AP lyase activity of the human ribosomal protein uS3: The DNA cleavage sequence specificity and the location of the enzyme active center.

The human protein uS3, a component of the small ribosomal subunit, has a long-known extra-ribosomal activity as an enzyme of base excision DNA repair displayed in its ability to cleave DNA at abasic (AP) sites. It has been found that the efficacy of DNA cleavage by uS3 in vitro depends on the DNA sequence. To clarify the issue on the sequence specificity of uS3 as an AP lyase in general, we applied a combinatorial approach based on the use of a model single-stranded circular DNA with an AP site flanked with random trinucleotides at both sides. The cleavage of this DNA by uS3 under conditions when only its minor portion undergoes the reaction resulted in the formation of the linear DNA with random triplets at the 5' and 3' termini. NGS sequencing of the DNA library derived from this DNA allowed identifying the contexts within which uS3 cleaves DNA the most and the least effectively. Given that the AP lyase reaction occurs via the formation of a covalent intermediate (Schiff base), we determined the region comprising the active center of the uS3 protein. By digesting of uS3 cross-linked to a radiolabeled AP site-containing model DNA with specific proteolytic agents followed by analysis of the resulting modified oligopeptides, the cross-link was mapped to the region 155-192 (likely, to R173/R178). Thus, our results clarified two previously unstudied features of the uS3 AP lyase activity, one related to the recognition of sequences in DNA surrounding the AP site, and the other to the protein region directly contacting this site.

Reorganization of the Landscape of Translated mRNAs in NSUN2-Deficient Cells and Specific Features of NSUN2 Target mRNAs.

The RNA cytosine C5 methyltransferase NSUN2 has a variety of RNA substrates and plays an important role in mRNA metabolism. NSUN2 binds to specific sequences enriched in exosomal mRNAs, suggesting its possible involvement in the sorting of mRNAs into exosomes. We applied the photoactivatable.4-thiouridine-enhanced cross-linking and immunoprecipitation assay involving high-throughput RNA sequencing (RNA-seq) to HEK293T cells to determine NSUN2 mRNA targets. NSUN2 cross-linking sites were found in more than one hundred relatively abundant mRNAs with a high GC content and a pronounced secondary structure. Then, utilizing RNA-seq for the total and polysome-associated mRNA from HEK293T cells with and without the knockdown of NSUN2, we identified differentially expressed genes, as well as genes with altered translational efficiency (GATEs). It turned out that the up-regulated GATE mRNAs were much shorter on average than the down-regulated ones, and their GC content was higher; moreover, they contained motifs with C residues located in GC-rich environments. Our findings reveal the specific features of mRNAs that make them potential targets for NSUN2 and expand our understanding of the role of NSUN2 in controlling translation and, possibly, in mRNA sorting into exosomes implemented through the methylation of cytosine residues.

The functional role of the eukaryote-specific motif YxxPKxYxK of the human ribosomal protein eS26 in translation.

The protein eS26 is a structural component of the eukaryotic small ribosomal subunit involved in the formation of the mRNA binding channel in the region of the exit site. By applying site-directed cross-linking to mammalian 80S ribosomes, it has been shown that the same mRNA nucleotide residues are implicated in the interaction with both eS26 and translation initiation factor 3 (eIF3) and that contacts of the protein with mRNAs are mediated by its eukaryote-specific motif YxxPKxYxK. To examine the role of eS26 in translation, we transfected HEK293T cells with plasmid constructs encoding the wild-type FLAG-labeled protein (wt-eS26FLAG) or its forms with either a single substitution of any conserved amino acid residue in the above motif, or a simultaneous replacement of all the five ones (5A). The western blot analysis of fractions of polysome profiles from the transfected cells revealed no effects of the single mutations in eS26, but showed that the replacement of the five conserved residues led to the increased share of the light polysome fraction compared to that detected with control, wt-eS26FLAG-producing cells. In addition, the above fraction exhibited the enhanced content of the eIF3e subunit that is known to promote selective translation. These findings, together with real-time PCR data on the relative contents of specific mRNAs in light and heavy polysomes from cells producing the mutant 5A compared to those from control cells, suggest a possible involvement of the YxxPKxYxK motif of eS26 in the fine regulation of translation to maintain the required balance of synthesized proteins.

Changes in the Transcriptome Caused by Mutations in the Ribosomal Protein uS10 Associated with a Predisposition to Colorectal Cancer.

A number of mutations in the RPS20 gene encoding the ribosomal protein uS10 have been found to be associated with a predisposition to hereditary non-polyposis colorectal carcinoma (CRC). We transfected HEK293T cells with constructs carrying the uS10 minigene with mutations identical to those mentioned above and examined the effects of the produced proteins on the cellular transcriptome. We showed that uS10 with mutations p.V50SfsX23 or p.L61EfsX11 cannot be incorporated into 40S ribosomal subunits, while the protein with the missense mutation p.V54L functionally replaces the respective endogenous protein in the 40S subunit assembly and the translation process. The comparison of RNA-seq data obtained from cells producing aberrant forms of uS10 with data for those producing the wild-type protein revealed overlapping sets of upregulated and downregulated differently expressed genes (DEGs) related to several pathways. Among the limited number of upregulated DEGs, there were genes directly associated with the progression of CRC, e.g., PPM1D and PIGN. Our findings indicate that the accumulation of the mutant forms of uS10 triggers a cascade of cellular events, similar to that which is triggered when the cell responds to a large number of erroneous proteins, suggesting that this may increase the risk of cancer.

Deficiency of the Ribosomal Protein uL5 Leads to Significant Rearrangements of the Transcriptional and Translational Landscapes in Mammalian Cells.

Protein uL5 (formerly called L11) is an integral component of the large (60S) subunit of the human ribosome, and its deficiency in cells leads to the impaired biogenesis of 60S subunits. Using RNA interference, we reduced the level of uL5 in HEK293T cells by three times, which caused an almost proportional decrease in the content of the fraction corresponding to 80S ribosomes, without a noticeable diminution in the level of polysomes. By RNA sequencing of uL5-deficient and control cell samples, which were those of total mRNA and mRNA from the polysome fraction, we identified hundreds of differentially expressed genes (DEGs) at the transcriptome and translatome levels and revealed dozens of genes with altered translational efficiency (GATEs). Transcriptionally up-regulated DEGs were mainly associated with rRNA processing, pre-mRNA splicing, translation and DNA repair, while down-regulated DEGs were genes of membrane proteins; the type of regulation depended on the GC content in the 3' untranslated regions of DEG mRNAs. The belonging of GATEs to up-regulated and down-regulated ones was determined by the coding sequence length of their mRNAs. Our findings suggest that the effects observed in uL5-deficient cells result from an insufficiency of translationally active ribosomes caused by a deficiency of 60S subunits.

Two alternative conformations of mRNA in the human ribosome during elongation and termination of translation as revealed by EPR spectroscopy.

The conformation of mRNA in the region of the human 80S ribosome decoding site was monitored using 11-mer mRNA analogues that bore nitroxide spin labels attached to the terminal nucleotide bases. Intramolecular spin-spin distances were measured by DEER/PELDOR spectroscopy in model complexes mimicking different states of the 80S ribosome during elongation and termination of translation. The measurements revealed that in all studied complexes, mRNA exists in two alternative conformations, whose ratios are different in post-translocation, pre-translocation and termination complexes. We found that the presence of a tRNA molecule at the ribosomal A site decreases the relative share of the more extended mRNA conformation, whereas the binding of eRF1 (alone or in a complex with eRF3) results in the opposite effect. In the termination complexes, the ratios of mRNA conformations are practically the same, indicating that a part of mRNA bound in the ribosome channel does not undergo significant structural alterations in the course of completion of the translation. Our results contribute to the understanding of mRNA molecular dynamics in the mammalian ribosome channel during translation.

AP sites in various mRNA positions cross-link to the protein uS3 in the translating mammalian ribosome.

Abasic (AP) sites in mRNAs are lesions whose accumulation in cells is linked to various neurodegenerative diseases arising from the appearance of truncated peptides due to the premature cessation of translation of these mRNAs. It is believed that the translation of AP site-containing mRNAs is stopped when the damaged codon arrives to the A site, where it is not decoded. We propose an alternative translation arrest mechanism mediated by the 40S ribosomal subunit protein uS3. Recently, it has been shown that in human 80S ribosomal complexes assembled without translation factors, uS3 cross-links to the AP site at the 3'-terminus of the mRNA, whose undamaged part is bound at the 40S subunit channel, via its peptide 55-64 exposed near the mRNA entry pore. In this study, we examined whether such cross-linking occurs during the translation of mRNA with the AP site. To this end, we used a set of synthetic mRNAs bearing the AP site inserted in the desired location in their sequences. An analysis of 80S ribosomal complexes formed with these mRNAs in a mammalian cell-free protein-synthesizing system demonstrates that AP sites do indeed cross-link to uS3 in the course of the translation. We also show that the cross-linking occurs as soon as the AP site arrives to a common favorable position relative to uS3, which is independent on its location in the mRNA. Our findings suggest that the mechanism of stopping translation of damaged mRNAs involving uS3, along with the one mentioned above, could underlie ribosome-associated mRNA quality control.

Knockdown of the Ribosomal Protein eL38 in HEK293 Cells Changes the Translational Efficiency of Specific Genes.

The protein eL38 is one of the smallest proteins of the mammalian ribosome, which is a component of its large (60S) subunit. The haploinsufficiency of eL38 in mice leads to the Tail-short mutant phenotype characterized by defects in the development of the axial skeleton caused by the poor translation of mRNA subsets of Hox genes. Using the ribosome profiling assay applied to HEK293 cells knocked down of eL38, we examined the effects of the lack of eL38 in 60S subunits on gene expression at the level of translation. A four-fold decrease in the cell content of eL38 was shown to result in significant changes in the translational efficiencies of 150 genes. Among the genes, whose expression at the level of translation was enhanced, there were mainly those associated with basic metabolic processes; namely, translation, protein folding, chromosome organization, splicing, and others. The set of genes with reduced translation efficiencies contained those that are mostly involved in the processes related to the regulation of transcription, including the activation of Hox genes. Thus, we demonstrated that eL38 insufficiency significantly affects the expression of certain genes at the translational level. Our findings facilitate understanding the possible causes of some anomalies in eL38-deficient animals.

Knockdown of the mRNA encoding the ribosomal protein eL38 in mammalian cells causes a substantial reorganization of genomic transcription.

The ribosomal protein eL38 is a component of the mammalian translation machine. The deletion of the Rpl38 locus in mice results in the Tail-short (Ts) mutant phenotype characterized by a shortened tail and other defects in the axial skeleton development. Here, using the next-generation sequencing of total RNA from HEK293 cells knocked down of eL38 mRNA by transfection with specific siRNAs, we examined the effect of reduced eL38 content on genomic transcription. An approximately 4-fold decrease in the level of eL38 was shown to cause changes in the expression of nearly 1500 genes. Among the down-regulated genes, there were those responsible for p53 activity, Ca2+ metabolism and several signaling processes, as well as genes involved in the organization and functioning of the cytoskeleton. The genes related to rRNA processing and translation, along with many others, including those whose dysregulation is associated with developmental disorders, turned out to be up-regulated. Thus, we demonstrated that the decreased RPL38 expression leads to a significant reorganization of genomic transcription. Our findings suggest a possible link between the balance of eL38 and genes implicated in osteogenesis, thereby contributing to the elucidation of the reasons for the appearance of the above Ts mutant phenotype in animals.

Eukaryotic protein uS19: a component of the decoding site of ribosomes and a player in human diseases.

Proteins belonging to the universal ribosomal protein (rp) uS19 family are constituents of small ribosomal subunits, and their conserved globular parts are involved in the formation of the head of these subunits. The eukaryotic rp uS19 (previously known as S15) comprises a C-terminal extension that has no homology in the bacterial counterparts. This extension is directly implicated in the formation of the ribosomal decoding site and thereby affects translational fidelity in a manner that has no analogy in bacterial ribosomes. Another eukaryote-specific feature of rp uS19 is its essential participance in the 40S subunit maturation due to the interactions with the subunit assembly factors required for the nuclear exit of pre-40S particles. Beyond properties related to the translation machinery, eukaryotic rp uS19 has an extra-ribosomal function concerned with its direct involvement in the regulation of the activity of an important tumor suppressor p53 in the Mdm2/Mdmx-p53 pathway. Mutations in the RPS15 gene encoding rp uS19 are linked to diseases (Diamond Blackfan anemia, chronic lymphocytic leukemia and Parkinson's disease) caused either by defects in the ribosome biogenesis or disturbances in the functioning of ribosomes containing mutant rp uS19, likely due to the changed translational fidelity. Here, we review currently available data on the involvement of rp uS19 in the operation of the translational machinery and in the maturation of 40S subunits, on its extra-ribosomal function, and on relationships between mutations in the RPS15 gene and certain human diseases.

Ribosomal protein uS3 in cell biology and human disease: Latest insights and prospects.

The conserved ribosomal protein uS3 in eukaryotes has long been known as one of the essential components of the small (40S) ribosomal subunit, which is involved in the structure of the 40S mRNA entry pore, ensuring the functioning of the 40S subunit during translation initiation. Besides, uS3, being outside the ribosome, is engaged in various cellular processes related to DNA repair, NF-kB signaling pathway and regulation of apoptosis. This review is devoted to recent data opening new horizons in understanding the roles of uS3 in such processes as the assembly and maturation of 40S subunits, ensuring proper structure of 48S pre-initiation complexes, regulation of initiation and ribosome-based RNA quality control pathways. Besides, we summarize novel results on the participation of the protein in processes beyond translation and consider biomedical implications of previously known and recently found extra-ribosomal functions of uS3, primarily, in oncogenesis.

The human ribosomal protein eL29 binds in vivo to the cognate mRNA by interacting with its coding sequence, as revealed from in-cell cross-linking data.

The balance of ribosomal proteins is important for the assembly of ribosomal subunits and cell viability. The synthesis of ribosomal proteins in a eukaryotic cell is controlled by various mechanisms, including autoregulation, which so far has been revealed for only a few of these proteins. We applied the photoactivatable 4-thiouridine-enhanced cross-linking and immunoprecipitation assay to HEK293T cells overproducing FLAG-labeled human ribosomal protein eL29 (eL29FLAG) to determine which RNAs other than rRNA interact with eL29. We demonstrated that eL29FLAG was incorporated into 60S subunits, and that ribosomes with those containing eL29FLAG were competent in translation. Analysis of the next generation sequencing data obtained from a DNA library derived from RNA fragments with covalently attached eL29FLAG peptide residues showed that the protein was cross-linked to the mRNA of the eL29-coding gene, which turned out to be its only major RNA target. The eL29FLAG cross-linking sites were located in the 3' part of the mRNA coding sequence (CDS). A specific helix that mimics the eL29 binding site on 28S rRNA was proposed as a site that is recognized by the protein upon its binding to the cognate mRNA. In addition, it was found that both eL29FLAG mRNA and eL29 mRNA, unlike those of other ribosomal proteins, were co-immunoprecipitated with eL29FLAG from the ribosome-depleted cell lysate, and recombinant eL29 inhibited the translation of the eL29 mRNA CDS transcript in a cell-free system. All this suggests that human eL29 regulates its own synthesis via a feedback mechanism by binding to the cognate mRNA, preventing its translation.

Knockdown of the Ribosomal Protein eL29 in Mammalian Cells Leads to Significant Changes in Gene Expression at the Transcription Level.

An imbalance in the synthesis of ribosomal proteins can lead to the disruption of various cellular processes. For mammalian cells, it has been shown that the level of the eukaryote-specific ribosomal protein eL29, also known as the one interacting with heparin/heparan sulfate, substantially affects their growth. Moreover, in animals lacking this protein, a number of anatomical abnormalities have been observed. Here, we applied next-generation RNA sequencing to HEK293 cells transfected with siRNAs specific for the mRNA of eL29 to determine what changes occur in the transcriptome profile with a decrease in the level of the target protein. We showed that an approximately 2.5-fold decrease in the content of eL29 leads to statistically significant changes in the expression of more than a thousand genes at the transcription level, without a noticeable effect on cell viability, rRNA level, and global translation. The set of eL29-dependent genes included both up-regulated and down-regulated ones, among which there are those previously identified as targets for proteins implicated in oncogenesis. Thus, our findings demonstrate that an insufficiency of eL29 in mammalian cells causes a significant reorganization of gene expression, thereby highlighting the relationship between the cellular balance of eL29 and the activities of certain genes.

The functional role of the C-terminal tail of the human ribosomal protein uS19.

The eukaryotic ribosomal protein uS19 has a C-terminal tail that is absent in its bacterial homologue. This tail has been shown to be involved in the formation of the decoding site of human ribosomes. We studied here the previously unexplored functional significance of the 15 C-terminal amino acid residues of human uS19 for the assembly of ribosomes and translation using HEK293-based cell cultures capable of producing FLAG-labeled uS19 (uS19FLAG) or its mutant form deprived of the mentioned amino acid ones. The examination of polysome profiles of cytoplasmic extracts from the respective cells revealed that the deletion of the above uS19 amino acid residues barely affected the assembly and maturation of 40S subunits and the initiation of translation, but completely prevented the formation of polysomes. This implied the crucial importance of the uS19 tail in the elongation process. Analysis of tRNAs associated with 40S subunits and 80S ribosomes containing wild type uS19FLAG or its truncated form showed that the deletion of the C-terminal pentadecapeptide fragment of uS19 did not interfere with the binding of aminoacyl-tRNA (aa-tRNA) at the ribosomal A site. The results led to the conclusion that the transpeptidation, which occurs on the large ribosomal subunit after decoding the A site codon by the incoming aa-tRNA, is the most likely elongation stage, where this uS19 fragment can play a critical role. Our findings suggest that the uS19 tail is a keystone player in the accommodation of aa-tRNA at the A site, which is a pre-requisite for the peptide transfer.

Degenerate consensus sequences in the 3'-untranslated regions of cellular mRNAs as specific motifs potentially involved in the YB-1-mediated packaging of these mRNAs.

The multifunctional protein YB-1 has previously been shown to be the only protein of the cytoplasmic extract of HEK293 cells, which is able to specifically interact with imperfect RNA hairpins containing motifs that are often found in exosomal (e) RNAs. In addition, it has been revealed that similar hairpins formed by degenerate consensus sequences corresponding to three eRNA-specific motifs are responsible for the cooperative binding of YB-1 to RNA in vitro. Here, using the photoactivatable ribonucleoside-enhanced cross-linking and immunoprecipitation method applied to HEK293 cells producing FLAG-labeled YB-1, we identified mRNAs cross-linked to YB-1 in vivo and then carried out a search for the aforementioned sequences in the regions of the YB-1 cross-linking sites. It turned out that many of the mRNAs found cross-linked to YB-1 encode proteins associated with various regulatory processes, including responses to stress. More than half of all cross-linked mRNAs contained degenerate consensus sequences, which were preferably located in 3'-untranslated regions (UTRs), where most of the YB-1 cross-linking sites appeared, although not close to these sequences. Furthermore, YB-1 was mainly cross-linked to those mRNAs with degenerate consensus sequences, which could be classified as packaged because their translation levels were low compared to cellular levels. This suggests that the cooperative binding of YB-1 to mRNAs through the above sequences probably triggers the well-known multimerization of YB-l, leading to the packaging of these mRNAs. Thus, our findings indicate a previously unknown link between the degenerate consensus sequences present in the 3'-UTRs of many cytoplasmic mRNAs and YB-1-mediated translational silencing.

mRNA regions where 80S ribosomes pause during translation elongation in vivo interact with protein uS19, a component of the decoding site.

In eukaryotic ribosomes, the conserved protein uS19, formerly known as S15, extends with its C-terminal tail to the decoding site. The cross-linking of uS19 to the A site codon has been detected using synthetic mRNAs bearing 4-thiouridine (s4U) residues. Here, we showed that the A-site tRNA prevents this cross-linking and that the P site codon does not contact uS19. Next, we focused on determining uS19-mRNA interactions in vivo by applying the photoactivatable-ribonucleoside enhancing cross-linking and immunoprecipitation method to a stable HEK293 cell line producing FLAG-tagged uS19 and grown in a medium containing s4U. We found that when translation was stopped by cycloheximide, uS19 was efficiently cross-linked to mRNA regions with a high frequency of Glu, Lys and, more rarely, Arg codons. The results indicate that the complexes, in which the A site codon is not involved in the formation of the mRNA-tRNA duplex, are present among the cycloheximide-arrested 80S complexes, which implies pausing of elongating ribosomes at the above mRNA regions. Thus, our findings demonstrate that the human ribosomal protein uS19 interacts with mRNAs during translation elongation and highlight the regions of mRNAs where ribosome pausing occurs, bringing new structural and functional insights into eukaryotic translation in vivo.

Exploring the interactions of short RNAs with the human 40S ribosomal subunit near the mRNA entry site by EPR spectroscopy.

The features of previously unexplored labile complexes of human 40S ribosomal subunits with RNAs, whose formation is manifested in the cross-linking of aldehyde derivatives of RNAs to the ribosomal protein uS3 through its peptide 55-64 located outside the mRNA channel, were studied by EPR spectroscopy methods. Analysis of subatomic 40S subunit models showed that a likely site for labile RNA binding is a cluster of positively charged amino acid residues between the mRNA entry site and uS3 peptide 55-64. This is consistent with our finding that the 3'-terminal mRNA fragment hanging outside the 40S subunit prevents the cross-linking of an RNA derivative to this peptide. To detect labile complexes of 40S subunits with RNA by DEER/PELDOR spectroscopy, an undecaribonucleotide derivative with nitroxide spin labels at terminal nucleotides was utilized. We demonstrated that the 40S subunit channel occupancy with mRNA does not affect the RNA derivative binding and that uS3 peptide 55-64 is not involved in binding interactions. Replacing the RNA derivative with a DNA one revealed the importance of ribose 2'-OH groups for the complex formation. Using the single-label RNA derivatives, the distance between the mRNA entry site and the loosely bound RNA site on the 40S subunit was estimated.

Tetrapeptide 60-63 of human ribosomal protein uS3 is crucial for translation initiation.

Conserved ribosomal protein uS3 contains a decapeptide fragment in positions 55-64 (human numbering), which has a very specific ability to cross-link to various RNA derivatives bearing aldehyde groups, likely provided by K62. It has been shown that during translation in the cell-free protein-synthesizing system, uS3 becomes accessible for such cross-linking only after eIF3j leaves the mRNA binding channel of the 40S ribosomal subunit. We studied the functional role of K62 and its nearest neighbors in the ribosomal assembly and translation with the use of HEK293T-derived cell cultures capable of producing FLAG-tagged uS3 (uS3FLAG) or its mutant form with amino acid residues at positions 60-63 replaced with alanines. Analysis of polysome profiles from the respective cells and cytosol lysates showed that the mutation significantly affected the uS3 ability to participate in the assembly of 40S subunits, but it was not essential for their maturation and did not prevent the binding of mRNAs to 40S subunits during translation initiation. The most striking effect of the replacement of amino acid residues in the above uS3 positions was that it almost completely deprived the 40S subunits of their ability to form 80S ribosomes, suggesting that the 48S pre-initiation complexes assembled on these subunits were defective in the binding of 60S subunits. Thus, our results revealed the previously unknown crucial role of the uS3 tetrapeptide 60GEKG63 in translation initiation related to maintaining the proper structure of the 48S complex, most likely via the prevention of premature mRNA loading into the ribosomal channel.

Hydroxylation of protein constituents of the human translation system: structural aspects and functional assignments.

During the current decade, data on the post-translational hydroxylation of specific amino acid residues of some ribosomal proteins and translation factors in both eukaryotes and eubacteria have accumulated. The reaction is catalyzed by dedicated oxygenases (so-called ribosomal oxygenases), whose action is impaired under hypoxia conditions. The modification occurs at amino acid residues directly involved in the formation of the main functional sites of ribosomes and factors. This review summarizes currently available data on the specific hydroxylation of protein constituents of eukaryotic and eubacterial translation systems with a special emphasis on the human system, as well as on the links between hypoxia impacts on the operation of ribosomal oxygenases, the functioning of the translational apparatus and human health problems.

Ribosomal protein eL42 contributes to the catalytic activity of the yeast ribosome at the elongation step of translation.

The GGQ minidomain of the ribosomal protein eL42 was previously shown to contact the CCA-arm of P-site bound tRNA in human ribosome, indicating a possible involvement of the protein in the catalytic activity. Here, using Schizosaccharomyces pombe (S. pombe) cells, we demonstrate that the GGQ minidomain and neighboring region of eL42 is critical for the ribosomal function. Mutant eL42 proteins containing amino acid substitutions within or adjacent to the GGQ minidomain failed to complement the function of wild-type eL42, and expression of the mutant eL42 proteins led to severe growth defects. These results suggest that the mutations in eL42 interfere with the ribosomal function in vivo. Furthermore, we show that some of the mutations associated with the conserved GGQ region lead to reduced activities in the poly(Phe) synthesis and/or in the peptidyl transferase reaction with respect to puromycin, as compared with those of the wild-type ribosomes. A pK value of 6.95 was measured for the side chain of Lys-55/Arg-55, which is considerably less than that of a Lys or Arg residue. Altogether, our findings suggest that eL42 contributes to the 80S ribosome's peptidyl transferase activity by promoting the course of the elongation cycle.