Sites of 18S rRNA contacting mRNA 3' and 5' of the P site codon in human ribosome: a cross-linking study with mRNAs carrying 4-thiouridines at specific positions.

Long synthetic mRNAs were used to study the positioning of the E site codon, the 2nd and 3rd nucleotides of the A site bound codon and a nucleotide 3' of this codon with respect to the 18S rRNA in the human 80S ribosome. The mRNAs contained a GAC triplet coding for Asp and a single 4-thiouridine residue (s(4)U) upstream or downstream of the GAC codon. In the presence of tRNA(Asp), the GAC codon of the mRNAs was targeted to the ribosomal P site thus placing s(4)U in one of the following positions -3, -2, -1, +5, +6 or +7 with respect to the first nucleotide of the P site bound codon. It was found that mRNAs that bore s(4)U in positions +5 to +7 cross-linked to the 18S rRNA nucleotides C1696, C1698 and 1820-1825, the distribution of cross-links among these targets depending on the position of s(4)U. Cross-links of mRNAs containing s(4)U in positions -3 to -1 were found in the region 1699-1704 of the 18S rRNA. In the absence of tRNA, all mRNAs cross-linked only to C1696 and C1698. Absence of the cross-linked nucleotides C1696 and C1698 in the case of mRNAs containing s(4)U in positions -3 to -1 confirmed that tRNA(Asp) actually phased the mRNA on the ribosome.

The sugar conformation governs (6-4) photoproduct formation at the dinucleotide level.

The LNA dinucleotide mimic of TpT whose two-sugar puckers are locked in the C3'-endo conformation selectively produces the corresponding cyclobutane pyrimidine dimer under 254 nm irradiation. In the natural series (TpT) the sugar puckers are in a major C2'-endo sugar conformation and the (6-4) photoproduct is also produced. Consequently, this study demonstrates that the C2'-endo conformation of the sugar pucker is necessary for (6-4) photoproduct formation.

Human replication protein A unfolds telomeric G-quadruplexes.

G-quadruplex structures inhibit telomerase activity and must be disrupted for telomere elongation during S phase. It has been suggested that the replication protein A (RPA) could unwind and maintain single-stranded DNA in a state amenable to the binding of telomeric components. We show here that under near-physiological in vitro conditions, human RPA is able to bind and unfold G-quadruplex structures formed from a 21mer human telomeric sequence. Analyses by native gel electrophoresis, cross-linking and fluorescence resonance energy transfer indicate the formation of both 1:1 and 2:1 complexes in which G-quadruplexes are unfolded. In addition, quadruplex opening by hRPA is much faster than observed with the complementary DNA, demonstrating that this protein efficiently unfolds G-quartets. A two-step mechanism accounting for the binding of hRPA to G-quadruplexes is proposed. These data point to the involvement of hRPA in regulation of telomere maintenance.

Dinucleotide TpT and its 2'-O-Me analogue possess different backbone conformations and flexibilities but similar stacked geometries.

UV irradiation at 254 nm of 2'-O,5-dimethyluridylyl(3'-5')-2'-O,5-dimethyluridine (1a) and of natural thymidylyl(3'-5')thymidine (1b) generates the same photoproducts (CPD and (6-4)PP; responsible for cell death and skin cancer). The ratios of quantum yields of photoproducts obtained from 1a (determined herein) to that from 1b are in a proportion close to the approximately threefold increase of stacked dinucleotides for 1a compared with those of 1b (from previous circular dichroism results). 1a and 1b however are endowed with different predominant sugar conformations, C3'-endo (1a) and C2'-endo (1b). The present investigation of the stacked conformation of these molecules, by unrestrained state-of-the-art molecular simulation in explicit solvent and salt, resolves this apparent paradox and suggests the following main conclusions. Stacked dinucleotides 1a and 1b adopt the main characteristic features of a single-stranded A and B form, respectively, where the relative positions of the backbone and the bases are very different. Unexpectedly, the geometry of the stacking of two thymine bases, within each dinucleotide, is very similar and is in excellent agreement with photochemical and circular dichroism results. Analyses of molecular dynamics trajectories with conformational adiabatic mapping show that 1a and 1b explore two different regions of conformational space and possess very different flexibilities. Therefore, even though their base stacking is very similar, these molecules possess different geometrical, mechanical, and dynamical properties that may account for the discrepancy observed between increased stacking and increased photoproduct formations. The computed average stacked conformations of 1a and 1b are well-defined and could serve as starting models to investigate photochemical reactions with quantum dynamics simulations.

Comparison of functional properties of mammalian DNA polymerase lambda and DNA polymerase beta in reactions of DNA synthesis related to DNA repair.

DNA polymerase lambda (Pol lambda) is a novel enzyme of the family X of DNA polymerases. Pol lambda has some properties in common with DNA polymerase beta (Pol beta). The substrate properties of Pol lambda were compared to Pol beta using DNAs mimicking short-patch (SP) and long-patch (LP) base excision repair (BER) intermediates as well as recessed template primers. In the present work, the influence of several BER proteins such as flap-endonuclease-1 (FEN1), PCNA, and apurinic/apyrimidinic endonuclease-1 (APE1) on the activity of Pol lambda was investigated. Pol lambda is unable to catalyze strand displacement synthesis using nicked DNA, although this enzyme efficiently incorporates a dNMP into a one-nucleotide gap. FEN1 and PCNA stimulate the strand displacement activity of Pol lambda. FEN1 processes nicked DNA, thus removing a barrier to Pol lambda DNA synthesis. It results in a one-nucleotide gapped DNA molecule that is a favorite substrate of Pol lambda. Photocrosslinking and functional assay show that Pol lambda is less efficient than Pol beta in binding to nicked DNA. APE1 has no influence on the strand displacement activity of Pol lambda though it stimulates strand displacement synthesis catalyzed with Pol beta. It is suggested that Pol lambda plays a role in the SP BER rather than contributes to the LP BER pathway.

Stop codons and UGG promote efficient binding of the polypeptide release factor eRF1 to the ribosomal A site.

To investigate the codon dependence of human eRF1 binding to the mRNA-ribosome complex, we examined the formation of photocrosslinks between ribosomal components and mRNAs bearing a photoactivable 4-thiouridine probe in the first position of the codon located in the A site. Addition of eRF1 to the phased mRNA-ribosome complexes triggers a codon-dependent quenching of crosslink formation. The concentration of eRF1 triggering half quenching ranges from low for the three stop codons, to intermediate for s4UGG and high for other near-cognate triplets. A theoretical analysis of the photochemical processes occurring in a two-state bimolecular model raises a number of stringent conditions, fulfilled by the system studied here, and shows that in any case sound KD values can be extracted if the ratio mT/KD<<1 (mT is total concentration of mRNA added). Considering the KD values obtained for the stop, s4UGG and sense codons (approximately 0.06 microM, 0.45 microM and 2.3 microM, respectively) and our previous finding that only the stop and s4UGG codons are able to promote formation of an eRF1-mRNA crosslink, implying a role for the NIKS loop at the tip of the N domain, we propose a two-step model for eRF1 binding to the A site: a codon-independent bimolecular step is followed by an isomerisation step observed solely with stop and s4UGG codons. Full recognition of the stop codons by the N domain of eRF1 triggers a rearrangement of bound eRF1 from an open to a closed conformation, allowing the universally conserved GGQ loop at the tip of the M domain to come into close proximity of the peptidyl transferase center of the ribosome. UGG is expected to behave as a cryptic stop codon, which, owing to imperfect eRF1-codon recognition, does not allow full reorientation of the M domain of eRF1. As far as the physical steps of eRF1 binding to the ribosome are considered, they appear to closely mimic the behaviour of the tRNA/EF-Tu/GTP complex, but clearly eRF1 is endowed with a greater conformational flexibility than tRNA.

Photochemistry of 4-Thiothymine Derivatives in the Presence of N-9-Substituted-Adenine Derivatives: Formation of N-6-Formamidopyrimidines.

UV irradiation of aqueous solutions containing either 4-thiothymin-1-ylacetic acid (1b) and adenosine (2a), 4-thiothymidine (1a) and adenin-9-ylacetic acid (2b), or 1b and 2b led to 4,5-diamino-6-formamidopyrimidine (N-6-Fapy-Ade) derivatives as observed after irradiation of a mixture of 1a and 2a (J. Am. Chem. Soc. 1996, 118, 8142-8143). These new observations demonstrate that the replacement of one or both nucleoside sugar residues by a carboxymethyl group does not affect the regioselective course of the photochemical reaction. The thermal decomposition of 3a that resulted from irradiation of 1a in the presence of 2a, was examined along with its behavior under mild alkaline conditions. Finally, irradiation of N-3-methyl-4-thiothymidine (6a) in the presence of adenosine gave the N-3-methylcytidine derivative 7.

Arrangement of 3'-terminus of tRNA on the human ribosome as revealed from cross-linking data.

This study is directed towards an important problem concerning the organization of the peptidyl transferase center (PTC) on the mammalian ribosome that cannot be studied by X-ray analysis since crystals of 80S ribosomes are still unavailable. Here, we investigated the arrangement of the 3'-end of tRNA in the 80S ribosomal A and P sites using a tRNA(Asp) analogue that bears a 4-thiouridine (s(4)U) attached to the 3'-terminal adenosine. It was shown that an additional nucleotide s(4)U77 on the 3'-end does not impede codon-dependent binding of the tRNA to the A and P sites of 80S ribosome. Mild UV-irradiation of the ribosomal complexes containing a short appropriately designed mRNA and the tRNA analogue resulted in cross-linking of the analogue exclusively to 28S rRNA. The cross-linking site was detected in the 4302-4540 fragment of the 28S rRNA which belongs to the highly conserved domain V that in prokaryotic ribosomes is involved in the formation of the PTC. Nucleotides cross-linked to the tRNA analogue were determined by means of reverse transcription. A comparison of the results obtained with a dynamic model of mutual arrangement of s(4)U77 of the A site tRNA and nucleotides of 23S rRNA built on the basis of an atomic model for the prokaryotic PTC led to the conclusion that environments of the tRNA 3'-terminus in prokaryotic and eukaryotic ribosomes share a significant extent of similarity, although pronounced differences are also detectable.

Crystal structure and photochemical behavior in solution of the 3'-N-sulfamate analogue of thymidylyl(3'-5')thymidine.

The 3'-N-sulfamate analogue of thymidylyl(3'-5')thymidine (TnsoT, 1) exhibits a preference for a C3'-endo conformation in the solution and solid states. Its photochemical behavior in solution is compared to that of its natural counterpart, thymidylyl(3'-5')thymidine (TpT, 2), to get further insight into the significance of the C3'-endo conformation on the photoproduct formation at the single-stranded dinucleotide level. Irradiation at 254 nm of 1 led to the same type of photoproducts as observed with 2. However, 1 was significantly more photoreactive than 2, and accordingly, the initial rate of photoproduct formation was enhanced in accordance with its propensity to base stack compared to 2. The corresponding quantum yields were determined and showed that the enhancement factor (1 compared to 2) is moderate for the cyclobutane pyrimidine dimer (CPD) (1.26) and much higher for the (6-4) photoproduct (1.8). These data strongly suggest that the CPD and (6-4) photoproduct arise from distinct minor stacked conformations.

The first position of a codon placed in the A site of the human 80S ribosome contacts nucleotide C1696 of the 18S rRNA as well as proteins S2, S3, S3a, S30, and S15.

Messenger RNA analogues (42-mers) containing a GAC codon (aspartic acid) in the middle of their sequence followed by a s(4)UGA stop codon were used to identify the components of the human ribosomal A site in direct contact with the photoactivatable 4-thiouridine (s(4)U) residue. We compared the behavior of the nonphased ribosome-mRNA complex, (-)tRNA(Asp), to the one of the phased complex, (+)tRNA(Asp), in the absence and in the presence of eRF1, the eukaryotic class 1 translation termination factor of human origin. The patterns of cross-links obtained for the three complexes were similar to those previously reported for rabbit ribosomes [Chavatte, L., et al. (2001) Eur. J. Biochem. 268, 2896-2904]. Cross-links involving proteins S2, S3, S3a, and S30 were poorly dependent on the presence of tRNA(Asp) and eRF1. Cross-linking to nucleotide C1696 of 18S rRNA occurred in all complexes, but its yield was at least two times higher in the phased complex with an empty A site than in the nonphased complex or when the A site was occupied by eRF1. In contrast, protein S15 cross-linked only in the phased complex in the absence of eRF1. The data obtained point to notable differences in organization of the decoding site between mammalian and prokaryotic ribosomes and to large internal mobility of the components of the tRNA (eRF1)-free A site.

Prokaryotic and eukaryotic tetrameric phenylalanyl-tRNA synthetases display conservation of the binding mode of the tRNA(Phe) CCA end.

The interaction of human phenylalanyl-tRNA synthetase, a eukaryotic prototype with an unknown three-dimensional structure, with the tRNA(Phe) acceptor end was studied by s(4)U-induced affinity cross-linking with human tRNA(Phe) derivatives site-specifically substituted at the single-stranded 3' end. Two different subunits of the enzyme bind two adjacent nucleotides of the tRNA(Phe) 3' end: nucleotide 76 is associated with the catalytic alpha subunit, while nucleotide 75 is in contact with the beta subunit. The binding mode is similar to that revealed previously in structural and affinity cross-linking studies of the prokaryotic Thermus thermophilus phenylalanyl-tRNA synthetase. Our results suggest that the distinctive features of tRNA(Phe) acceptor end binding are conserved for the eukaryotic and prokaryotic tetrameric phenylalanyl-tRNA synthetases despite their significant differences in the domain composition of the beta subunits. The data from affinity cross-linking experiments with human phenylalanyl-tRNA synthetase complexed with small ligands (ATP and/or phenylalanine or a stable synthetic analogue of phenylalanyl adenylate) reveal that the location of the tRNA(Phe) acceptor end varies with the presence and nature of other substrates. The lack of substrate activity of human tRNA(Phe) substituted with s(4)U at the 3'-terminal position suggests that base-specific interactions of the terminal adenosine are critically important for a productive interaction. The conformational rearrangement of the tRNA 3' end induced by the other substrates and dictated by base-specific contacts of the terminal nucleotide is an additional means of ensuring the phenylalanylation specificity in both prokaryotic and eukaryotic systems.

Determination of platinated purines in oligoribonucleotides by limited digestion with ribonucleases T1 and U2.

Platinum complexes which are known to react preferentially with guanine (G) and adenine (A) bases of oligonucleotides can be used as tools to analyze their tertiary structures and eventually to cross-link them. However, this requires efficient methods to allow the identification and quantification of the corresponding adducts which have so far been developed only for oligodeoxyribonucleotides. Maxam-Gilbert type digestions cannot be used for RNAs and HPLC techniques would require too large amounts of expensive material for separation and further characterization. We report a method to determine platination sites on oligoribonucleotides based on the cleavage activity of ribonucleases T1 and U2. To test the method, these enzymes were first used under conditions of limited digestion on 5-mer oligoribonucleotides platinated at a single defined purine. The phosphodiester bond on the 3' side of platinated G or A appeared fully resistant to cleavage by ribonuclease T1 or U2, respectively. An inhibitory effect was also observed due to neighboring platinated purines, which decreases with their distance (-2, -1, +1, +2) from the cleavage site and with the enzyme concentration. The method allowed the identification and quantification of the platination sites of a 17-mer oligoribonucleotide, based on the analysis of the mixture of monoplatinated adducts.

The invariant uridine of stop codons contacts the conserved NIKSR loop of human eRF1 in the ribosome.

To unravel the region of human eukaryotic release factor 1 (eRF1) that is close to stop codons within the ribosome, we used mRNAs containing a single photoactivatable 4-thiouridine (s(4)U) residue in the first position of stop or control sense codons. Accurate phasing of these mRNAs onto the ribosome was achieved by the addition of tRNA(Asp). Under these conditions, eRF1 was shown to crosslink exclusively to mRNAs containing a stop or s(4)UGG codon. A procedure that yielded (32)P-labeled eRF1 deprived of the mRNA chain was developed; analysis of the labeled peptides generated after specific cleavage of both wild-type and mutant eRF1s maps the crosslink in the tripeptide KSR (positions 63-65 of human eRF1) and points to K63 located in the conserved NIKS loop as the main crosslinking site. These data directly show the interaction of the N-terminal (N) domain of eRF1 with stop codons within the 40S ribosomal subunit and provide strong support for the positioning of the eRF1 middle (M) domain on the 60S subunit. Thus, the N and M domains mimic the tRNA anticodon and acceptor arms, respectively.

Stop codon selection in eukaryotic translation termination: comparison of the discriminating potential between human and ciliate eRF1s.

During eukaryotic translation termination, eRF1 responds to three stop codons. However, in ciliates with variant genetic codes, only one or two codons function as a stop signal. To localize the region of ciliate eRF1 implicated in stop codon discrimination, we have constructed ciliate-human hybrid eRF1s by swapping regions of human eRF1 for the equivalent region of ciliate Euplotes eRF1. We have examined the formation of a cross-link between recombinant eRF1s and mRNA analogs containing the photoactivable 4-thiouridine (s(4)U) at the first position of stop and control sense codons. With human eRF1, this cross-link can be detected only when either stop or UGG codons are located in the ribosomal A site. Here we show that the cross-link of the Euplotes-human hybrid eRF1 is restricted to mRNAs containing UAG and UAA codons, and that the entire N-terminal domain of Euplotes eRF1 is involved in discriminating against UGA and UGG. On the basis of these results, we discuss the steps of the selection process that determine the accuracy of stop codon recognition in eukaryotes.

Photoaffinity labeling of proteins in bovine testis nuclear extract.

A binary system of photoaffinity reagents for selective affinity labeling of DNA polymerases has been developed. The photoreactive probe was formed in nuclear extract, using an end-labeled oligonucleotide containing a synthetic abasic site. This site was incised by apurinic/apyrimidinic endonuclease and then dNMPs carrying a photoreactive adduct were added to the 3(') hydroxyl using base-substituted arylazido derivatives of dUTP or dCTP. This results in the synthesis of photoreactive base excision repair (BER) intermediates. The photoreactive group was then activated, either directly (UV light exposure 320nm) or in the presence of the sensitizer of dTTP analog containing a pyrene group (Pyr-dUTP) under UV light 365nm. DNA polymerase beta was the main target crosslinked by photoreactive BER intermediates in this nuclear extract. In contrast, several proteins were labeled under the conditions of direct activation of arylazido group.

AP endonuclease 1 has no biologically significant 3(')-->5(')-exonuclease activity.

The 3(')-->5(')-exonucleolytic activity of human apurinic/apyrimidinic endonuclease 1 (APE1) on mispaired DNA at the 3(')-termini of recessed, nicked or gapped DNA molecules was analyzed and compared with the primary endonucleolytic activity. We found that under reaction conditions optimal for AP endonuclease activity the 3(')-->5(')-exonuclease activity of APE1 manifests only at enzyme concentration elevated by 6-7 orders of magnitude. This activity does not show a preference to mismatched compared to matched DNA structures as well as to nicked or gapped DNA substrates in comparison to recessed ones. Therefore, the 3(')-->5(')-exonuclease activity associated with APE1 can hardly be considered as key mechanism that improves fidelity of DNA repair.