RNA-RNA interactions in the binding site of protein L24 on 23S ribosomal RNA of Escherichia coli: 1. Evidence for their occurrence between widely separated sequence regions.

Protein L24, from the Escherichia coli ribosome, protects a large region of 23S RNA against ribonuclease digestion. This protected RNA consists of a series of non-contiguous subfragments encompassing about 480 nucleotides at the 5' -end of 23S RNA (1). The present work demonstrates that this RNA moiety remains intact, after removal of protein L24, indicating that the subfragments are maintained together by RNA-RNA interactions. Using a urea washing procedure, the weakly bound RNA subfragments were selectively removed leaving more strongly interacting subfragments that were identified, by gel electrophoresis and oligonucleotide fingerprinting, and shown to derive from widely separated sequence regions.     

The structure of the RNA binding site of ribosomal proteins S8 and S15.

Proteins S8 and S15 from the 30 S ribosomal subunit of Escherichia coli were bound to 16 S RNA and digested with ribonuclease A. A ribonucleoprotein complex was isolated which contained the two proteins and three noncontiguous RNA subfragments totaling 93 nucleotides, that could be unambiguously located in the 16 S RNA sequence. We present a secondary structural model for the RNA moiety of the binding site complex, in which the two smaller fragments are extensively base-paired, respectively, to the two halves of the large fragment, to form two disconnected duplexes. Each of the two duplexes is interrupted by a small internal loop. This model is supported by (i) minimum energy considerations, (ii) sites of cleavage by ribonuclease A, and (iii) modification by the single strand-specific reagent kethoxal. The effect of protein binding on the topography of the complex is reflected in the kethoxal reactivity of the RNA moiety. In the absence of the proteins, 5 guanines are modified; 4 of these, at positions 663, 732, 733, and 741, are strongly protected from kethoxal when protein S15 is bound.     

The Escherichia coli DEAD protein DbpA recognizes a small RNA hairpin in 23S rRNA

The Escherichia coli DEAD protein DbpA is an RNA-specific ATPase that is activated by a 153-nt fragment within domain V of 23S rRNA. A series of RNA subfragments and sequence changes were used to identify the recognition elements of this RNA-protein interaction. Reducing the size of the fully active 153-nt RNA yields compromised substrates in which both RNA and ATP binding are weakened considerably without affecting the maximal rate of ATP hydrolysis. All RNAs that stimulate ATPase activity contain hairpin 92 of 23S rRNA, which is known to interact with the 3' end of tRNAs in the ribosomal A-site. RNAs with base mutations within this hairpin fail to activate ATP hydrolysis, suggesting that it is a critical recognition element for DbpA. Although the isolated hairpin fails to activate DbpA, RNAs with an extension of approximately 15 nt on either the 5' or 3' side of hairpin 92 elicit full ATPase activity. These results suggest that the binding of DbpA to RNA requires sequence-specific interactions with hairpin 92 as well as nonspecific interactions with the RNA extension. A model relating the RNA binding and ATPase activities of DbpA is presented.     

A ribonuclease-resistant region of 5S RNA and its relation to the RNA binding sites of proteins L18 and L25.

An RNA fragment, constituting three subfragments of nucleotide sequences 1-11, 69-87 and 89-120, is the most ribonuclease-resistant part of the native 5S RNA of Escherichia coli, at 0 degrees C. A smaller fragment of nucleotide sequence 69-87 and 90-110 is ribonuclease-resistant at 25 degrees. Degradation of the L25-5S RNA complex with ribonuclease A or T2 yielded RNA fragments similar to those of the free 5S RNA at 0 degrees C and 25 degrees C; moreover L25 remained strongly bound to both RNA fragments and also produced some opening of the RNA structure in at least two positions. Protein L18 initially protected most of the 5S RNA against ribonuclease digestion, at 0 degrees C, but was then gradually released prior to the formation of the larger RNA fragment. It cannot be concluded, therefore, as it was earlier (Gray et al., 1973), that this RNA fragment contains the primary binding site of L18.     

Structure of the RNA Binding Domain of a DEAD-Box Helicase Bound to Its Ribosomal RNA Target Reveals a Novel Mode of Recognition by an RNA Recognition Motif

DEAD-box RNA helicases of the bacterial DbpA subfamily are localized to their biological substrate when a carboxy-terminal RNA recognition motif domain binds tightly and specifically to a segment of 23S ribosomal RNA (rRNA) that includes hairpin 92 of the peptidyl transferase center. A complex between a fragment of 23S rRNA and the RNA binding domain (RBD) of the Bacillus subtilis DbpA protein YxiN was crystallized and its structure was determined to 2.9 Å resolution, revealing an RNA recognition mode that differs from those observed with other RNA recognition motifs. The RBD is bound between two RNA strands at a three-way junction. Multiple phosphates of the RNA backbone interact with an electropositive band generated by lysines of the RBD. Nucleotides of the single-stranded loop of hairpin 92 interact with the RBD, including the guanosine base of G2553, which forms three hydrogen bonds with the peptide backbone. A G2553U mutation reduces the RNA binding affinity by 2 orders of magnitude, confirming that G2553 is a sequence specificity determinant in RNA binding. Binding of the RBD to 23S rRNA in the late stages of ribosome subunit maturation would position the ATP-binding duplex destabilization fragment of the protein for interaction with rRNA in the peptidyl transferase cleft of the subunit, allowing it to “melt out” unstable secondary structures and allow proper folding.     

RNA-protein interactions in the ribosome: VIII. Co-operative interactions in the 50 S subunit of Escherichia coli

Six 50 S ribosomal subunit proteins, each unable to interact independently with the 23 S RNA, were shown to associate specifically with ribonucleoprotein complexes consisting of intact 23 S RNA, or fragments derived from it, and one or more RNA-binding proteins. In particular, L21 and L22 depend for attachment upon L20 and L24, respectively; L5, L10 and L11 interact individually with complexes containing L2 and L16; and one or both proteins of the $\text{L}\text{17}\text{L}\text{27}$ mixture are stimulated to bind in the presence of L1, L3, L6, L13 and L23. Moreover, L14 alone was found to interact with a fragment from the 3′ end of the 23 S RNA, even though it cannot bind to 23 S RNA. By correlating the data reported here with the findings of others, it has been possible to formulate a partial in vitro assembly map of the Escherichia coli 50 S subunit encompassing both the 5 S and 23 S RNAs as well as 21 of the 34 subunit proteins.     

Chloramphenicol-erythromycin resistance mutations in a 23S rRNA gene of Escherichia coli.

Two chloramphenicol resistance mutations were isolated in an Escherichia coli rRNA operon (rrnH) located on a multicopy plasmid. Both mutations also confer resistance to 14-atom lactone ring macrolide antibiotics, but they do not confer resistance to 16-atom lactone ring macrolide antibiotics or other inhibitors of the large ribosomal subunit. Classic genetic and recombinant DNA methods were used to map the two mutations to 154-base-pair regions of the 23S RNA genes. DNA sequencing of these regions revealed that chloramphenicol-erythromycin resistance results from a guanine-to-adenine transition at position 2057 of the 23S RNA genes of both independently isolated mutants. These mutations affect a region of 23S RNA strongly implicated in peptidyl transfer and known to interact with a variety of peptidyl transferase inhibitors.     

Application of a rapid gel method to the sequencing of fragments of 16S ribosomal RNA from Escherichia coli.

A gel sequencing method has been applied to two 5' end-labelled fragments of the 16S ribosomal RNA from E. coli. The procedure involves partial enzymatic hydrolysis by ribonucleases T1, U2 or A, in order to generate series of end-labelled subfragments terminating in guanine, adenine, or pyrimidine residues, respectively. The two fragments concerned were approximately 75 and 90 nucleotides in length, and both arose from the 3' region of the 16S RNA. The sequences deduced are compared with the published sequence of 16S RNA, and contribute information to the final ordering of the ribonuclease T1 oligonucleotides in the latter, as well as revealing some probable errors.     

Effect of actin concentration on the intermediate oxygen exchange of myosin; relation to the refractory state and the mechanism of exchange.

The effect of actin concentration on the myosin catalyzed exchange of phosphate oxygens with water accompanying ATP hydrolysis has been investigated. The extent of exchange was found to extrapolate to zero at infinite actin concentration at 23 and 0 degrees C for myosin subfragments S1(A1) and S1(A2). This result is consistent with actin associating directly with the product of the hydrolysis step and is not readily consistent with refractory state schemes in which the entire flow goes via a dissociating pathway. The possibility of a refractory state in the form of a phosphorylated intermediate or a bound metaphosphate state with hydrolysis occurring in the transition to the refractory state merits consideration. A full analysis of the dependence of intermediate exchange on the rate constants of the acto-S1 scheme is given and the errors arising from other methods of analysis are discussed. The rate of oxygen exchange was measured as 10 s-1 (23 degrees C) a value comparable with but slightly lower than the rate of reversal of the ATP cleavage step.     

Letter: Binding of 50 S ribosomal subunit proteins to 23 S RNA of Escherichia coli

Each of the 50 S ribosomal subunit proteins of Escherichia coli was tested independently in two laboratories for its ability to bind specifically to 23 S RNA. Four new RNA-binding proteins, L1, L3, L4 and L13 were identified in this way. Consistent with earlier work, proteins L2, L6, L16, L20, L23 and L24 were found to interact directly and independently with 23 S RNA as well. No binding of L17 was detected, however, contrary to previous reports, and the results for L19 were variable. The molar ratio of protein and RNA in each complex was measured at saturation. Significant differences in binding stoichiometry were noted among the various proteins. In addition, saturation levels were found to be influenced by the state of both the RNA and the proteins.     

Chemical crosslinking of elongation factor G to the 23S RNA in 70S ribosomes from Escherichia coli

Elongation factor G was crosslinked to the 23S RNA of 70S Escherichia coli ribosomes with the bifunctional, cleavable reagent diepoxybutane (DEB). The EF-G-23S RNA complex was isolated and digested with ribonuclease A. After digestion, an RNA fragment, protected by EF-G was cleaved from the complex and isolated. The nucleotide sequence of this RNA fragment was determined by partial ribonuclease digestion. It proved to be 27 nucleotides long and it could be identified with residues 1055 to 1081 of the nucleotide sequence of E. coli 23S RNA. In the presence of thiostrepton, which prevents binding of EF-G to the ribosome, there was a dramatic decrease in the yield of this complex.     

Properties of Antigenomic Hepatitis Delta Virus Ribozyme That Consists of Three RNA Oligomer Strands

A three-strand ribozyme, a derivative of antigenomic hepatitis delta virus (HDV) ribozyme, which consists of subfragments of 16 (L), 17 (S), and 33 nucleotides (B), has been constructed. The ternary B-L-S complex formed by the subfragments in stoichiometric ratio was able to catalyze a self-cleavage reaction. Kinetics of this reaction exhibited biphasic behavior and the same parameters as in the case of natural cis-ribozyme. Study of kinetics of reaction initiated by adding various reaction components and the study of binary complex formation between subfragments B and L, B and S, and also ternary B-L-S complex formation revealed that: 1) in the presence of Mg2+, B and S form a stoichiometric complex, L and S do not form complex at all, while B and L form 2 types of complexes, probably B-L and 2B-L; and addition of S subfragment prevented the formation of the latter complex; 2) the reaction initiated by S subfragment proceeds much slower than that initiated by other components pointing to the possibility that in the absence of S L may form a nonproductive complex with B, which is slowly displaced by S followed by productive ternary complex formation. Dissociation constants for binary B-L, B-S and ternary B-L-S complexes have been estimated.     

Antibiotic interactions at the GTPase-associated centre within Escherichia coli 23S rRNA.

A comprehensive range of chemical reagents and ribonucleases was employed to investigate the interaction of the antibiotics thiostrepton and micrococcin with the ribosomal protein L11-23S RNA complex and with the 50S subunit. Both antibiotics block processes associated with the ribosomal A-site but differ in their effects on GTP hydrolysis, which is inhibited by thiostrepton and stimulated by micrococcin. The interaction sites of both drugs were shown to occur within the nucleotide sequences A1067-A1098 within the protein L11 binding site on 23S RNA. This region of the ribosome structure is involved in elongation factor-G-dependent GTP hydrolysis and in the stringent response. No effects of drug binding were detected elsewhere in the 23S RNA. In general, the two drugs afforded 23S RNA similar protection from the chemical and nuclease probes in accord with their similar modes of action. One important exception, however, occurred at nucleotide A1067 within a terminal loop where thiostrepton protected the N-1 position while micrococcin rendered it more reactive. This difference correlates with the opposite effects of the two antibiotics on GTPase activity.     

Fragment of protein L18 from the Escherichia coli ribosome that contains the 5S RNA binding site.

A fragment of ribosomal protein L18 was prepared by limited trypsin digestion of a specific complex of L18 and 5S RNA. It was characterised for sequence and the very basic N-terminal region of the protein was found to be absent. No smaller resistant fragments were produced. 5S RNA binding experiments indicated that the basic N-terminal region, from amino acid residues 1 to 17, was not important for the L18-5S RNA association. Under milder trypsin digestion conditions three resistant fragments were produced from the free protein. The largest corresponded to that isolated from the complex. The smaller ones were trimmed slightly further at both N- and C-terminal ends. These smaller fragments did not reassociate with 5S RNA. It was concluded on the basis of the trypsin protection observations and the 5S RNA binding results that the region extending from residues 18 to 117 approximates to the minimum amount of protein required for a specific and stable protein-RNA interaction. The accessibility of the very basic N-terminal region of L18, in the L18-5S RNA complex, suggests that it may be involved, in some way, in the interaction of 5S RNA with 23S RNA.     

Purification and characterization of nebulin subfragments produced by 0.1 mM CaCl2.

Nebulin, which forms a long inextensible filament in sarcomeres, was fragmented into 200-, 180-, 40-, 33-, and 23-kDa subfragments on treatment with 0.1 mM CaCl2. The subfragments released from myofibrils were successfully purified by immunoaffinity column chromatography. The 200-, 40-, 33-, and 23-kDa subfragments were released from myofibrils and occupied 80% of the nebulin filaments. The remainder comprised the 180-kDa subfragment bound to the myofibrils. There is a possibility that an entire nebulin filament is constructed from the 200-, 180-, 40-, 33-, and 23-kDa subfragments. We have developed a new "fluorescence-method" to detect the binding of calcium ions to a protein using quin2, and clarified that nebulin is a calcium-binding protein, and that calcium ions bind to the 200-, 40-, and 23-kDa subfragments. Nebulin filaments are probably fragmented on the binding of large amounts of calcium ions to the 200-, 40-, and 23-kDa subfragments.     

Studies on the binding of the ribosomal protein complex L7/12-L10 and protein L11 to the 5''-one third of 23S RNA: a functional centre of the 50S subunit.

The RNA binding sites of the protein complex of L7/12 dimers and L10, and of protein L11, occur within the 5'-one third of 23S RNA. Binding of the L7/12-L10 protein complex to the 23S RNA is stimulated by protein L11 and vice-versa. This is the second example to be established of mutual stimulation of RNA binding by two ribosomal proteins or protein complexes, and suggests that this may be an important principle governing ribosomal protein-RNA assembly. When the L7/12-L10 complex is bound to the RNA, L10 becomes strongly resistant to trypsin. Since the L7/12 dimer does not bind specifically to the 23S RNA, this suggests that L10 constitutes a major RNA binding site of the protein complex. Only one of the L7/12 dimers is bound strongly in the (L7/12-L10)-23S RNA complex; the other can dissociate with no concurrent loss of L10.     

Evidence for tertiary structural RNA-RNA interactions within the protein S4 binding site at the 5''-end of 16S ribosomal RNA of Escherichia coli.+.

Evidence is presented for tertiary structural interaction(s) (interactions(s) between two regions of an RNA molecule that are widely separated in the RNA sequence) within the 5'-one third of the 16S ribosomal RNA of Escherichia coli that constitutes the binding site of protein S4. The two main interacting RNA regions were separated by about 120 nucleotides (sections Q to M) of the 16S RNA sequence. A second, smaller gap, of 13 nucleotides, occurred within section C". The two main interacting regions contain about 150 nucleotides (sections H" to Q) and 160 nucleotides (sections M to C"). They are folded back on one another and, especially in the presence of protein S4, are strongly protected against ribonuclease digestion. The intermediate region (sections Q to M), however, is relatively accessible to ribonucleases in the S4-RNP. By partial removal of subfragments from the RNA complex it was possible to localise the two main interacting sites within sections H" - H and sections I" - C". Three main criteria for the specificity of the RNA-RNA interactions were invoked and satisfied. The possibility of other tertiary structural RNA-RNA interactions occurring in other regions of the 16S RNA is discussed. Finally, all the structural information on the S4-RNP is summarised and a tentative model is proposed.     

Crystal structure of the ffh and EF-G binding sites in the conserved domain IV of Escherichia coli 4.5S RNA

BACKGROUND: Bacterial signal recognition particle (SRP), consisting of 4.5S RNA and Ffh protein, plays an essential role in targeting signal-peptide-containing proteins to the secretory apparatus in the cell membrane. The 4.5S RNA increases the affinity of Ffh for signal peptides and is essential for the interaction between SRP and its receptor, protein FtsY. The 4.5S RNA also interacts with elongation factor G (EF-G) in the ribosome and this interaction is required for efficient translation. RESULTS: We have determined by multiple anomalous dispersion (MAD) with Lu(3+) the 2.7 A crystal structure of a 4.5S RNA fragment containing binding sites for both Ffh and EF-G. This fragment consists of three helices connected by a symmetric and an asymmetric internal loop. In contrast to NMR-derived structures reported previously, the symmetric loop is entirely constituted by non-canonical base pairs. These pairs continuously stack and project unusual sets of hydrogen-bond donors and acceptors into the shallow minor groove. The structure can therefore be regarded as two double helical rods hinged by the asymmetric loop that protrudes from one strand. CONCLUSIONS: Based on our crystal structure and results of chemical protection experiments reported previously, we predicted that Ffh binds to the minor groove of the symmetric loop. An identical decanucleotide sequence is found in the EF-G binding sites of both 4.5S RNA and 23S rRNA. The decanucleotide structure in the 4.5S RNA and the ribosomal protein L11-RNA complex crystals suggests how 4.5S RNA and 23S rRNA might interact with EF-G and function in translating ribosomes.     

The secondary structure of the protein L1 binding region of ribosomal 23S RNA. Homologies with putative secondary structures of the L11 mRNA and of a region of mitochondrial 16S rRNA.

An heterologous complex was formed between E. coli protein L1 and P. vulgaris 23S RNA. We determined the primary structure of the RNA region which remained associated with protein L1 after RNase digestion of this complex. We also identified the loci of this RNA region which are highly susceptible to T1, S1 and Naja oxiana nuclease digestions respectively. By comparison of these results with those previously obtained with the homologous regions of E. coli and B. stearothermophilus 23S RNAs, we postulate a general structure for the protein L1 binding region of bacterial 23S RNA. Both mouse and human mit 16S rRNAs and Xenopus laevis and Tetrahymena 28S rRNAs contain a sequence similar to the E. coli 23s RNS region preceding the L1 binding site. The region of mit 16S rRNA which follows this sequence has a potential secondary structure bearing common features with the L1-associated region of bacterial 23S rRNA. The 5'-end region of the L11 mRNA also has several sequence potential secondary structures displaying striking homologies with the protein L1 binding region of 23S rRNA and this probably explains how protein L1 functions as a translational repressor. One of the L11 mRNA putative structures bears the features common to both the L1-associated region of bacterial 23S rRNA and the corresponding region of mit 16S rRNA.