anticodon and 2-thiouridine

Topics: Anticodon; Escherichia coli; RNA, Transfer; Saccharomyces cerevisiae; Thermus thermophilus; Thiouridine

Natural RNAs utilize extensive chemical modifications to diversify their structures and functions. 2-Thiouridine geranylation is a special hydrophobic tRNA modification that has been discovered very recently in several bacteria, such as Escherichia coli, Enterobacter aerogenes, Pseudomonas aeruginosa and Salmonella Typhimurium The geranylated residues are located in the first anticodon position of tRNAs specific for lysine, glutamine and glutamic acid. This big hydrophobic terpene functional group affects the codon recognition patterns and reduces frameshifting errors during translation. We aimed to systematically study the structure, function and biosynthesis mechanism of this geranylation pathway, as well as answer the question of why nature uses such a hydrophobic modification in hydrophilic RNA systems. Recently, we have synthesized the deoxy-analog of S-geranyluridine and showed the geranylated T-G pair is much stronger than the geranylated T-A pair and other mismatched pairs in the B-form DNA duplex context, which is consistent with the observation that the geranylated tRNA(Glu) UUC recognizes GAG more efficiently than GAA. In this manuscript we report the synthesis and base pairing specificity studies of geranylated RNA oligos. We also report extensive molecular simulation studies to explore the structural features of the geranyl group in the context of A-form RNA and its effect on codon-anticodon interaction during ribosome binding.

Topics: Anticodon; Codon; DNA, B-Form; Escherichia coli; Hydrophobic and Hydrophilic Interactions; Nucleic Acid Conformation; Protein Biosynthesis; Ribosomes; RNA; RNA, Transfer; Thiouridine

The 2-thiouridine (s(2)U) at the wobble position of certain bacterial and eukaryotic tRNAs enhances aminoacylation kinetics, assists proper codon-anticodon base pairing at the ribosome A-site, and prevents frameshifting during translation. By mass spectrometry of affinity-purified native Escherichia coli tRNA1(Gln)UUG, we show that the complete modification at the wobble position 34 is 5-carboxyaminomethyl-2-thiouridine (cmnm(5)s(2)U). The crystal structure of E. coli glutaminyl-tRNA synthetase (GlnRS) bound to native tRNA1(Gln) and ATP demonstrates that cmnm(5)s(2)U34 improves the order of a previously unobserved 11-amino-acid surface loop in the distal β-barrel domain of the enzyme and imparts other local rearrangements of nearby amino acids that create a binding pocket for the 2-thio moiety. Together with previously solved structures, these observations explain the degenerate recognition of C34 and modified U34 by GlnRS. Comparative pre-steady-state aminoacylation kinetics of native tRNA1(Gln), synthetic tRNA1(Gln) containing s(2)U34 as sole modification, and unmodified wild-type and mutant tRNA1(Gln) and tRNA2(Gln) transcripts demonstrates that the exocyclic sulfur moiety improves tRNA binding affinity to GlnRS 10-fold compared with the unmodified transcript and that an additional fourfold improvement arises from the presence of the cmnm(5) moiety. Measurements of Gln-tRNA(Gln) interactions at the ribosome A-site show that the s(2)U modification enhances binding affinity to the glutamine codons CAA and CAG and increases the rate of GTP hydrolysis by E. coli EF-Tu by fivefold.

Topics: Adenosine Triphosphate; Amino Acyl-tRNA Synthetases; Anticodon; Base Sequence; Crystallography, X-Ray; Escherichia coli; Molecular Docking Simulation; Nucleic Acid Conformation; Nucleosides; Protein Binding; Protein Biosynthesis; Protein Conformation; Ribosomes; RNA, Transfer; RNA, Transfer, Gln; Thiouridine

The 2-thiomodified nucleosides, located at first position of tRNAs anticodon, may constitute a primary target for oxidative attack under conditions of oxidative stress. Desulfuration of 2-thiouridine (S2U) was investigated in the (1)H NMR scale in the presence of 100mM H2O2 and phosphate buffer in the physiological pH range, from pH 6.6 to 7.6. The obtained data demonstrate an intriguing result that within one unit of the pH range uridine is the major product of the S2U desulfuration in the pH 7.6, while the 4-pyrimidinone nucleoside (H2U) is dominant in pH 6.6. The possible desulfuration pathway and the biological importance of the transformation of S2U either to U or H2U are discussed in the context of the tRNA oxidative damage.

Topics: Anticodon; Hydrogen Peroxide; Hydrogen-Ion Concentration; Magnetic Resonance Spectroscopy; RNA, Transfer; Sulfur; Thiouridine; Uridine

Replication of human immunodeficiency virus (HIV) requires base pairing of the reverse transcriptase primer, human tRNA(Lys3), to the viral RNA. Although the major complementary base pairing occurs between the HIV primer binding sequence (PBS) and the tRNA's 3'-terminus, an important discriminatory, secondary contact occurs between the viral A-rich Loop I, 5'-adjacent to the PBS, and the modified, U-rich anticodon domain of tRNA(Lys3). The importance of individual and combined anticodon modifications to the tRNA/HIV-1 Loop I RNA's interaction was determined. The thermal stabilities of variously modified tRNA anticodon region sequences bound to the Loop I of viral sub(sero)types G and B were analyzed and the structure of one duplex containing two modified nucleosides was determined using NMR spectroscopy and restrained molecular dynamics. The modifications 2-thiouridine, s(2)U(34), and pseudouridine, Psi(39), appreciably stabilized the interaction of the anticodon region with the viral subtype G and B RNAs. The structure of the duplex results in two coaxially stacked A-form RNA stems separated by two mismatched base pairs, U(162)*Psi(39) and G(163)*A(38), that maintained a reasonable A-form helix diameter. The tRNA's s(2)U(34) stabilized the interaction between the A-rich HIV Loop I sequence and the U-rich anticodon, whereas the tRNA's Psi(39) stabilized the adjacent mismatched pairs.

Topics: Anticodon; Base Pair Mismatch; Base Sequence; Carbohydrates; Genome, Viral; HIV-1; Humans; Models, Molecular; Molecular Sequence Data; Nuclear Magnetic Resonance, Biomolecular; Protons; Pseudouridine; RNA, Transfer, Lys; RNA, Viral; Thermodynamics; Thiouridine

Previous nuclear magnetic resonance (NMR) studies of unmodified and pseudouridine39-modified tRNA(Lys) anticodon stem loops (ASLs) show that significant structural rearrangements must occur to attain a canonical anticodon loop conformation. The Escherichia coli tRNA(Lys) modifications mnm(5)s(2)U34 and t(6)A37 have indeed been shown to remodel the anticodon loop, although significant dynamic flexibility remains within the weakly stacked U35 and U36 anticodon residues. The present study examines the individual effects of mnm(5)s(2)U34, s(2)U34, t(6)A37, and Mg(2+) on tRNA(Lys) ASLs to decipher how the E. coli modifications accomplish the noncanonical to canonical structural transition. We also investigated the effects of the corresponding human tRNA(Lys,3) versions of the E. coli modifications, using NMR to analyze tRNA ASLs containing the nucleosides mcm(5)U34, mcm(5)s(2)U34, and ms(2)t(6)A37. The human wobble modification has a less dramatic loop remodeling effect, presumably because of the absence of a positive charge on the mcm(5) side chain. Nonspecific magnesium effects appear to play an important role in promoting anticodon stacking. Paradoxically, both t(6)A37 and ms(2)t(6)A37 actually decrease anticodon stacking compared to A37 by promoting U36 bulging. Rather than stack with U36, the t(6)A37 nucleotide in the free tRNAs is prepositioned to form a cross-strand stack with the first codon nucleotide as seen in the recent crystal structures of tRNA(Lys) ASLs bound to the 30S ribosomal subunit. Wobble modifications, t(6)A37, and magnesium each make unique contributions toward promoting canonical tRNA structure in the fundamentally dynamic tRNA(Lys)(UUU) anticodon.

Topics: Adenosine; Anticodon; Base Pairing; Binding Sites; Codon; Escherichia coli; Genetic Engineering; Humans; Magnesium; Models, Molecular; Nuclear Magnetic Resonance, Biomolecular; Nucleic Acid Conformation; Pseudouridine; Ribosomes; RNA, Transfer, Lys; Thermodynamics; Thionucleosides; Thiouridine

Thionucleosides are uniquely present in tRNA. In many organisms, tRNA specific for Lys, Glu, and Gln contain hypermodified 2-thiouridine (s(2)U) derivatives at wobble position 34. The s(2) group of s(2)U34 stabilizes anticodon structure, confers ribosome binding ability to tRNA and improves reading frame maintenance. Earlier studies have mapped and later identified the mnmA gene (formerly asuE or trmU) as required for the s(2)U modification in Escherichia coli. We have prepared a nonpolar deletion of the mnmA gene and show that it is not required for viability in E. coli. We also cloned mnmA from E. coli, and overproduced and purified the protein. Using a gel mobility shift assay, we show that MnmA binds to unmodified E. coli tRNA(Lys) with affinity in the low micromolar range. MnmA does not bind observably to the nonsubstrate E. coli tRNA(Phe). Corroborating this, tRNA(Glu) protected MnmA from tryptic digestion. ATP also protected MnmA from trypsinolysis, suggesting the presence of an ATP binding site that is consistent with analysis of the amino acid sequence. We have reconstituted the in vitro biosynthesis of s(2)U using unmodified E. coli tRNA(Glu) as a substrate. The activity requires MnmA, Mg-ATP, l-cysteine, and the cysteine desulfurase IscS. HPLC analysis of thiolated tRNA digests using [(35)S]cysteine confirms that the product of the in vitro reaction is s(2)U. As in the case of 4-thiouridine synthesis, purified IscS-persulfide is able to provide sulfur for in vitro s(2)U synthesis in the absence of cysteine. Small RNAs that represent the anticodon stem loops for tRNA(Glu) and tRNA(Lys) are substrates of comparable activity to the full length tRNAs, indicating that the major determinants for substrate recognition are contained within this region.

Topics: Aminopeptidases; Anticodon; Binding Sites; Carbon-Sulfur Lyases; Escherichia coli; Escherichia coli Proteins; Kinetics; Plasmids; RNA-Binding Proteins; RNA, Transfer, Amino Acyl; Substrate Specificity; Sulfides; Sulfur; Thiouridine

Escherichia coli tRNALysSUU, as well as human tRNALys3SUU, has 2-thiouridine derivatives at wobble position 34 (s2U*34). Unlike the native tRNALysSUU, the full-length, unmodified transcript of human tRNALys3UUU and the unmodified tRNALys3UUU anticodon stem/loop (ASLLys3UUU) did not bind AAA- or AAG-programmed ribosomes. In contrast, the completely unmodified yeast tRNAPhe anticodon stem/loop (ASLPheGAA) had an affinity (Kd = 136+/-49 nM) similar to that of native yeast tRNAPheGmAA (Kd = 103+/-19 nM). We have found that the single, site-specific substitution of s2U34 for U34 to produce the modified ASLLysSUU was sufficient to restore ribosomal binding. The modified ASLLysSUU bound the ribosome with an affinity (Kd = 176+/-62 nM) comparable to that of native tRNALysSUU (Kd = 70+/-7 nM). Furthermore, in binding to the ribosome, the modified ASLLys3SUU produced the same 16S P-site tRNA footprint as did native E. coli tRNALysSUU, yeast tRNAPheGmAA, and the unmodified ASLPheGAA. The unmodified ASLLys3UUU had no footprint at all. Investigations of thermal stability and structure monitored by UV spectroscopy and NMR showed that the dynamic conformation of the loop of modified ASLLys3SUU was different from that of the unmodified ASLLysUUU, whereas the stems were isomorphous. Based on these and other data, we conclude that s2U34 in tRNALysSUU and in other s2U34-containing tRNAs is critical for generating an anticodon conformation that leads to effective codon interaction in all organisms. This is the first example of a single atom substitution (U34-->s2U34) that confers the property of ribosomal binding on an otherwise inactive tRNA.

Topics: Aldehydes; Anticodon; Butanones; Escherichia coli; Humans; Magnetic Resonance Spectroscopy; Nucleic Acid Conformation; Nucleic Acid Denaturation; Nucleic Acid Hybridization; Ribosomes; RNA, Fungal; RNA, Transfer, Lys; Spectrum Analysis; Temperature; Thiouridine

In order to understand the effect of 2-thiouridine (s2U) substitution on RNA structure and the potential for stabilization of tRNA codon-anticodon interactions through s2U-34 modification, a pentamer RNA sequence, Gs2UUUC, was synthesized and characterized by NMR spectroscopy. The single strand contains the UUU anticodon sequence of tRNALys with flanking GCs to increase duplex stability. Regiochemical effects of uridine thiolation were determined by comparing the structure and stability of the 2-thiouridine containing oligonucleotide with an identical sequence containing 4-thiouridine (s4U) and also the normal uridine nucleoside. Circular dichroism spectrum indicated an A-form helical conformation for Gs2UUUC which was further confirmed by 2D ROESY NMR experiments. The duplex stability of the three pentamers complexed with a 2'-O-methyl-ribonucleotide complementary strand, GmAmAmAmCm, was determined by UV thermal melting studies and by 1H NMR spectroscopy. The duplex containing s2U has a T m of 30.7 degrees C compared to 19. 0 degrees C for the unmodified control and 14.5 degrees C for the s4U containing duplex. The results from UV experiments were corroborated by imino proton NMR studies that show proton exchange rates, chemical shift differences, and NH proton linewidths indicative of the stability order s2U >U >s4U. The magnitude of the effect of s2U in our model system is comparable to the 20 degrees C stabilization observed by Grosjean and co-workers for 2-thiolation in a codon-anticodon model system composed of two tRNAs with complementary anticodon sequences [Houssier, C., Degee, P., Nicoghosian, K. and Grosjean, H. (1988) J. Biomol. Struct. Dyn., 5, 1259-1266].

Topics: Anticodon; Codon; Indicators and Reagents; Kinetics; Magnetic Resonance Spectroscopy; Oligoribonucleotides; RNA; RNA, Transfer, Lys; Thermodynamics; Thiouridine