thiouridine and 6-thioguanosine

Eukaryotic initiation factor (eIF) 1 maintains the fidelity of initiation codon selection and enables mammalian 43S preinitiation complexes to discriminate against AUG codons with a context that deviates from the optimum sequence GCC(A/G)CCAUGG, in which the purines at (-)3 and (+)4 positions are most important. We hypothesize that eIF1 acts by antagonizing conformational changes that occur in ribosomal complexes upon codon-anticodon base-pairing during 48S initiation complex formation, and that the role of (-)3 and (+)4 context nucleotides is to stabilize these changes by interacting with components of this complex. Here we report that U and G at (+)4 both UV-cross-linked to ribosomal protein (rp) S15 in 48S complexes. However, whereas U cross-linked strongly to C(1696) and less well to AA(1818-1819) in helix 44 of 18S rRNA, G cross-linked exclusively to AA(1818-1819). U at (-)3 cross-linked to rpS5 and eIF2alpha, whereas G cross-linked only to eIF2alpha. Results of UV cross-linking experiments and of assays of 48S complex formation done using alpha-subunit-deficient eIF2 indicate that eIF2alpha's interaction with the (-)3 purine is responsible for recognition of the (-)3 context position by 43S complexes and suggest that the (+)4 purine/AA(1818-1819) interaction might be responsible for recognizing the (+)4 position.

Topics: Animals; Cattle; Codon, Initiator; Eukaryotic Initiation Factor-1; Eukaryotic Initiation Factors; Guanosine; Models, Molecular; Molecular Structure; Peptide Chain Initiation, Translational; Ribosomes; RNA, Messenger; Thionucleosides; Thiouridine

Despite the biological importance of self-splicing group II introns, little is known about their structural organization. Synthetic incorporation of site-specific photo-cross-linkers within catalytic domains resulted in functional distance constraints that, when combined with known tertiary interactions, provide a three-dimensional view of the active intron architecture. All functionalities important for both steps of splicing are proximal before the first step, suggestive of a single active-site region for group II intron catalysis.

Topics: Binding Sites; Catalysis; Cross-Linking Reagents; Guanosine; Introns; Models, Molecular; RNA Splicing; Thionucleosides; Thiouridine

4-Thiouridine, 6-thioguanosine, and 6-thioinosine 3',5'-bisphosphates (9, 20, and 28) were synthesized in good yields by considerably improved methods. In the former two compounds, uridine and 2-N-phenylacetylguanosine were converted via transient O-trimethylsilylation to the corresponding 4- and 6-O-benzenesulfonyl intermediates (2 and 13), which, in turn, were allowed to react with 2-cyanoethanethiol in the presence of N-methylpyrrolidine to give 4-thiouridine (3) and 2-N-phenylacetyl-6-thioguanosine derivatives (14), respectively. In situ dimethoxytritylation of these thionucleoside derivatives gave the 5'-masked products 4 and 15 in high overall yields from 1 and 11. 6-S-(2-Cyanoethyl)-5'-O-(4,4'-dimethoxytrityl)-6-thioinosine (23) was synthesized via substitution of the 5'-O-tritylated 6-chloropurine riboside derivative 22 with 2-cyanoethanethiol. These S-(2-cyanoethyl)thionucleosides were converted to the 2'-O-(tert-butyldimethylsilyl)ribonucleoside 3'-phosphoramidite derivatives 7, 18, and 26 or 3',5'-bisphosphate derivatives 8, 19, and 27. Treatment of 8, 19, and 27 with DBU gave thionucleoside 3',5'-bisphosphate derivatives 9, 20, and 28, which were found to be substrates of T4 RNA ligase. These thionucleoside 3',5'-bisphosphates were examined as donors for ligation with m3(2,2,7) G5'pppAmUmA, i.e., the 5'-terminal tetranucleotide fragment of U1 snRNA, The 4-thiouridine 3',5'-bisphosphate derivative 9 was found to serve as the most active substrate of T4 RNA ligase with a reaction efficiency of 96%.

Topics: Guanosine; Magnetic Resonance Spectroscopy; Phosphates; Photochemistry; RNA, Small Nuclear; Thioinosine; Thionucleosides; Thiouridine

Newly synthesized mRNA from hamster cells was labeled in vivo with the thionucleoside analogs 4-thiouridine (4-TU) and 6-thioguanosine (6-TG). The thio-substituted RNA was selectively recovered by Affi-Gel 501 phenylmercury affinity chromatography. Following a 1-h labeling period, enrichment for newly transcribed RNA after a single round of chromatography ranged between 10- and 15-fold when compared with total RNA. Exposure of CHO UrdA- cells, a uridine auxotrophic line, to 50 microM 4-TU allowed for optimal recovery of newly transcribed RNA. Increasing the concentration of 4-TU to 100 microM or labeling with 6-TG at concentrations of 3 microM or greater resulted in similar recoveries from uridine-prototrophic hamster cell lines. For shorter term labeling, exposure of prototrophic cells to 500 microM 4-TU or 100 microM 6-TG for 15 min allowed newly synthesized RNA to be selectively recovered. As a specific test case, enrichment for histone H3.2 mRNA was analyzed after hamster cells were labeled with 4-TU under conditions in which the gene was highly transcriptionally active. Northern blot analysis and the specific activity of thio-substituted RNA revealed a 15-fold enrichment when compared to total RNA. In vivo labeling of cellular RNA with 4-TU or 6-TG should provide a useful method for studying inducible gene expression and for isolating and cloning specific mRNAs from mammalian cells.

Topics: Affinity Labels; Animals; Chromatography, Affinity; Cricetinae; Cricetulus; Guanosine; RNA, Messenger; Thionucleosides; Thiouridine

Isolation of newly synthesised RNA can be achieved by treatment of cells in culture with 6-thioguanosine or 4-thiouridine followed by separation of thiol-containing RNA by affinity chromatography on mercurated cellulose columns. After short periods of treatment with 6-thioguanosine the proportion of RNA retained on mercurated cellulose is the same for both poly(A)-containing and poly(A)-free RNA, indicating similar incorporation of the drug into mRNA and rRNA. However, after longer periods of exposure, the cytotoxic effect of 6-thioguanosine results in diminished incorporation of radioactive uridine into RNA and of radioactive leucine into protein; this suggests that synthesis of both RNA and protein are impaired. On the other hand, even after long exposure to high concentrations of 4-thiouridine, the syntheses of RNA and protein are not significantly affected. Proteins synthesised after treatment of cells with 6-thioguanosine are less stable than proteins synthesised after treatment of cells with 4-thiouridine.

Topics: Animals; Cells, Cultured; Chromatography, Affinity; Cricetinae; Guanosine; Leucine; Poly A; Proteins; RNA; RNA, Messenger; RNA, Ribosomal; Thionucleosides; Thiouridine; Uridine