alone gave no protected fragments, but S7 together with S14 and S19 protected an RNA region comprising the sequences 936-965, 972-1030, 1208-1262 and 1285-1379 of the 16S RNA. Addition of increasing amounts of protein S9 to the S7/S14/S19 particle resulted in a parallel increase in the protection of the hairpin loop between bases 1262 and 1285. The results are discussed in terms of the three-dimensional folding of 16S RNA in the 30S subunit.

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Section: Introductionmentioning

confidence: 99%

Protein binding sites onEscherichia coli16S RNA; RNA regions that are protected by proteins S7, S14 and S19 in the presence or absence of protein S9

Wiener

Brimacombe

1987

Nucl Acids Res

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“…These helices are surrounded by helices 2 and 3, which may be involved in intramolecular switching in the rRNA with helices 28-30 (43). The secondary structure of this region is not clearly defined in eukaryotes, but it is probably organized in a different way than in prokaryotes (usually helix 17 is not stable) (22).…”

Section: Resultsmentioning

confidence: 99%

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

Herzog

Maroteaux

1986

Proc. Natl. Acad. Sci. U.S.A.

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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.In the five-kingdom system for classification of organisms (1) (3) and possessing a number of peculiar traits of nuclear organization (4) suggestive ofthe prokaryotic state. Among this unusual primitive pattern of nuclear organization, the most striking feature is the now well-documented absence of histones and nucleosomal structures. Dinoflagellate chromatin fibrils, which appear as smooth filaments in electron microscopy, are associated with a low amount of one or two major basic proteins whose amino acid composition is different from known prokaryotic basic proteins or eukaryotic histones (5-7). Nuclease digestion of purified nuclei lends to a smear with no recognizable discrete DNA fragments (8, 9). Permanently condensed chromosomes are stabilized by divalent cations and RNA (10, 11). In eukaryotes histones and especially the histone H1, which is thought to be primarily responsible for organizing higherorder structure of nucleosomes, are involved in gene repression (12). Thus, the problem of gene regulation in such organisms is still unsolved, with a prokaryotic-like chromatin organization and some of the following eukaryotic nuclear traits: (i) The portion of repeated sequences (around 60%) is typical for eukaryotes (13). (ii) The rRNA is synthesized as a precursor of 38S, and a 5.8S rRNA has been reported to be released from the 27S precursor to give rise to the final 24S RNA (14). (iii) The 5S rRNA sequence shows greater homology with that of higher eukaryotes than that of eubacteria (15), but additional molecular data (16) indicate that it contains some conserved residues specific for lower eukaryotes (unpublished data) and that the general structure of the 5S rRNA from sulfolobale and thermoplasmale archaeobacteria is also closer to that of eukaryotes than that of eubacteria (17). (iv) Poly(ADP-ribose) polymerase activity is detectable (18). (v) The small nuclear RNAs U1-U5 have been isolated (19). The U5 dinoflagellate sequence shows strong homology (63%) with that of vertebrates (20), but appears to be more homologous to that of Tetrahymena (70%) (ref. 21, and unpublished data). Thus these molecular data, in addition to the interpretat...

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“…Clearly, the most important parameters determining the eventual formation of a link from a photoactivated s4U and a proteic group are the proximity and orientation factors between the putative reactive groups or atoms as well as the nature of the immediate environment. For example, although the 254-nm photochemistry of nucleic acid residues in solution or in model polynucleotides tell us that by far the pyrimidines are the most reactive, there are numerous recent examples where in the tertiary folding of 16s RNA in the 30s particle Pur-Pur adducts appear to form efficiently (Atmadja and Brimacombe, 1985). Another parameter that should be considered is the excited state life-time of the base, since adequate positioning may only OCCUI transiently.…”

Section: -Thiouridine Model Reactionsmentioning

confidence: 99%

“…In addition to the photoreaction upon the 5-6 double bond already found in photoexcited uridine and cytosine, another photoreactive site is found, namely the C4 sulfur bond. Classically this C-S bond is involved in thietane formation between excited s4U and pyrimidines (Bergstrom and Leonard, 1972) leading to the 8-13 link in tRNA (Favre et al, 1972). Photoreactions relevant to the photoaddition of amino acids have not been extensively studied.…”

Section: -Thiouridine Model Reactionsmentioning

confidence: 99%

RNA PROTEIN CROSSLINKS INTRODUCED INTO E. coli RIBOSOMES BY USE OF THE INTRINSIC PROBE 4‐THIOURIDINE

Hajnsdorf

Dubreuil

Bezerra

et al. 1987

Photochem & Photobiology

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Abstract— 70S Ribosome substituted by the uridine photoactivable analogue 4‐thiouridine has been prepared by an in vivo method (substitution level 4.5%). The r‐proteins crosslinked to 16S and 23S rRNA before and after 366‐nm photoactivation were identified. Proteins S2‐S7‐S9/11‐S18 are found linked to 16S RNA in dark‐prepared 30S subunits. Illumination increases uniformly their binding by a factor of 2.5. Similarly, proteins L5‐L15‐L18‐L23‐L28‐L32 are found crosslinked to 23S RNA in dark‐prepared 50S subunits. Photoactivation increases their binding but in addition promotes the covalent linking of proteins L1‐L3‐L4.

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Investigation of the tertiary folding ofEscherichia coli16s RNA byin situintra-RNA crosslinking within 30S ribosomal subunits

Cited by 39 publications

References 26 publications

Protein binding sites onEscherichia coli16S RNA; RNA regions that are protected by proteins S7, S14 and S19 in the presence or absence of protein S9

Protein binding sites onEscherichia coli16S RNA; RNA regions that are protected by proteins S7, S14 and S19 in the presence or absence of protein S9

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

RNA PROTEIN CROSSLINKS INTRODUCED INTO E. coli RIBOSOMES BY USE OF THE INTRINSIC PROBE 4‐THIOURIDINE

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