Crosslinking of mRNA analog, pUUAGUAUUUAUU derivative with a photoactivated group at the guanosine residue, with human 80S ribosomes

Crosslinking of mRNA analog, dodecaribonucleotide pUUAGUAUUUAUU derivative carrying a perfluoroarylazido group at the guanine N7, was studied in model complexes with 80S ribosomes involving tRNA and in binary complex (i.e., in the absence of tRNA). It was shown that, irrespectively of complex formation conditions (13 mM Mg2+, or 4 mM Mg2+ in the presence of polyamines), the mRNA analog in binary complex with 80S ribosomes was crosslinked with sequence 1840-1849 of 18S rRNA, but in the complexes formed with participation of Phe-TPHKPhe (where the G residue carrying the arylazido group occupied position-3 to the first nucleotide of the UUU codon at the P site) the analog was crosslinked with nucleotide 1207. The presence and the nature of tRNA at the E site had no effect on the environment of position-3 of the mRNA analog. Efficient crosslinking of the mRNA analog with tRNA was observed in all studied types of complex. Modified codon GUA, when located at the E site, underwent crosslinking with both cognate valine tRNA and noncognate aspartate tRNA for which the extent of binding at the E site of 80S ribosomes was almost the same and depended little on Mg2+ concentration and the presence of polyamines.     

Positioning of the mRNA stop signal with respect to polypeptide chain release factors and ribosomal proteins in 80S ribosomes

To study positioning of the mRNA stop signal with respect to polypeptide chain release factors (RFs) and ribosomal components within human 80S ribosomes, photoreactive mRNA analogs were applied. Derivatives of the UUCUAAA heptaribonucleotide containing the UUC codon for Phe and the stop signal UAAA, which bore a perfluoroaryl azido group at either the fourth nucleotide or the 3'-terminal phosphate, were synthesized. The UUC codon was directed to the ribosomal P site by the cognate tRNA(Phe), targeting the UAA stop codon to the A site. Mild UV irradiation of the ternary complexes consisting of the 80S ribosome, the mRNA analog and tRNA resulted in tRNA-dependent crosslinking of the mRNA analogs to the 40S ribosomal proteins and the 18S rRNA. mRNA analogs with the photoreactive group at the fourth uridine (the first base of the stop codon) crosslinked mainly to protein S15 (and much less to S2). For the 3'-modified mRNA analog, the major crosslinking target was protein S2, while protein S15 was much less crosslinked. Crosslinking of eukaryotic (e) RF1 was entirely dependent on the presence of a stop signal in the mRNA analog. eRF3 in the presence of eRF1 did not crosslink, but decreased the yield of eRF1 crosslinking. We conclude that (i) proteins S15 and S2 of the 40S ribosomal subunit are located near the A site-bound codon; (ii) eRF1 can induce spatial rearrangement of the 80S ribosome leading to movement of protein L4 of the 60S ribosomal subunit closer to the codon located at the A site; (iii) within the 80S ribosome, eRF3 in the presence of eRF1 does not contact the stop codon at the A site and is probably located mostly (if not entirely) on the 60S subunit.     

Crosslinking of mRNA Analog,pUUAGUAUUUAUU Derivative with Photoactivatable Group at the Guanosine Residue,with Human 80S Ribosomes

Crosslinking of mRNA analog, dodecaribonucleotide pUUAGUAUUUAUU derivative carrying a perfluoroarylazido group at the guanine N7, was studied in model complexes with 80S ribosomes involving tRNA and in binary complex (i.e., in the absence of tRNA). It was shown that, irrespectively of complex formation conditions (13 mM Mg²⁺, or 4 mM Mg²⁺ in the presence of polyamines), the mRNA analog in binary complex with 80S ribosomes was crosslinked with sequence 1840–1849 of 18S rRNA, but in the complexes formed with participation of Phe-tRNA^Phe (where the G residue carrying the arylazido group occupied position –3 to the first nucleotide of the UUU codon at the P site) the analog was crosslinked with nucleotide 1207. The presence and the nature of tRNA at the E site had no effect on the environment of position –3 of the mRNA analog. Efficient crosslinking of the mRNA analog with tRNA was observed in all studied types of complex. Modified codon GUA, when located at the E site, underwent crosslinking with both cognate valine tRNA and noncognate aspartate tRNA for which the extent of binding at the E site of 80S ribosomes was almost the same and depended little on Mg²⁺ concentration and the presence of polyamines.     

Investigation of the ribosomal peptidyl transferase center using a photoaffinity label

The synthesis of a peptidyl-tRNA photoaffinity analog, 2-nitro-4-azidophenoxy-4′-phenylacetyl-phenylalanyl-tRNA^Phe is described. Covalent attachment of this analog to Escherichia coli 70 S ribosomes requires poly(U)-stimulated binding prior to photolysis. Peptidyl site binding is indicated by the ability of puromycin to release the peptidyl moiety from non-photolyzed samples. Covalently attached 2-nitro-4-azidophenoxy-4-phenylacetyl-Phe-tRNA^Phe can subsequently participate in peptidyl transfer with [³H]Phe-tRNA^Phe bound at the aminoacyl site. This means that the covalent reaction does not produce sufficient distortion of the peptidyl site and its bound tRNA to inactivate the peptidyl transference. If peptidyl transfer with [³H]Phe-tRNA^Phe is allowed to proceed before photolysis, covalent reaction can still occur. In all cases, the main reaction products are two 50 S ribosomal proteins, L11 and L18. The results strongly indicate that these two proteins either form part of the peptidyl transferase center or are located adjacent to it. Presumably, α-halocarbonyl affinity reagents used previously failed to identify these two proteins because they lack easily accessible, reactive nucleophilic groups.     

Translation initiation by factor-independent binding of eukaryotic ribosomes to internal ribosomal entry sites

Two exceptional mechanisms of eukaryotic translation initiation have recently been identified that differ fundamentally from the canonical factor-mediated, end-dependent mechanism of ribosomal attachment to mRNA. Instead, ribosomal 40S subunits bind in a factor-independent manner to the internal ribosomal entry site (IRES) in an mRNA. These two mechanisms are exemplified by initiation on the unrelated approximately 300 nt.-long Hepatitis C virus (HCV) IRES and the approximately 200 nt.-long cricket paralysis virus (CrPV) intergenic region (IGR) IRES, respectively. Ribosomal binding involves interaction with multiple non-contiguous sites on these IRESs, and therefore also differs from the factor-independent attachment of prokaryotic ribosomes to mRNA, which involves base-pairing to the linear Shine-Dalgarno sequence. The HCV IRES binds to the solvent side of the 40S subunit, docks a domain of the IRES into the ribosomal exit (E) site and places the initiation codon in the ribosomal peptidyl (P) site. Subsequent binding of eIF3 and the eIF2-GTP/initiator tRNA complex to form a 48S complex is followed by subunit joining to form an 80S ribosome. The CrPV IRES binds to ribosomes in a very different manner, by occupying the ribosomal E and P sites in the intersubunit cavity, thereby excluding initiator tRNA. Ribosomes enter the elongation stage of translation directly, without any involvement of initiator tRNA or initiation factors, following recruitment of aminoacyl-tRNA to the ribosomal aminoacyl (A) site and translocation of it to the P site.     

Destabilization of the P site codon-anticodon helix results from movement of tRNA into the P/E hybrid state within the ribosome

Retention of the reading frame in ribosomal complexes after single-round translocation depends on the acylation state of the tRNA. When tRNA lacking a peptidyl group is translocated to the P site, the mRNA slips to allow re-pairing of the tRNA with a nearby out-of-frame codon. Here, we show that this ribosomal activity results from movement of tRNA into the P/E hybrid state. Slippage of mRNA is suppressed by 3' truncation of the translocated tRNA, increased MgCl2 concentration, and mutation C2394A of the 50S E site, and each of these conditions inhibits P/E-state formation. Mutation G2252U of the 50S P site stimulates mRNA slippage, suggesting that decreased affinity of tRNA for the P/P state also destabilizes mRNA in the complex. The effects of G2252U are suppressed by C2394A, further implicating the P/E state in mRNA destabilization. This work uncovers a functional attribute of the P/E state crucial for understanding translation.     

The mechanism of covalent reaction of bromoacetyl-phenylalanyl-transfer RNA with the peptidyl-transfer RNA binding site of the Escherichia coli ribosome

Results are presented to prove that bromoacetyl-phenylalanyl-transfer RNA reacts covalently with 50 S ribosomal proteins L2 and L27 while it is bound correctly to the peptidyl site on the 70 S ribosome. Attachment of the BrAcPhe moiety to tRNA causes a 100-fold enhancement of its reactivity with ribosomes. This reactivity closely parallels binding of tRNA whether measured by poly(U) stimulation or competition with deacylated tRNA. BrAcPhe-tRNA can bind correctly to the P site as judged by puromycin releasibility and lack of tetracycline inhibition. Little significant reaction of BrAcPhe-tRNA with L2 and L27 occurs during procedures used to purify and analyze ribosomal proteins. If ribosomes are first incubated with BrAcPhe-tRNA and subsequently treated with puromycin before analysis, little inhibition of the covalent reaction with L2 and L27 is observed. In contrast, a few minor reaction products are markedly suppressed. Covalently attached BrAcPhe-tRNA is still capable of accepting an amino acid from Phe-tRNA or puromycin. The products from this reaction are found attached to proteins L2 and L27 and to a lesser extent to L15 and L16. This shows that true affinity labeling of proteins in the peptidyl binding site has been accomplished.Some covalent reaction of BrAcPhe-tRNA with the 30 S protein S18 is also observed. This reaction is not poly(U)-dependent, however, and S18-reacted BrAcPhe-tRNA is not capable of peptide bond formation with Phe-tRNA. It seems likely that reaction with S18 results from a non-functional interaction of the affinity label with the ribosome.     

Base-pairing between 23S rRNA and tRNA in the ribosomal A site

The aminoacyl (A site) tRNA analog 4-thio-dT-p-C-p-puromycin (s4TCPm) photochemically cross-links with high efficiency and specificity to G2553 of 23S rRNA and is peptidyl transferase reactive in its cross-linked state, establishing proximity between the highly conserved 2555 loop in domain V of 23S rRNA and the universally conserved CCA end of tRNA. To test for base-pairing interactions between 23S rRNA and aminoacyl tRNA, site-directed mutations were made at the universally conserved nucleotides U2552 and G2553 of 23S rRNA in both E. coli and B. stearothermophilus ribosomal RNA and incorporated into ribosomes. Mutations at G2553 resulted in dominant growth defects in E. coli and in decreased levels of peptidyl transferase activity in vitro. Genetic analysis in vitro of U2552 and G2553 mutant ribosomes and CCA end mutant tRNA substrates identified a base-pairing interaction between C75 of aminoacyl tRNA and G2553 of 23S rRNA.     

Evidence for RNA in the peptidyl transferase center of Escherichia coli ribosomes as indicated by fluorescence.

A coumarin derivative was covalently attached to either the amino acid or the 5' end of phenylalanine-specific transfer RNA (tRNA(phe)). Its fluorescence was quenched by methyl viologen when the tRNA was free in solution or bound to Escherichia coli ribosomes. Methyl viologen as a cation in solution has a strong affinity for the ionized phosphates of a nucleic acid and so can be used to qualitatively measure the presence of RNA in the immediate vicinity of the tRNA-linked coumarins upon binding to ribosomes. Fluorescence lifetime measurements indicate that the increase in fluorescence quenching observed when the tRNAs are bound into the peptidyl site of ribosomes is due to static quenching by methyl viologen bound to RNA in the immediate vicinity of the fluorophore. The data lead to the conclusion that the ribosome peptidyl transferase center is rich in ribosomal RNA. Movement of the fluorophore at the N-terminus of the nascent peptide as it is extended or movement of the tRNA acceptor stem away from the peptidyl transferase center during peptide bond formation appears to result in movement of the probe into a region containing less rRNA.     

Analysis of recognition of transfer-messenger RNA by the ribosomal decoding center

Bacterial ribosomes stalled on defective mRNAs are rescued by tmRNA that functions as both tRNA and mRNA. The first ribosomal elongation cycle on tmRNA where tmRNA functions as tRNA is highly unusual: occupation of the ribosomal A site by tmRNA occurs without codon:anticodon pairing. Our analysis shows that in this case the role of a codon:anticodon duplex should be accomplished by a single unpaired triplet. In order that tmRNA could participate in the ribosomal elongation cycle, a triplet preceding the mRNA portion of tmRNA (the -1triplet) should be in the A-form and this form should be recognized by the ribosomal decoding center. A rule is derived that determines what triplets cannot be used as the -1triplet. The rule was tested with the -1triplets of all known 414 tmRNA species. All 23 observed -1triplets follow the formulated rule. The rule is also supported by the available data on base substitutions within the -1triplet.     

Positioning of mRNA 3' of the a site bound codon on the human 80S ribosome

Short mRNA analogues carrying a UUU triplet at the 5'-termini and a perfluorophenylazide group at either the N7 atom of the guanosine or the C5 atom of the uridine 3' of the triplet were applied to study positioning of mRNA 3' of the A site codon. Complexes of 80S ribosomes with the mRNA analogues were obtained in the presence of tRNAPhe that directed UUU codon to the P site and consequently provided placement of the nucleotide with cross-linker in positions +9 or +12 with respect to the first nucleotide of the P site bound codon. Both types mRNA analogues cross-linked to the 18S rRNA and 40S proteins under mild UV-irradiation. Cross-linking patterns in the complexes where modified nucleotides of the mRNA analogues were in position +7 were analyzed for comparison (cross-linking to the 18S rRNA in such complexes has been studied previously). The efficiency of cross-linking to the ribosomal components depended on the nature of the modified nucleotide in the mRNA analogue and its position on the ribosome, extent of cross-linking to the 18S rRNA being decreased drastically when the modified nucleotide was moved from position +7 to position +12. The nucleotides of 18S rRNA cross-linked to mRNA analogues were determined. Modified nucleotides in positions +9 and +12 cross-linked to the invariant dinucleotide A1824/A1825 and to variable A1823 in the 3'-minidomain of 18S rRNA as well as to protein S15. The same ribosomal components have been found earlier to cross-link to modified mRNA nucleotides in positions from +4 to +7. Besides, all mRNA analogues cross-linked to the invariant nucleotide c1698 in the 3'-minidomain and to and the conserved region 605-620 closing helix 18 in the 5'-domain.     

The mRNA codon environment at the P and E sites of human ribosomes deduced from photo crosslinking with pUUUGUU

Three mRNA analogs--derivatives of hexaribonucleotide pUUUGUU comprising phenylalanine and valine codons with a perfluoroarylazido group attached to the C5 atom of the uridine residue at the first, second, or third position--were used for photocrosslinking with 80S ribosomes from human placenta. The mRNA analogs were positioned on the ribosome with tRNA recognizing these codons: UUU was at the P site if tRNA(Phe) was used, while tRNA(Val) was used to put there the GUU codon (UUU at the E site). Thus, the crosslinking group of mRNA analog might occupy positions -3 to +3 with respect to the first nucleotide of the codon at the P site. Irradiation of the complexes with soft UV light (lambda > 280 nm) resulted in the crosslinking of pUUUGUU derivatives with 18S RNA and proteins in the ribosome small subunit. The crosslinking with rRNA was observed only in the presence of tRNA. The photoactivatable group in positions -1 to +3 binds to G1207, while that in positions -2 or -3 binds to G961 of 18S RNA. In all cases, we observed crosslinking with S2 and S3 proteins irrespective of the presence of tRNA in the complex. Crosslinking with S23 and S26 proteins was observed mainly in the presence of tRNA when modified nucleotide occupied the +1 position (for both proteins) or the -3 position (for S26 protein). The crosslinking with S5/S7 proteins was substantial when modified nucleotide was in the -3 position, this crosslinking was not observed in the absence of tRNA.     

C-terminal fragment of ribosomal protein S15 is located at the decoding site of the human ribosome

Protein S15 is a characteristic component of the mammalian 80S ribosome that neighbors mRNA codon at the decoding site and the downstream triplets. In this study we determined S15 protein fragments located close to mRNA positions +4 to +12 with respect to the first nucleotide of the P site codon on the human ribosome. For cross-linking to ribosomal protein S15, a set of mRNA was used that contained triplet UUU/UUC at the 5'-termini and a perfluorophenyl azide-modified uridine in position 3' of this triplet. The locations of mRNA analogues on the ribosome were governed by tRNAPhe cognate to the UUU/UUC triplet targeted to the P site. Cross-linked S15 protein was isolated from the irradiated with mild UV light complexes of 80S ribosomes with tRNAPhe and mRNA analogues with subsequent cleavage with CNBr that splits polypeptide chain after methionines. Analysis of modified oligopeptides resulted from the cleavage revealed that in all cases cross-linking site was located in C-terminal fragment 111-145 of protein S15 indicating that this fragment is involved in formation of decoding site of the eukaryotic ribosome.     

Recycling of eukaryotic posttermination ribosomal complexes

After translational termination, mRNA and P site deacylated tRNA remain associated with ribosomes in posttermination complexes (post-TCs), which must therefore be recycled by releasing mRNA and deacylated tRNA and by dissociating ribosomes into subunits. Recycling of bacterial post-TCs requires elongation factor EF-G and a ribosome recycling factor RRF. Eukaryotes do not encode a RRF homolog, and their mechanism of ribosomal recycling is unknown. We investigated eukaryotic recycling using post-TCs assembled on a model mRNA encoding a tetrapeptide followed by a UAA stop codon and report that initiation factors eIF3, eIF1, eIF1A, and eIF3j, a loosely associated subunit of eIF3, can promote recycling of eukaryotic post-TCs. eIF3 is the principal factor that promotes splitting of posttermination ribosomes into 60S subunits and tRNA- and mRNA-bound 40S subunits. Its activity is enhanced by eIFs 3j, 1, and 1A. eIF1 also mediates release of P site tRNA, whereas eIF3j ensures subsequent dissociation of mRNA.     

New photoreactive tRNA derivatives for probing the peptidyl transferase center of the ribosome

Three new photoreactive tRNA derivatives have been synthesized for use as probes of the peptidyl transferase center of the ribosome. In two of these derivatives, the 3' adenosine of yeast tRNA(Phe) has been replaced by either 2-azidodeoxyadenosine or 2-azido-2'-O-methyl adenosine, while in a third the 3'-terminal 2-azidodeoxyadenosine of the tRNA is joined to puromycin via a phosphoramidate linkage to generate a photoreactive transition-state analog. All three derivatives bind to the P site of 70S ribosomes with affinities similar to that of unmodified tRNA(Phe) and can be cross-linked to components of the 50S ribosomal subunit by irradiation with near-UV light. Characteristic differences in the cross-linking patterns suggest that these tRNA derivatives can be used to follow subtle changes in the position of the tRNA relative to the components of the peptidyl transferase center.     

The context theory as applied to the decoding of the initiator tRNA by Escherichia coli ribosomes

The involvement of nucleotides adjacent to the termination codons in tRNA during the suppression of termination has been formulated as the 'context theory' by Bossi and Roth (1980) [Nature (Lond.) 286, 123-127]. The finding that U-U-G functions as an initiator codon has revived the discussion on the participation of the nucleotides flanking the initiator triplet in the decoding of initiator tRNA (context theory of initiation by the ribosome). We compared the capacity of oligonucleotides cognate to the anticodon loop of formylmethionine tRNA, such as A-U-G, A-U-G-A and U-A-U-G-A, to enhance the formation of the 30-S and 70-S ribosomal initiation complexes. Three different methods were used to determine the apparent binding constants and the stoichiometries of the respective complexes: adsorption of the complexes to nitrocellulose filters, equilibrium dialysis, and velocity sedimentation. We found that in the 30-S ribosomal initiation complex and in the presence of initiation factor 2 and GTP, formylmethionyl-tRNA is preferentially decoded by more than three mRNA bases. With the 70-S ribosome, however, once initiation factor 2 had been released, A-U-G represented the most effective codon to direct the formylmethionyl-tRNA to the peptidyl site. An extended initiator sequence may either give additional stability to the 30-S initiation complex or may allow for an ambiguity by one base pair in the decoding of the initiator tRNA.     

Interresidual distance determination by four-pulse double electron-electron resonance in an integral membrane protein: the Na+/proline transporter PutP of Escherichia coli

Proximity relationships within three doubly spin-labeled variants of the Na+/proline transporter PutP of Escherichia coli were studied by means of four-pulse double electron-electron resonance spectroscopy. The large value of 4.8 nm for the interspin distance determined between positions 107 in loop 4 and 223 in loop 7 strongly supports the idea of these positions being located on opposite sides of the membrane. Significant smaller values of between 1.8 and 2.5 nm were found for the average interspin distances between spin labels attached to the cytoplasmic loops 2 and 4 (position 37 and 107) and loops 2 and 6 (position 37 and 187). The large distance distribution widths visible in the pair correlation functions reveal a high flexibility of the studied loop regions. An increase of the distance between positions 37 and 187 upon Na+ binding suggests ligand-induced structural alterations of PutP. The results demonstrate that four-pulse double electron-electron resonance spectroscopy is a powerful means to investigate the structure and conformational changes of integral membrane proteins reconstituted in proteoliposomes.