The mRNA Codon Environment at the P and E Sites of Human Ribosomes Deduced from Photocrosslinking with pUUUGUU Derivatives

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 mild UV light ( > 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.     

Arrangement of the Sense and Stop Codons of the Template in the A Site of the Human Ribosome as Inferred from Crosslinking with Oligonucleotide Derivatives

Oligoribonucleotide derivatives containing Phe codon UUC along with a 3-flanking sense or stop codon with a perfluoroarylazido group at G or U were used to study the positioning of each nucleotide of the latter codon relative to the 18S rRNA in the A site of the 80S ribosome. To place the modified sense or stop codon in the A site, tRNA^Phe cognate to UCC was bound in the P site. Regardless of the position in the sense or stop codon, the modified nucleotide crosslinked with invariant dinucleotide A1823/A1824 and nucleotide A1825 in helix 44 close to the 3 end of the 18S rRNA. Located in the second or third position of either codon, the modified G bound with invariant nucleotide G626, which is in the evolutionarily conserved 530 stem–loop fragment. The results were collated with the X-ray structure of the bacterial ribosome, and the template codon was assumed to be similarly arranged relative to the small-subunit rRNA in the ribosomal A site of various organisms.     

The Template Region 5′ of the E-Site Codon Is Close to S26 in the Human 80S Ribosome

The environment of the template sequence 5 of the E-site codon on the 80S ribosome was studied with nonaribonucleotide or dodecaribonucleotide derivatives containing Phe codon UUU at the 3 end and a perfluoroarylazido group at the first or third nucleotide. A photoreactive group was linked to C5 of U or N7 of G. The analogs were positioned on the ribosome with the use of tRNA^Phe, which is cognate to the UUU codon and directs it to the P site, bringing a modified nucleotide in position –4 to –9 relative to the first nucleotide of the P-site codon. Upon irradiation of ribosome complexes with tRNA^Phe and the mRNA analogs with mild UV light, the analogs crosslinked predominantly to the 40S subunit, modifying the proteins. The major target of modification was S26 in all cases. In addition, S3 was modified to a low extent when the reactive nucleotide was in position –4 and S14 was in position –6. In the absence of tRNA, all mRNA analogs modified S3.     

Highly Conserved Region 1816–1831 of the 18S Ribosomal RNA Is Close to the First Nucleotide of the A-Site Codon in Elongation and Termination of Translation

Two mRNA analogs, pUUCUAAA (with stop codon UAA) and pUUCUCAA (with Ser codon UCA) containing a perfluoroarylazido group at U4, were used to study the position relative to the 18S rRNA for the first nucleotide of the codon located in the A site of the human 80S ribosome. To place UAA or UCA in the A site, UCC-recognizing tRNA^Phe was bound in the P site. With each analog, crosslinking was detected for highly conserved fragment 1816–1831, which contains invariant dinucleotide A1823/A1824 and is in helix 44 at the 3" end of the 18S rRNA. Since 18S rRNA modification did not depend on whether the U4 photoreactive group was in the sense or stop codon, it was assumed that polypeptide chain release factor 1 directly recognizes the trinucleotide of a stop codon located in the A site.     

Positioning of mRNA codons with respect to 18S rRNA at the P and E sites of human ribosome

Positioning of each nucleotide of the E site and the P site bound codons with respect to the 18S rRNA on the human ribosome was studied by cross-linking with mRNA analogs, derivatives of the hexaribonucleotide UUUGUU (comprising Phe and Val codons) that carried a perfluorophenylazide group on the second or the third uracil, and a derivative of the dodecaribonucleotide UUAGUAUUUAUU with a similar group on the guanine residue. The location of the modified nucleotides at any mRNA position from -3 to +3 (position +1 corresponds to the 5' nucleotide of the P site bound codon) was adjusted by the cognate tRNAs. A modified uridine at positions from -1 to +3 cross-linked to nucleotide G1207 of the 18S rRNA, and to nucleotide G961 when it was in position -2. A modified guanosine cross-linked to nucleotide G1207 if it was in position -3 of the mRNA. These data indicate that nucleotide G961 of the 18S rRNA is close only to mRNA positions -3 and -2, while G1207 is in the vicinity of positions from -3 to +3. The latter suggests that there is a sharp turn between the P and E site bound codons that brings nucleotide G1207 of the 18S rRNA close to each nucleotide of these codons. This correlates well with X-ray crystallographic data on bacterial ribosomes, indicating existence of a sharp turn between the P site and E site bound codons near a conserved nucleotide G926 of the 16S rRNA (corresponding to G1207 in 18S rRNA) close to helix 23b containing the conserved nucleotide 693 of the 16S rRNA (corresponding exactly to G961 of the 18S rRNA).     

Molecular environment of the subdomain IIIe loop of the RNA IRES element of hepatitis C virus on the human 40S ribosomal subunit

The molecular environment of the internal ribosome entry site (IRES element) of hepatitis C viral (HCV) RNA in the binary complex with the human 40S ribosomal subunit was studied. To this end, RNA derivatives bearing mild UV-reactive perfluorophenylazide groups at nucleotide G87 in IRES domain II and at nucleotide A296 in the subdomain IIIe loop were used, which were prepared by the RNA complementarily-addressed modification with alkylating oligonucleotide derivatives. None of the RNA derivatives were shown to be crosslinked to the 18S rRNA of the 40S subunit. It was found that the photoreactive group of IRES nucleotide A296 crosslinked to the 40S subunit S2/S3a, S5, and p40 (SOA) proteins. No protein crosslinking was observed for the RNA derivative containing the same photoreactive group at nucleotide G87. It was concluded that the subdomain IIIe loop of the HCV RNA IRES element in the complex with the 40S subunit is located on the subunit between the head and the body aside the “beak” near the exit from the mRNA-binding channel.     

Protein Environment of the Sense Codon of the Template in the A Site of the Human Ribosome as Inferred from Crosslinking to Oligoribonucleotide Derivatives

The protein environment of each nucleotide of the template codon located in the A site of the human ribosome was studied with UUCUCAA and UUUGUU derivatives containing a Phe codon (UUC and UUU, respectively) and a perfluoroarylazido group at U4, U5, or U6. The analogs were positioned in the ribosome with the use of tRNA^Phe, which is cognate to the UUC or UUU codon and directs it to the P site, bringing a modified codon in the A site with a modified nucleotide occupying position +4, +5, or +6 relative to the first nucleotide of the P-site codon. On irradiation of ribosome complexes with tRNA^Phe and mRNA analogs with mild UV light, the analogs crosslinked predominantly to the 40S subunit, modifying the proteins to a greater extent than the rRNA. The 18S rRNA nucleotides crosslinking to the analogs were identified previously. Of the small-subunit proteins, S3 and S15 were the major targets of modification in all cases. The former was modified both in ternary complexes and in the absence of tRNA, and the latter, only in ternary complexes. The extent of crosslinking of mRNA analogs to S15 decreased when the modified nucleotide was shifted from position +4 to position +6. The results were collated with the data on ribosomal proteins located at the decoding site of the 70S ribosome, and conclusion was made that the protein environment of the A-site codon strikingly differs between bacterial and eukaryotic ribosomes.     

WBSCR22/Merm1 is required for late nuclear pre-ribosomal RNA processing and mediates N7-methylation of G1639 in human 18S rRNA

Ribosomal (r)RNAs are extensively modified during ribosome synthesis and their modification is required for the fidelity and efficiency of translation. Besides numerous small nucleolar RNA-guided 2′-O methylations and pseudouridinylations, a number of individual RNA methyltransferases are involved in rRNA modification. WBSCR22/Merm1, which is affected in Williams–Beuren syndrome and has been implicated in tumorigenesis and metastasis formation, was recently shown to be involved in ribosome synthesis, but its molecular functions have remained elusive. Here we show that depletion of WBSCR22 leads to nuclear accumulation of 3′-extended 18SE pre-rRNA intermediates resulting in impaired 18S rRNA maturation. We map the 3′ ends of the 18SE pre-rRNA intermediates accumulating after depletion of WBSCR22 and in control cells using 3′-RACE and deep sequencing. Furthermore, we demonstrate that WBSCR22 is required for N⁷-methylation of G1639 in human 18S rRNA in vivo. Interestingly, the catalytic activity of WBSCR22 is not required for 18S pre-rRNA processing, suggesting that the key role of WBSCR22 in 40S subunit biogenesis is independent of its function as an RNA methyltransferase.     

Arrangement of the Template 3′ of the A-Site Codon on the Human 80S Ribosome

The arrangement of the template sequence 3′ of the A-site codon on the 80S ribosome was studied using mRNA analogs containing Phe codon UUU at the 5′ end and a photoreactive perfluoroarylazido group linked to C5 of U or N7 of G. The analogs were positioned on the ribosome with the use of tRNA^Phe, which directed the UUU codon to the P site, bringing a modified nucleotide to position +9 or +12 relative to the first nucleotide of the P-site codon. Upon mild UV irradiation of ribosome complexes, the analogs of both types crosslinked to the 18S rRNA and proteins of the 40S subunit. Comparisons were made with the crosslinking patterns of complexes in which an mRNA analog contained a modified nucleotide in position +7 (the crosslinking to 18S rRNA in such complexes has been studied previously). The efficiency of crosslinking to ribosomal components depended on the nature of the modified nucleotide of an mRNA analog and its position on the ribosome. The extent of crosslinking to the 18S rRNA drastically decreased as the modified nucleotide was transferred from position +7 to position +12. The 18S rRNA nucleotides involved in crosslinking were identified. A modified nucleotide in position +9 crosslinked to the invariant dinucleotide A1824/A1825 and variable A1823 in the 3′ minidomain of the 18S rRNA and to S15. The same ribosomal components have earlier been shown to crosslink to modified nucleotides in positions +4 to +7. In addition, all mRNA analogs crosslinked to invariant C1698 in the 3′ minidomain and to conserved region 605–620, which closes helix 18 in the 5′ domain.     

Nucleotides of 18S rRNA surrounding mRNA codons at the human ribosomal A, P, and E sites: a crosslinking study with mRNA analogs carrying an aryl azide group at either the uracil or the guanine residue

The 18S rRNA environment of the mRNA at the decoding site of human 80S ribosomes has been studied by cross-linking with derivatives of hexaribonucleotide UUUGUU (comprising Phe and Val codons) that carried a perfluorophenylazide group either at the N7 atom of the guanine or at the C5 atom of the 5'-terminal uracil residue. The location of the codons on the ribosome at A, P, or E sites has been adjusted by the cognate tRNAs. Three types of complexes have been obtained for each type derivative, namely, (1) codon UUU and Phe-tRNAPhe at the P site (codon GUU at the A site), (2) codon UUU and tRNAPhe at the P site and PheVal-tRNAVal at the A site, and (3) codon GUU and Val-tRNAVal at the P site (codon UUU at the E site). This allowed the placement of modified nucleotides of the mRNA analog at positions -3, +1, or +4 on the ribosome. Mild UV irradiation resulted in tRNA-dependent crosslinking of the mRNA analogs to the 18S rRNA. Nucleotide G961 crosslinked to mRNA position -3, nucleotide G1207 to position +1, and A1823 together with A1824 to position +4. All of these nucleotides are located in the most strongly conserved regions of the small subunit RNA structure, and correspond to nucleotides G693, G926, G1491, and A1492 of bacterial 16S rRNA. Three of them (with the exception of G1491) had been found earlier at the 70S ribosomal decoding site. The similarities and differences between the 16S and 18S rRNA decoding sites are discussed.     

Protein S3 in the human 80S ribosome adjoins mRNA 3′ of the A-site codon

The protein environment of mRNA 3′ of the A-site codon (the decoding site) in the human 80S ribosome was studied using a set of oligoribonucleotide derivatives bearing a UUU triplet at the 5′-end and a perfluoroarylazide group at one of the nucleotide residues 3′ of this triplet. Analogues of mRNA were phased into the ribosome using binding at the tRNA^Phe P-site, which recognizes the UUU codon. Mild UV irradiation of ribosome complexes with tRNA^Phe and mRNA analogues resulted in the predominant crosslinking of the analogues with the 40S subunit components, mainly with proteins and, to a lesser extent, with rRNA. Among the 40S subunit ribosomal proteins, the S3 protein was the main target for modification in all cases. In addition, minor crosslinking with the S2 protein was observed. The crosslinking with the S3 and S2 proteins occurred both in ternary complexes and in the absence of tRNA. Within ternary complexes, crosslinking with S15 protein was also found, its efficiency considerably falling when the modified nucleotide was moved from positions +5 to +12 relative to the first codon nucleotide in the P-site. In some cases, crosslinking with the S30 protein was observed; it was most efficient for the derivative containing a photoreactive group at the +7 adenosine residue. The results indicate that the S3 protein in the human ribosome plays a key role in the formation of the mRNA binding site 3′ of the codon in the decoding site.     

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.     

The C domain of translation termination factor eRF1 is close to the stop codon in the A site of the 80S ribosome

The arrangement of the stop codon and its 3′-flanking codon relative to the components of translation termination complexes of human 80S ribosomes was studied using mRNA analogs containing the stop signal UPuPuPu (Pu is A or G) and the photoreactive perfluoroarylazido group, which was linked to a stop-signal or 3′-flanking nucleotide (positions from +4 to +9 relative to the first nucleotide of the P-site codon). Upon mild UV irradiation, the analogs crosslinked to components of the model complexes, mimicking the state of the 80S ribosome at translation termination. Termination factors eRF1 and eRF3 did not change the relative arrangement of the stop signal and 18S rRNA. Crosslinking to eRF1 was observed for modified nucleotides in positions +5 to +9 (that for stop-codon nucleotide +4 was detected earlier). The eRF1 fragments crosslinked to the mRNA analogs were identified. Fragment 52–195, including the N domain and part of the M domain, crosslinked to the analogs carrying the reactive group at A or G in positions +5 to +9 or at the terminal phosphate of nucleotide +7. The site crosslinking to mRNA analogs containing modified G in positions +5 to +7 was assigned to eRF1 fragment 82–166 (beyond the NIKS motif). All but one analog (that with modified G in position +4) crosslinked to the C domain of eRF1 (fragment 330–422). The efficiency of crosslinking to the C domain was higher than to the N domain in most cases. It was assumed that the C domain of eRF1 bound in the A site is close to nucleotides +5 to +9, especially +7 and +8, and that eRF1 undergoes substantial conformational changes when binding to the ribosome.     

Site-specific cleavage of the 40S ribosomal subunit reveals eukaryote-specific ribosomal protein S28 in the subunit head

After resolving the crystal structure of the prokaryotic ribosome, mapping the proteins in the eukaryotic ribosome is a challenging task. We applied RNase H digestion to split the human 40S ribosomal subunit into head and body parts. Mass spectrometry of the proteins in the 40S subunit head revealed the presence of eukaryote-specific ribosomal protein S28e. Recombinant S28e was capable of specific binding to the 3′ major domain of the 18S rRNA (K_a = 8.0 ± 0.5 × 10⁹ M⁻¹). We conclude that S28e has a binding site on the 18S rRNA within the 40S subunit head.

Structured summary

MINT-8044084: S8 (uniprotkb:P62241) and S19 (uniprotkb:P39019) colocalize (MI:0403) by cosedimentation through density gradient (MI:0029)MINT-8044095: S8 (uniprotkb:P62241), S19 (uniprotkb:P39019) and S13 (uniprotkb:P62277) colocalize (MI:0403) by cosedimentation through density gradient (MI:0029)MINT-8044024: S29 (uniprotkb:P62273), S28 (uniprotkb:P62857), S21 (uniprotkb:P63220), S20 (uniprotkb:P60866), S26 (uniprotkb:P62854), S25 (uniprotkb:P62851), S12 (uniprotkb:P25398), S17 (uniprotkb:P08708), S19 (uniprotkb:P39019), S14 (uniprotkb:P62263), S16 (uniprotkb:P62249) and S11 (uniprotkb:P62280) colocalize (MI:0403) by cosedimentation through density gradient (MI:0029)MINT-8044065: S29 (uniprotkb:P62273), S28 (uniprotkb:P62857), S19 (uniprotkb:P39019), S14 (uniprotkb:P62263) and S16 (uniprotkb:P62249) colocalize (MI:0403) by cosedimentation through density gradient (MI:0029)     

Structural and Functional Topography of Human Ribosomes Deduced from Crosslinking with mRNA Analogs,Oligoribonucleotide Derivatives

Reviewed are data on the position of template codons with respect to 18S rRNA and certain proteins on human ribosome obtained using a set of mRNA analogs, oligoribonucleotide derivatives carrying alkylating or photoactivatable groups at different positions. A comparison of data on the template position on the human and Escherichia coliribosomes has revealed both the similarity in the structure of the mRNA-binding site of bacterial and mammalian ribosomes and the peculiarities of the functioning of mammalian (in particular, human) ribosomes. The similarity manifests itself in that the template codons at the A-, P-, and E-sites of bacterial and human ribosomes are surrounded by similar nucleotides (occupying similar positions in the conserved regions of secondary structure) of small subunit rRNA. The template forms a loop whose foot is in proximity to the 530 stem–loop conserved region of rRNA. The specific features of mammalian ribosomes appear to be associated with their lower conformational mobility as compared with bacterial ribosomes, owing to which their interaction with the template involves a lesser number of molecular contacts.