X-ray crystallographic observation of "in-line" and "adjacent" conformations in a bulged self-cleaving RNA/DNA hybrid.

The RNA strand in an RNA/DNA duplex with unpaired ribonucleotides can undergo self-cleavage at bulge sites in the presence of a variety of divalent metal ions (Hüsken et al., Biochemistry, 1996, 35:16591-16600). Transesterification proceeds via an in-line mechanism, with the 2'-OH of the bulged nucleotide attacking the 3'-adjacent phosphate group. The site-specificity of the reaction is most likely a consequence of the greater local conformational freedom of the RNA backbone in the bulge region. A standard A-form backbone geometry prohibits formation of an in-line arrangement between 2'-oxygen and phosphate. However, the backbone in the region of an unpaired nucleotide appears to be conducive to an in-line approach. Therefore, the bulge-mediated phosphoryl transfer reaction represents one of the simplest RNA self-cleavage systems. Here we focus on the conformational features of the RNA that underlie site-specific cleavage. The structures of an RNA/DNA duplex with single ribo-adenosyl bulges were analyzed in two crystal forms, permitting observation of 10 individual conformations of the RNA bulge moiety. The bulge geometries cover a range of relative arrangements between the 2'-oxygen of the bulged nucleotide and the P-O5' bond (including adjacent and near in-line) and give a detailed picture of the conformational changes necessary to line up the 2'-OH nucleophile and scissile bond. Although metal ions are of crucial importance in the catalysis of analogous cleavage reactions by ribozymes, it is clear that local strain or conformational flexibility in the RNA also affect cleavage selectivity and rate (Soukup & Breaker, RNA, 1999, 5:1308-1325). The geometries of the RNA bulges frozen out in the crystals provide snapshots along the reaction pathway prior to the transition state of the phosphoryl transfer reaction.

Structural origins of the exonuclease resistance of a zwitterionic RNA.

Nuclease resistance and RNA affinity are key criteria in the search for optimal antisense nucleic acid modifications, but the origins of the various levels of resistance to nuclease degradation conferred by chemical modification of DNA and RNA are currently not understood. The 2'-O-aminopropyl (AP)-RNA modification displays the highest nuclease resistance among all phosphodiester-based analogues and its RNA binding affinity surpasses that of phosphorothioate DNA by 1 degrees C per modified residue. We found that oligodeoxynucleotides containing AP-RNA residues at their 3' ends competitively inhibit the degradation of single-stranded DNA by the Escherichia coli Klenow fragment (KF) 3'-5' exonuclease and snake venom phosphodiesterase. To shed light on the origins of nuclease resistance brought about by the AP modification, we determined the crystal structure of an A-form DNA duplex with AP-RNA modifications at 1.6-A resolution. In addition, the crystal structures of complexes between short DNA fragments carrying AP-RNA modifications and wild-type KF were determined at resolutions between 2.2 and 3.0 A and compared with the structure of the complex between oligo(dT) and the D355A/E357A KF mutant. The structural models suggest that interference of the positively charged 2'-O-substituent with the metal ion binding site B of the exonuclease allows AP-RNA to effectively slow down degradation.

In vitro selection and characterization of streptomycin-binding RNAs: recognition discrimination between antibiotics.

As pathogens continue to evade therapeutical drugs, a better understanding of the mode of action of antibiotics continues to have high importance. A growing body of evidence points to RNA as a crucial target for antibacterial and antiviral drugs. For example, the aminocyclitol antibiotic streptomycin interacts with the 16S ribosomal RNA and, in addition, inhibits group I intron splicing. To understand the mode of binding of streptomycin to RNA, we isolated small, streptomycin-binding RNA aptamers via in vitro selection. In addition, bluensomycin, a streptomycin analogue that does not inhibit splicing, was used in a counter-selection to obtain RNAs that bind streptomycin with high affinity and specificity. Although an RNA from the normal selection (motif 2) bound both antibiotics, an RNA from the counter-selection (motif 1) discriminated between streptomycin and bluensomycin by four orders of magnitude. The binding site of streptomycin on the RNAs was determined via chemical probing with dimethylsulfate and kethoxal. The minimal size required for drug binding was a 46- and a 41-mer RNA for motifs 1 and 2, respectively. Using Pb2+ cleavage in the presence and absence of streptomycin, a conformational change spanning the entire mapped sequence length of motif 1 was observed only when both streptomycin and Mg2+ were present. Both RNAs require Mg2+ for binding streptomycin.

Social phobia and positive social events: the price of success.

Patients with generalized social phobia (N = 32; 16 men, 16 women) and nonclinical control participants (N = 32; 16 men, 16 women) took part in a social interaction that was manipulated to be successful or unsuccessful. Participants rated their ability, perceptions of others' standards, social goals, and emotional responses before and after the interactions. As predicted, the successful social interaction produced a somewhat negative response in patients with social phobia. Social success led to self-protective social goals, negative emotional states and perceptions that others would expect more in future interactions. These results indicate that positive social events may not be processed in a way that leads to a revision of negative self- and social judgments in patients with social phobia.

In vitro selection of a viomycin-binding RNA pseudoknot.

BACKGROUND: The peptide antibiotic viomycin inhibits ribosomal protein synthesis, group I intron self-splicing and self-cleavage of the human hepatitis delta virus ribozyme. To understand the molecular basis of RNA binding and recognition by viomycin, we isolated a variety of novel viomycin-binding RNA molecules using in vitro selection. RESULTS: More than 90% of the selected RNA molecules shared one continuous highly conserved region of 14 nucleotides. Mutational analyses, structural probing, together with footprinting experiments by chemical modification, and Pb2+-induced cleavage showed that this conserved sequence harbours the antibiotic-binding site and forms a stem-loop structure. Moreover, the loop is engaged in a long-range interaction forming a pseudoknot. CONCLUSIONS: A comparison between the novel viomycin-binding motif and the natural RNA target sites for viomycin showed that all these segments form a pseudoknot at the antibiotic-binding site. We therefore conclude that this peptide antibiotic has a strong selectivity for particular RNA pseudoknots.

Social phobia and social appraisal in successful and unsuccessful social interactions.

32 generalized social phobic outpatients and 32 matched nonclinical control subjects participated in a dyadic 'getting acquainted' interaction with an experimental assistant who engaged in either positive or negative social behavior. The accuracy of social phobics' and control subjects' perceptions of themselves and their partners were compared in the two conditions. Relative to observers' ratings, the social phobics displayed a negative bias in their appraisals of some, but not all, aspects of their social performance. These results suggested that social phobics may have particular difficulty gauging the nonverbal aspects of their social behavior. The phobics discounted their social competence to the same extent in the positive interaction, where their behavior was more skillful, as in the negative interaction. The social phobics were also less accurate than nonclinical controls in their appraisals of their partners, however, these phobic subjects displayed a positive bias when appraising their partner's performance.

Creating health delivery systems. Interview by Donald E. Johnson.

Coalitions between health care providers and employers that enable hospitals to focus on the important issues of the community will go a long way in controlling costs as well as answering questions of industry. In the following interview with Health Care Strategic Management's Donald E.L. Johnson, Samuel T. Wallace, president of St. Luke's Hospital, Cedar Rapids, Iowa, a 520-bed institution that serves as a center for cancer, neonatal and heart services, describes a coalition concept that can help control costs while addressing the specific health care problems of local employees.