@article{ashraf_guenther_ansari_malkiewicz_sochacka_agris_2000, title={Role of modified nucleosides of yeast tRNA(Phe) in ribosomal binding}, volume={33}, ISSN={["1559-0283"]}, DOI={10.1385/CBB:33:3:241}, abstractNote={Naturally occurring nucleoside modifications are an intrinsic feature of transfer RNA (tRNA), and have been implicated in the efficiency, as well as accuracy-of codon recognition. The structural and functional contributions of the modified nucleosides in the yeast tRNA(Phe) anticodon domain were examined. Modified nucleosides were site-selectively incorporated, individually and in combinations, into the heptadecamer anticodon stem and loop domain, (ASL(Phe)). The stem modification, 5-methylcytidine, improved RNA thermal stability, but had a deleterious effect on ribosomal binding. In contrast, the loop modification, 1-methylguanosine, enhanced ribosome binding, but dramatically decreased thermal stability. With multiple modifications present, the global ASL stability was mostly the result of the individual contributions to the stem plus that to the loop. The effect of modification on ribosomal binding was not predictable from thermodynamic contributions or location in the stem or loop. With 4/5 modifications in the ASL, ribosomal binding was comparable to that of the unmodified ASL. Therefore, modifications of the yeast tRNA(Phe) anticodon domain may have more to do with accuracy of codon reading than with affinity of this tRNA for the ribosomal P-site. In addition, we have used the approach of site-selective incorporation of specific nucleoside modifications to identify 2'O-methylation of guanosine at wobble position 34 (Gm34) as being responsible for the characteristically enhanced chemical reactivity of C1400 in Escherichia coli 16S rRNA upon ribosomal footprinting of yeast tRNA(Phe). Thus, effective ribosome binding of tRNA(Phe) is a combination of anticodon stem stability and the correct architecture and dynamics of the anticodon loop. Correct tRNA binding to the ribosomal P-site probably includes interaction of Gm34 with 16S rRNA C1400.}, number={3}, journal={CELL BIOCHEMISTRY AND BIOPHYSICS}, author={Ashraf, SS and Guenther, RH and Ansari, G and Malkiewicz, A and Sochacka, E and Agris, PF}, year={2000}, pages={241–252} }
 @article{yarian_basti_cain_ansari_guenther_sochacka_czerwinska_malkiewicz_agris_1999, title={Structural and functional roles of the N1-and N3-protons of Psi at tRNA's position 39}, volume={27}, ISSN={["1362-4962"]}, DOI={10.1093/nar/27.17.3543}, abstractNote={Pseudouridine at position 39 (Psi(39)) of tRNA's anticodon stem and loop domain (ASL) is highly conserved. To determine the physicochemical contributions of Psi(39)to the ASL and to relate these properties to tRNA function in translation, we synthesized the unmodified yeast tRNA(Phe)ASL and ASLs with various derivatives of U(39)and Psi(39). Psi(39)increased the thermal stability of the ASL (Delta T (m)= 1.3 +/- 0.5 degrees C), but did not significantly affect ribosomal binding ( K (d)= 229 +/- 29 nM) compared to that of the unmodified ASL (K (d)= 197 +/- 58 nM). The ASL-Psi(39)P-site fingerprint on the 30S ribosomal subunit was similar to that of the unmodified ASL. The stability, ribosome binding and fingerprint of the ASL with m(1)Psi(39)were comparable to that of the ASL with Psi(39). Thus, the contribution of Psi(39)to ASL stability is not related to N1-H hydrogen bonding, but probably is due to the nucleoside's ability to improve base stacking compared to U. In contrast, substitutions of m(3)Psi(39), the isosteric m(3)U(39)and m(1)m(3)Psi(39)destabilized the ASL by disrupting the A(31)-U(39)base pair in the stem, as confirmed by NMR. N3-methylations of both U and Psi dramatically decreased ribosomal binding ( K (d)= 1060 +/- 189 to 1283 +/- 258 nM). Thus, canonical base pairing of Psi(39)to A(31)through N3-H is important to structure, stability and ribosome binding, whereas the increased stability and the N1-proton afforded by modification of U(39)to Psi(39)may have biological roles other than tRNA's binding to the ribosomal P-site.}, number={17}, journal={NUCLEIC ACIDS RESEARCH}, author={Yarian, CS and Basti, MM and Cain, RJ and Ansari, G and Guenther, RH and Sochacka, E and Czerwinska, G and Malkiewicz, A and Agris, PF}, year={1999}, month={Sep}, pages={3543–3549} }
 @article{ashraf_ansari_guenther_sochacka_malkiewicz_agris_1999, title={The uridine in "U-turn": Contributions to tRNA-ribosomal binding}, volume={5}, ISSN={["1469-9001"]}, DOI={10.1017/S1355838299981931}, abstractNote={"U-turns" represent an important class of structural motifs in the RNA world, wherein a uridine is involved in an abrupt change in the direction of the polynucleotide backbone. In the crystal structure of yeast tRNAPhe, the invariant uridine at position 33 (U33), adjacent to the anticodon, stabilizes the exemplar U-turn with three non-Watson-Crick interactions: hydrogen bonding of the 2'-OH to N7 of A35 and the N3-H to A36-phosphate, and stacking between C32 and A35-phosphate. The functional importance of each noncanonical interaction was determined by assaying the ribosomal binding affinities of tRNAPhe anticodon stem and loop domains (ASLs) with substitutions at U33. An unsubstituted ASL bound 30S ribosomal subunits with an affinity (Kd = 140+/-50 nM) comparable to that of native yeast tRNAPhe (Kd = 100+/-20 nM). However, the binding affinities of ASLs with dU-33 (no 2'-OH) and C-33 (no N3-H) were significantly reduced (2,930+/-140 nM and 2,190+/-300 nM, respectively). Surprisingly, the ASL with N3-methyluridine-33 (no N3-H) bound ribosomes with a high affinity (Kd = 220+/-20 nM). In contrast, ASLs constructed with position 33 uridine analogs in nonstacking, nonnative, and constrained conformations, dihydrouridine (C2'-endo), 6-methyluridine (syn) and 2'O-methyluridine (C3'-endo) had almost undetectable binding. The inability of ASLs with 6-methyluridine-33 and 2'O-methyluridine-33 to bind ribosomes was not attributable to any thermal instability of the RNAs. These results demonstrate that proton donations by the N3-H and 2'OH groups of U33 are not absolutely required for ribosomal binding. Rather, the results suggest that the overall uridine conformation, including a dynamic (C3'-endo > C2'-endo) sugar pucker, anti conformation, and ability of uracil to stack between C32 and A35-phosphate, are the contributing factors to a functional U-turn.}, number={4}, journal={RNA}, author={Ashraf, SS and Ansari, G and Guenther, R and Sochacka, E and Malkiewicz, A and Agris, PF}, year={1999}, month={Apr}, pages={503–511} }