Characterization of an anti-RNA recombinant autoantibody fragment (scFv) isolated from a phage display library and detailed analysis of its binding site on U1 snRNA.

This is the first study in which the complex of a monoclonal autoantibody fragment and its target, stem loop II of U1 snRNA, was investigated with enzymatic and chemical probing. A phage display antibody library derived from bone marrow cells of an SLE patient was used for selection of scFvs specific for stem loop II. The scFv specificity was tested by RNA immunoprecipitation and nitrocellulose filter binding competition experiments. Immunofluorescence data and immunoprecipitation of U1 snRNPs containing U1A protein, pointed to an scFv binding site different from the U1A binding site. The scFv binding site on stem loop II was determined by footprinting experiments using RNase A, RNase V1, and hydroxyl radicals. The results show that the binding site covers three sequence elements on the RNA, one on the 5' strand of the stem and two on the 3' strand. Hypersensitivity of three loop nucleotides suggests a conformational change of the RNA upon antibody binding. A three-dimensional representation of stem loop II reveals a juxtapositioning of the three protected regions on one side of the helix, spanning approximately one helical turn. The location of the scFv binding site on stem loop II is in full agreement with the finding that both the U1A protein and the scFv are able to bind stem loop II simultaneously. As a consequence, this recombinant monoclonal anti-U1 snRNA scFv might be very useful in studies on U1 snRNPs and its involvement in cellular processes like splicing.     

Scission of RNA by the chemical nuclease of 1,10-phenanthroline-copper ion: preference for single-stranded loops.

The scission of RNA by the chemical nuclease activity of 1,10-phenanthroline-copper (OP-Cu) has been studied using a lac mRNA fragment and tRNAphe as substrates. Since the chemical mechanism of scission involves oxidative attack on the ribose, scission is observed at all nucleotides including dihydrouridine and Y-bases. Specificity for single-stranded loop regions is apparent from the similarity of the reactivity of OP-Cu to the single-strand specific reagents dimethyl sulfate and diethyl pyrocarbonate using the fragment of lac mRNA as a substrate. Similar preference is observed in the reaction with tRNA although scission in the helical acceptor stem is also observed.     

2.8 A crystal structure of the malachite green aptamer

Previous in vitro selection experiments identified an RNA aptamer that recognizes the chromophore malachite green (MG) with a high level of affinity, and which undergoes site-specific cleavage following laser irradiation. To understand the mechanism by which this RNA folds to recognize specifically its ligand and the structural basis for chromophore-assisted laser inactivation, we have determined the 2.8 A crystal structure of the aptamer bound to tetramethylrosamine (TMR), a high-affinity MG analog. The ligand-binding site is defined by an asymmetric internal loop, flanked by a pair of helices. A U-turn and several non-canonical base interactions stabilize the folding of loop nucleotides around the TMR. The aptamer utilizes several tiers of stacked nucleotides arranged in pairs, triples, and a novel base quadruple to effectively encapsulate the ligand. Even in the absence of specific stabilizing hydrogen bonds, discrimination between related fluorophores and chromophores is possible due to tight packing in the RNA binding pocket, which severely limits the size and shape of recognized ligands. The site of laser-induced cleavage lies relatively far from the bound TMR ( approximately 15 A). The unusual backbone conformation of the cleavage site nucleotide and its high level of solvent accessibility may combine to allow preferential reaction with freely diffusing hydroxyl radicals generated at the bound ligand. Several observations, however, favor alternative mechanisms for cleavage, such as conformational changes in the aptamer or long-range electron transfer between the bound ligand and the cleavage site nucleotide.     

Specific binding of a basic peptide from HIV-1 Rev.

Human immunodeficiency virus type I (HIV-1) encodes a regulatory protein, Rev, which is required for cytoplasmic expression of incompletely spliced viral mRNA. Rev activity is mediated through specific binding to a cis-acting Rev responsive element (RRE) located within the env region of HIV-1. A monomer Rev binding site corresponding to 37 nucleotides of the RRE (IIB RNA) was studied by RNA footprinting, modification interference experiments and mutational analysis. Surprisingly, a 17 amino acid peptide, corresponding to the basic domain of Rev, binds specifically to this site at essentially identical nucleotides and probably induces additional base pairing. The Rev protein and related peptide interact primarily with two sets of nucleotides located at the junction of single and double stranded regions, and at an additional site located within a helix. This suggests that the domains of proteins responsible for specific RNA binding can be remarkably small and that the interaction between RNA and protein can probably induce structure in both constituents.     

Recognition of RNA encapsidation signal by the yeast L-A double-stranded RNA virus

The encapsidation signal of the yeast L-A virus contains a 24-nucleotide stem-loop structure with a 5-nucleotide loop and an A bulged at the 5' side of the stem. The Pol part of the Gag-Pol fusion protein is responsible for encapsidation of viral RNA. Opened empty viral particles containing Gag-Pol specifically bind to this encapsidation signal in vitro. We found that binding to empty particles protected the bulged A and the flanking-two nucleotides from cleavage by Fe(II)-EDTA-generated hydroxyl radicals. The five nucleotides of the loop sequence ((4190)GAUCC(4194)) were not protected. However, T1 RNase protection and in vitro mutagenesis experiments indicated that G(4190) is essential for binding. Although the sequence of the other four nucleotides of the loop is not essential, data from RNase protection and chemical modification experiments suggested that C(4194) was also directly involved in binding to empty particles rather than indirectly through its potential base pairing with G(4190). These results suggest that the Pol domain of Gag-Pol contacts the encapsidation signal at two sites: one, the bulged A, and the other, G and C bases at the opening of the loop. These two sites are conserved in the encapsidation signal of M1, a satellite RNA of the L-A virus.     

Specific binding of o-phenanthroline at a DNA structural lesion.

DNA intercalators are found to recognize a DNA lesion as a high affinity receptor site. This lesion-specific binding is observed when one strand of a DNA double helix contains an extra, unpaired nucleotide. Our assay for binding controls for the effects of sequence with a series of oligodeoxynucleotide duplexes which are identical except for the location of the lesion, an extra cytidine. Scission of the series of oligodeoxynucleotides by the cuprous complex of ortho-phenanthroline (OP-Cu) indicates that OP-Cu binds at the lesion-specific stable intercalation site, suggesting that OP-Cu intercalates into DNA. The dispersion of OP-Cu scission sites over three residues is consistent with scission via a diffusible intermediate. The location of the scission sites, directly on the 3' side of the lesion, is consistent with minor groove binding in B DNA.     

The RNA binding site of S8 ribosomal protein of Escherichia coli: Selex and hydroxyl radical probing studies.

The RNA binding site of ribosomal protein S8 of Escherichia coli is confined to a small region within the stem of a hairpin in 16S rRNA (nt 588-605/633-651), and thus represents a model system for understanding RNA/protein interaction rules. The S8 binding site on 16S rRNA was suspected to contain noncanonical features difficult to prove with classical genetical or biochemical means. We performed in vitro iterative selection of RNA aptamers that bind S8. For the different aptamers, the interactions with the protein were probed with hydroxyl radicals. Aptamers that were recognized according to the same structural rules as wild-type RNA, but with variations not found in nature, were identified. These aptamers revealed features in the S8 binding site that had been concealed during previous characterizations by the high base conservation throughout evolution. Our data demonstrate that the core structure of the S8 binding site is composed of three interdependent bases (nt 597/641/643), with an essential intervening adenine nucleotide (position 642). The other elements important for the binding site are a base pair (598/640) above the three interdependent bases and a bulged base at position 595, the identity of which is not important. Possible implications on the geometry of the S8 binding site are discussed with the help of a three-dimensional model.     

1,10-Phenanthroline-copper, a footprinting reagent for single-stranded regions of RNAs.

The 1,10-phenanthroline-cuprous complex (OP-Cu) with hydrogen peroxide as a coreactant nicks the single-stranded loops and bulges of RNA stem-loop structures more rapidly than the double-stranded stems. This chemical nuclease is therefore a useful footprinting reagent for these regions and can be used to monitor both intramolecular and intermolecular hybridization of single-stranded domains. The formation of A-form structures characteristic of either RNA-RNA or RNA-DNA duplexes inhibits scission because it blocks the binding site of the coordination complex in single-stranded loops and not because the oxidatively sensitive hydrogens of the ribose moiety are blocked. The C-4' and C-1' hydrogens are accessible to solvent in A-structures.     

Mapping the interaction of SmpB with ribosomes by footprinting of ribosomal RNA

In trans-translation transfer messenger RNA (tmRNA) and small protein B (SmpB) rescue ribosomes stalled on truncated or in other ways problematic mRNAs. SmpB promotes the binding of tmRNA to the ribosome but there is uncertainty about the number of participating SmpB molecules as well as their ribosomal location. Here, the interaction of SmpB with ribosomal subunits and ribosomes was studied by isolation of SmpB containing complexes followed by chemical modification of ribosomal RNA with dimethyl sulfate, kethoxal and hydroxyl radicals. The results show that SmpB binds 30S and 50S subunits with 1:1 molar ratios and the 70S ribosome with 2:1 molar ratio. SmpB-footprints are similar on subunits and the ribosome. In the 30S subunit, SmpB footprints nucleotides that are in the vicinity of the P-site facing the E-site, and in the 50S subunit SmpB footprints nucleotides that are located below the L7/L12 stalk in the 3D structure of the ribosome. Based on these results, we suggest a mechanism where two molecules of SmpB interact with tmRNA and the ribosome during trans-translation. The first SmpB molecule binds near the factor-binding site on the 50S subunit helping tmRNA accommodation on the ribosome, whereas the second SmpB molecule may functionally substitute for a missing anticodon stem–loop in tmRNA during later steps of trans-translation.     

Structural changes of tRNA and 5S rRNA induced with magnesium and visualized with synchrotron mediated hydroxyl radical cleavage

The structure of native yeast tRNA^Phe and wheat germ ribosomal 5S RNA induced by different magnesium ion concentrations was studied in solution with a synchrotron mediated hydroxyl radical RNA cleavage reaction. We showed that very small amounts of Mg⁺² can induce significant changes in the hydroxyl radical cleavage pattern of tRNA^Phe. It also turned out that a reactivity of tRNA^Phe towards OH coincides with the strong metal binding sites. Because of the Mg ions are heavily hydrated one can suggest the strong correlation of the observed nucleosides reactivity in vicinity of Mg²⁺ binding sites with availability of water molecules as a source of hydroxyl radical. On the other hand the structure of wheat germ 5S rRNA is less sensitive to the hydroxyl radical reaction than tRNA^Phe although some changes are visible at 4 mM Mg ions. It is probably due to the lack of strong Mg⁺² binding sites in that molecule. The reactivity of nucleotides in loops C and D of 5S rRNA is not effected, what suggests their flexibility or involvement in higher order structure formation. There is different effect of magnesium on tRNA and 5S rRNA folding. We found that nucleotides forming strong binding sites for magnesium are very sensitive to X-ray generated hydroxyl radical and can be mapped with OH. The results show, that guanine nucleotides are preferentially hydrated. X-ray footprinting mediated hydroxyl radical RNA cleavage is a very powerful method and has been applied to studies of stable RNAs for the first time.     

Drosophila engrailed-1,10-phenanthroline chimeras as probes of homeodomain-DNA complexes.

We have converted the Drosophila engrailed homeodomain into a sequence-specific nuclease by linking the protein to the chemical nuclease 1,10-phenanthroline-copper (OP-Cu). Unique cysteines were introduced at six positions into the homeodomain by site-directed mutagenesis for the covalent attachment of OP-Cu. The varied DNA-binding affinity and specificity of these mutants and the DNA cleavage pattern of their OP-Cu derivatives allowed us to assess the crystal structure of the engrailed homeodomain-DNA complex. We have also achieved site-specific double-stranded DNA scission with one of the homeodomain mutants, E28C, which has the potential of being used to identify engrailed binding sites in the genome. Because the homeodomain is so well conserved among members of the homeodomain-containing protein family, other homeodomain proteins can be converted into nucleases by attaching OP-Cu at position 28 of their homeodomains.     

The spin trapping of pyrimidine nucleotide free radicals in a Fenton system.

The reaction of the hydroxyl radical, generated by a Fenton system, with pyrimidine deoxyribonucleotides was investigated by using the e.s.r. technique of spin trapping. The spin trap t-nitrosobutane was employed to trap secondary radicals formed by the reaction of the hydroxyl radical with these nucleotides. The results presented here show that hydroxyl-radical attack on thymidine, 2-deoxycytidine 5-monophosphate and 2-deoxyuridine 5-monophosphate produced nucleotide-derived free radicals. The results indicate that .OH radical attack occurs predominantly at the carbon-carbon double bond of the pyrimidine base. The e.s.r. studies showed a good correlation with previous results obtained by authors who used x- or gamma-ray irradiation to generate the hydroxyl radical. A thiobarbituric acid assay was also used to monitor the damage produced to the nucleotides by the Fenton system. These results showed qualitative agreement with the spin-trapping studies.     

Guanosine binding required for cyclization of the self-splicing intervening sequence ribonucleic acid from Tetrahymena thermophila

We have converted the intramolecular cyclization reaction of the self-splicing intervening sequence (IVS) ribonucleic acid (RNA) from Tetrahymena thermophila into an intermolecular guanosine addition reaction. This was accomplished by selectively removing the 3'-terminal nucleotide by oxidation and beta-elimination; the beta-eliminated IVS thereby is no longer capable of reacting with itself. However, under cyclization conditions, a free guanosine molecule can make a nucleophilic attack at the normal cyclization site. We have used this guanosine addition reaction as a model system for a Michaelis-Menten kinetic analysis of the guanosine binding site involved in cyclization. The results indicate that functional groups on the guanine that are used in a G-C Watson-Crick base pair are important for the cyclization reaction. This is the same result that was obtained for the guanosine binding site involved in splicing [Bass, B. L., & Cech, T. R. (1984) Nature (London) 308, 820-826]. Unlike splicing, however, certain additional nucleotides 5' to the guanosine moiety make significant binding contributions. We conclude that the guanosine binding site in cyclization is similar to, but not identical with, the guanosine binding site in splicing. The same binding interactions used in cyclization could help align the 3' splice site of the rRNA precursor for exon ligation. We also report that the phosphodiester bond at the cyclization site is susceptible to a pH-dependent hydrolysis reaction; the phosphodiester bond is somehow activated toward attack by the 3'hydroxyl of a guanosine molecule or by a hydroxyl ion.     

Mapping the ribosomal protein S7 regulatory binding site on mRNA of the E. coli streptomycin operon

In this work it is shown by deletion analysis that an intercistronic region (ICR) approximately 80 nucleotides in length is necessary for interaction with recombinant E. coli S7 protein (r6hEcoS7). A model is proposed for the interaction of S7 with two ICR sites-region of hairpin bifurcations and Shine-Dalgarno sequence of cistron S7. A de novo RNA binding site for heterologous S7 protein of Thermus thermophilus (r6hTthS7) was constructed by selection of a combinatorial RNA library based on E. coli ICR: it has only a single supposed protein recognition site in the region of bifurcation. The SERW technique was used for selection of two intercistronic RNA libraries in which five nucleotides of a double-stranded region, adjacent to the bifurcation, had the randomized sequence. One library contained an authentic AG (?82/?20) pair, while in the other this pair was replaced by AU. A serwamer capable of specific binding to r6hTthS7 was selected; it appeared to be the RNA68 mutant with eight nucleotide mutations. The serwamer binds to r6hTthS7 with the same affinity as homologous authentic ICR of str mRNA binds to r6hEcoS7; apparent dissociation constants are 89 ± 43 and 50 ± 24 nM, respectively.     

Rapid formation of a solvent-inaccessible core in the Neurospora Varkud satellite ribozyme

We have used hydroxyl radicals generated by decomposition of peroxynitrous acid to study Mg(2+)-dependent structure and folding of the Varkud satellite (VS) ribozyme. Protection from radical cleavage shows the existence of a solvent-inaccessible core, which includes nucleotides near two three-helix junctions, the kissing interaction between stem-loops I and V and other nucleotides, most of which have also been implicated as important for folding or activity. Kinetic folding experiments showed that the ribozyme folds very quickly, with the observed protections completely formed within 2 s of addition of MgCl(2). In mutants that disrupt the kissing interaction or entirely remove stem-loop I, which contains the cleavage site, nucleotides in the three-helix junctions and a subset of those elsewhere remain protected. Unlike smaller ribozymes, the VS ribozyme retains a significant amount of structure in the absence of its substrate. Protections that depend on proper interaction between the substrate and the rest ribozyme map to a region previously proposed as the active site of the ribozyme and along both sides of helix II, identifying candidate sites of docking for the substrate helix.     

A more complex isoleucine aptamer with a cognate triplet

The simplest RNA that can meet a column affinity selection for isoleucine was previously defined using selection amplification with decreasing numbers of randomized nucleotides. This simplest UAUU motif was a small asymmetric internal loop. Conserved positions of the loop include isoleucine codon and anticodon triplets (Lozupone C., Changayil, S., Majerfeld, I., and Yarus, M. (2003) RNA (N. Y.) 9, 1315-1322). Using new primer sequences, we now select a somewhat more complex isoleucine binding RNA, requiring 4.7 more bits of information to describe. The newly selected structure is a terminal or hairpin loop of 20 nucleotides, 15 being invariant. An information profile shows that the new binding site contains five short functional loop regions joined by less significant single nucleotide positions. Among the important nucleotides is a conserved isoleucine anticodon, supporting the escaped triplet theory, which posits a stereochemical genetic code originating in RNA amino acid binding sites.