Functional interaction of an arginine conserved in the sixteen amino acid insertion module of Escherichia coli methionyl-tRNA formyltransferase with determinants for formylation in the initiator tRNA

Formylation of initiator methionyl-tRNA by methionyl-tRNA formyltransferase (MTF) is important for initiation of protein synthesis in eubacteria. The determinants for formylation are clustered mostly in the acceptor stem of the initiator tRNA. Previous studies suggested that a 16 amino acid insertion loop, present in all eubacterial MTF's (residues 34-49 in the E. coli enzyme), plays an important role in specific recognition of the initiator tRNA. Here, we have analyzed the effect of site-specific mutations of amino acids within this region. We show that an invariant arginine at position 42 within the loop plays a very important role both in the steps of substrate binding and in catalysis. The kinetic parameters of the R42K and R42L mutant enzymes using acceptor stem mutant initiator tRNAs as substrates suggest that arginine 42 makes functional contacts with the determinants at the 3:70 and possibly also the 2:71 base pairs in the acceptor stem of the initiator tRNA. The kinetic parameters of the G41R/R42L double mutant enzyme are essentially the same as those of R42L mutant, suggesting that the requirement for arginine at position 42 cannot be fulfilled by an arginine at position 41. Along with other data, this result suggests that the insertion loop, which is normally unstructured and flexible, adopts a defined conformation upon binding to the tRNA.     

EF-G-catalyzed translocation of anticodon stem-loop analogs of transfer RNA in the ribosome

Translocation, catalyzed by elongation factor EF-G, is the precise movement of the tRNA-mRNA complex within the ribosome following peptide bond formation. Here we examine the structural requirement for A- and P-site tRNAs in EF-G-catalyzed translocation by substituting anticodon stem-loop (ASL) analogs for the respective tRNAs. Translocation of mRNA and tRNA was monitored independently; mRNA movement was assayed by toeprinting, while tRNA and ASL movement was monitored by hydroxyl radical probing by Fe(II) tethered to the ASLs and by chemical footprinting. Translocation depends on occupancy of both A and P sites by tRNA bound in a mRNA-dependent fashion. The requirement for an A-site tRNA can be satisfied by a 15 nucleotide ASL analog comprising only a 4 base pair (bp) stem and a 7 nucleotide anticodon loop. Translocation of the ASL is both EF-G- and GTP-dependent, and is inhibited by the translocational inhibitor thiostrepton. These findings show that the D, T and acceptor stem regions of A-site tRNA are not essential for EF-G-dependent translocation. In contrast, no translocation occurs if the P-site tRNA is substituted with an ASL, indicating that other elements of P-site tRNA structure are required for translocation. We also tested the effect of increasing the A-site ASL stem length from 4 to 33 bp on translocation from A to P site. Translocation efficiency decreases as the ASL stem extends beyond 22 bp, corresponding approximately to the maximum dimension of tRNA along the anticodon-D arm axis. This result suggests that a structural feature of the ribosome between the A and P sites, interferes with movement of tRNA analogs that exceed the normal dimensions of the coaxial tRNA anticodon-D arm.     

Induced fit of a peptide loop of methionyl-tRNA formyltransferase triggered by the initiator tRNA substrate

A 16-aa insertion loop present in eubacterial methionyl-tRNA formyltransferases (MTF) is critical for specific recognition of the initiator tRNA in Escherichia coli. We have studied the interactions between this region of the E. coli enzyme and initiator methionyl-tRNA (Met-tRNA) by using two complementary protection experiments: protection of MTF against proteolytic cleavage by tRNA and protection of tRNA against nucleolytic cleavage by MTF. The insertion loop in MTF is uniquely sensitive to cleavage by trypsin. We show that the substrate initiator Met-tRNA protects MTF against trypsin cleavage, whereas a formylation-defective mutant initiator Met-tRNA, which binds to MTF with approximately the same affinity, does not. Also, mutants of MTF within the insertion loop (which are defective in formylation) are not protected by the initiator Met-tRNA. Thus, a functional enzyme-substrate complex is necessary for protection of MTF against trypsin cleavage. Along with other data, these results strongly suggest that a segment of the insertion loop, which is exposed and unstructured in MTF, undergoes an induced fit in the functional MTF.Met-tRNA complex but not in the nonfunctional one. Footprinting experiments show that MTF specifically protects the acceptor stem and the 3'-end region of the initiator Met-tRNA against cleavage by double and single strand-specific nucleases. This protection also depends on formation of a functional MTF.Met-tRNA complex. Thus, the insertion loop interacts mostly with the acceptor stem of the initiator Met-tRNA, which contains the critical determinants for formylation.     

Glutaminyl-tRNA synthetase

Among the twenty aminoacyl-tRNA synthetases glutaminyl-tRNA synthetase occupies a special position: it is one of only two enzymes of this family which is not found in all organisms, being mainly absent from gram positive eubacteria, archaebacteria and organelles. The E. coli GlnRS is relatively small with 553 amino acids and a molecular mass of 64.4 kDa and functions as a monomer. The mammalian enzymes are somewhat larger and can be parts of multienzyme complexes. Crystal structures were solved of E. coli GlnRS complexed with tRNA(Gln) and ATP, of this complex containing tRNA(Gln) replaced by unmodified tRNA(Gln), and of three complexes with mutated GlnRS enzymes. The GlnRS molecule consists of four domains, the catalytic site is located in the Rossman fold, typical for class I synthetases, and the reaction mechanism follows the normal adenylate pathway. The enzyme shows many similarities with glutamyl-tRNA synthetase; a common ancestor of both molecules is well established. In the E. coli system recognition of the cognate tRNA has been studied in many details using both natural and artificial mutants of tRNA(Gln) and of the enzyme: GlnRS recognizes mainly conventional parts of the tRNA molecule, namely some bases of the anticodon loop and parts of the acceptor stem.     

Identification of specific Rp-phosphate oxygens in the tRNA anticodon loop required for ribosomal P-site binding

tRNA binding to the ribosomal P site is dependent not only on correct codon-anticodon interaction but also involves identification of structural elements of tRNA by the ribosome. By using a phosphorothioate substitution-interference approach, we identified specific nonbridging Rp-phosphate oxygens in the anticodon loop of tRNA(Phe) from Escherichia coli which are required for P-site binding. Stereospecific involvement of phosphate oxygens at these positions was confirmed by using synthetic anticodon arm analogues at which single Rp- or Sp-phosphorothioates were incorporated. Identical interference results with yeast tRNA(Phe) and E. coli tRNA(fMet) indicate a common backbone conformation or common recognition elements in the anticodon loop of tRNAs. N-ethyl-N-nitrosourea modification-interference experiments with natural tRNAs point to the importance of the same phosphates in the loop. Guided by the crystal structure of tRNA(Phe), we propose that specific Rp-phosphate oxygens are required for anticodon loop ("U-turn") stabilization or are involved in interactions with the ribosome on correct tRNA-mRNA complex formation.     

Expression of bovine mitochondrial tRNASer GCU derivatives in Escherichia coli

By replacing a stretch of five A-U base pairs in the acceptor stem with G-C pairs, mitochondrial tRNA-SerGCU lacking a D arm could be expressed in Escherichia coli cells in considerable amounts. The expressed tRNA with no modified nucleoside was serylated in vitro with the mitochondrial enzyme. The tRNASerGCU derivatives carrying identity elements for alanine tRNA and the related anticodons were expressed. However, this expression event did not affect cell growth, probably because the expression started from the late log phase, which suggests that these mitochondrial tRNA derivatives are not involved in E.coli gene expression systems. Although there are some restrictions in the secondary structure of tRNAs that can be expressed by this method, it could prove useful for preparing large amounts of heterologous tRNAs in vivo.     

Mutations in the conserved P loop perturb the conformation of two structural elements in the peptidyl transferase center of 23 S ribosomal RNA

Evidence is presented for the participation of the P loop (nucleotides G2250-C2254) of 23 S rRNA in establishing the tertiary structure of the peptidyl transferase center. Single base substitutions were introduced into the P loop, which participates in peptide bond formation through direct interaction with the CCA end of P site-bound tRNA. These mutations altered the pattern of reactivity of RNA to chemical probes in a structural subdomain encompassing the P loop and extending roughly from G2238 to A2433. Most of the effects on chemical modification in the P loop subdomain occurred near sites of tertiary interactions inferred from comparative sequence analysis, indicating that these mutations perturb the tertiary structure of this region of RNA. Changes in chemical modification were also seen in a subdomain composed of the 2530 loop (nucleotides G2529-A2534) and the A loop (nucleotides U2552-C2556), the latter a site of interaction with the CCA end of A site-bound tRNA. Mutations in the P loop induced effects on chemical modification that were commensurate with the severity of their characterized functional defects in peptide bond formation, tRNA binding and translational fidelity. These results indicate that, in addition to its direct role in peptide bond formation, the P loop contributes to the tertiary structure of the peptidyl transferase center and influences the conformation of both the acceptor and peptidyl tRNA binding sites.     

Functional replacement of hamster lysyl-tRNA synthetase by the yeast enzyme requires cognate amino acid sequences for proper tRNA recognition

We cloned the cDNA encoding a 597-aa hamster lysyl-tRNA synthetase. This enzyme is a close homologue of the 591-aa Saccharomyces cerevisiae enzyme, with the noticeable exception of their 60-aa N-terminal regions, which differ significantly. Several particular features of this polypeptide fragment from the hamster lysyl-tRNA synthetase suggest that it is implicated in the assembly of that enzyme within the multisynthetase complex. However, we show that this protein domain is dispensable in vivo to sustain growth of CHO cells. The cross-species complementation was investigated in the lysine system. The mammalian enzyme functionally replaces a null-allele of the yeast KRS1 gene. Conversely, the yeast enzyme cannot rescue Lys-101 cells, a CHO cell line with a temperature-sensitive lysyl-tRNA synthetase. The yeast and mammalian enzymes, overexpressed in yeast, were purified to homogeneity. The hamster lysyl-tRNA synthetase efficiently aminoacylates both mammalian and yeast tRNA(Lys), whereas the yeast enzyme aminoacylates mammalian tRNA(Lys) with a catalytic efficiency 20-fold lower, as compared to its cognate tRNA. The 152-aa C-terminus extremity of the hamster enzyme provides the yeast enzyme with the capacity to complement Lys-101 cells. This hybrid protein is fairly stable and aminoacylates both yeast and mammalian tRNA(Lys) with similar catalytic efficiencies. Because this C-terminal polypeptide fragment is likely to make contacts with the acceptor stem of tRNA(Lys), we conclude that it should carry the protein determinants conferring specific recognition of the cognate tRNA acceptor stem and therefore contributes an essential role in the operational RNA code for amino acids.     

Topography of the E site on the Escherichia coli ribosome

Three photoreactive tRNA probes have been utilized in order to identify ribosomal components that are in contact with the aminoacyl acceptor end and the anticodon loop of tRNA bound to the E site of Escherichia coli ribosomes. Two of the probes were derivatives of E. coli tRNA(Phe) in which adenosines at positions 73 and 76 were replaced by 2-azidoadenosine. The third probe was derived from yeast tRNA(Phe) by substituting wyosine at position 37 with 2-azidoadenosine. Despite the modifications, all of the photoreactive tRNA species were able to bind to the E site of E. coli ribosomes programmed with poly(A) and, upon irradiation, formed covalent adducts with the ribosomal subunits. The tRNA(Phe) probes modified at or near the 3' terminus exclusively labeled protein L33 in the 50S subunit. The tRNA(Phe) derivative containing 2-azidoadenosine within the anticodon loop became cross-linked to protein S11 as well as to a segment of the 16S rRNA encompassing the 3'-terminal 30 nucleotides. We have located the two extremities of the E site-bound tRNA on the ribosomal subunits according to the positions of L33, S11 and the 3' end of 16S rRNA defined by immune electron microscopy. Our results demonstrate conclusively that the E site is topographically distinct from either the P site or the A site, and that it is located alongside the P site as expected for the tRNA exit site.     

CCA addition by tRNA nucleotidyltransferase: polymerization without translocation?

The CCA-adding enzyme repairs the 3'-terminal CCA sequence of all tRNAs. To determine how the enzyme recognizes tRNA, we probed critical contacts between tRNA substrates and the archaeal Sulfolobus shibatae class I and the eubacterial Escherichia coli class II CCA-adding enzymes. Both CTP addition to tRNA-C and ATP addition to tRNA-CC were dramatically inhibited by alkylation of the same tRNA phosphates in the acceptor stem and TPsiC stem-loop. Both enzymes also protected the same tRNA phosphates in tRNA-C and tRNA-CC. Thus the tRNA substrate must remain fixed on the enzyme surface during CA addition. Indeed, tRNA-C cross-linked to the S. shibatae enzyme remains fully active for addition of CTP and ATP. We propose that the growing 3'-terminus of the tRNA progressively refolds to allow the solitary active site to reuse a single CTP binding site. The ATP binding site would then be created collaboratively by the refolded CC terminus and the enzyme, and nucleotide addition would cease when the nucleotide binding pocket is full. The template for CCA addition would be a dynamic ribonucleoprotein structure.     

Ribosome-catalyzed peptide-bond formation with an A-site substrate covalently linked to 23S ribosomal RNA

In the ribosome, the aminoacyl-transfer RNA (tRNA) analog 4-thio-dT-p-C-p-puromycin crosslinks photochemically with G2553 of 23S ribosomal RNA (rRNA). This covalently linked substrate reacts with a peptidyl-tRNA analog to form a peptide bond in a peptidyl transferase-catalyzed reaction. This result places the conserved 2555 loop of 23S rRNA at the peptidyl transferase A site and suggests that peptide bond formation can occur uncoupled from movement of the A-site tRNA. Crosslink formation depends on occupancy of the P site by a tRNA carrying an intact CCA acceptor end, indicating that peptidyl-tRNA, directly or indirectly, helps to create the peptidyl transferase A site.     

tRNA anticodon recognition and specification within subclass IIb aminoacyl-tRNA synthetases

Subclass IIb aminoacyl-tRNA synthetases (Asn-, Asp- and LysRS) recognize the anticodon triplet of their cognate tRNA (GUU, GUC and UUU, respectively) through an OB-folded N-terminal extension. In the present study, the specificity of constitutive lysyl-tRNA synthetase (LysS) from Escherichia coli was analyzed by cross-mutagenesis of the tRNA(Lys) anticodon, on the one hand, and of the amino acid residues composing the anticodon binding site on the other. From this analysis, a tentative model is deduced for both the recognition of the cognate anticodon and the rejection of non-cognate anticodons. In this model, the enzyme offers a rigid scaffold of amino acid residues along the beta-strands of the OB-fold for tRNA binding. Phe85 and Gln96 play a critical role in this spatial organization. This scaffold can recognize directly U35 at the center of the anticodon. Specification of the correct enzyme:tRNA complex is further achieved through the accommodation of U34 and U36. The binding of these bases triggers the conformationnal change of a flexible seven-residue loop between strands 4 and 5 of the OB-fold (L45). Additional free energy of binding is recovered from the resulting network of cooperative interactions. Such a mechanism would not depend on the modifications of the anticodon loop of tRNA(Lys) (mnm5s2U34 and t6A37). In the model, exclusion by the synthetase of non-cognate anticodons can be accounted for by a hindrance to the positioning of the L45 loop. In addition, Glu135 would repulse a cytosine base at position 35. Sequence comparisons show that the composition and length of the L45 loop are markedly conserved in each of the families composing subclass IIb aminoacyl-tRNA synthetases. The possible role of the loop is discussed for each case, including that of archaebacterial aspartyl-tRNA synthetases.     

A conserved aspartate of tRNA pseudouridine synthase is essential for activity and a probable nucleophilic catalyst

tRNA pseudouridine synthase I catalyzes the conversion of uridine to pseudouridine at positions 38, 39, and/or 40 in the anticodon loop of many tRNAs. Pseudouridine synthase I was cloned behind a T7 promoter and expressed in Escherichia coli to about 20% of total soluble proteins. Fluorouracil-substituted tRNA caused a time-dependent inactivation of pseudouridine synthase I and formed a covalent complex with the enzyme that involved the FUMP at position 39. Asp60, conserved in all known and putative pseudouridine synthases, was mutated to amino acids with diverse side chains. All Asp60 mutants bound tRNA but were catalytically inactive and failed to form covalent complexes with fluorouracil-substituted tRNA. We conclude that the conserved Asp60 is essential for pseudouridine synthase activity and propose mechanisms which involve this residue in important catalytic roles.     

Interaction of structural modules in substrate binding by the ribozyme from Bacillus subtilis RNase P

The ribozyme from bacterial ribonuclease P recognizes two structural modules in a tRNA substrate: the T stem-loop and the acceptor stem. These two modules are connected through a helical linker. The T stem-loop binds at a surface confined in a folding domain away from the active site. Substrates for the Bacillus subtilis RNase P RNA were previously selected in vitro that are shown to bind comparably well or better than a tRNA substrate. Chemical modification of P RNA-substrate complexes with dimethylsulfate and kethoxal was performed to determine how the P RNA recognizes three in vitro selected substrates. All three substrates bind at the surface known to interact with the T stem-loop of tRNA. Similar to a tRNA, the secondary structure of these substrates contains a helix around the cleavage site and a hairpin loop at the corresponding position of the T stem-loop. Unlike a tRNA, these two structural modules are connected through a non-helical linker. The two structural modules in the tRNA and in the selected substrates bind to two different domains in P RNA. The properties of substrate recognition exhibited by this ribozyme may be exploited to isolate new ribozyme-substrate pairs with interactive structural modules.     

Large-scale isolation of tRNA from barley embryos

1. Large-scale isolation of tRNA from barley embryos is described, involving: phenol extraction, RNA deproteinization with the chloroform-isoamyl alcohol mixture, batch sorption on DEAE-cellulose, NaCl gradient elution of tRNA from DEAE-cellulose, and deaminoacylation of tRNA in the presence of bentonite. The procedure yielded tRNA free of protein and RNase activity. 2. The amino acid acceptor activity of the crude barley tRNA, its melting profiles and chromatographic patterns on Sephadex G-100 and BD-cellulose were similar to those of tRNA from other sources.     

RNA-RNA interactions between oligonucleotide substrates for aminoacylation

RNA stem-loop microhelices with helix sequences based on tRNA acceptor stems can be charged with specific amino acids. Experiments were designed to test the possibility that microhelices could laterally associate through complementary loop sequences and thereby bring their attached aminoacyl groups close enough together to form a peptide bond. Computer simulations suggested that formation of such complexes would be sensitive to the number of loop nucleotides needed to span the grooves of the quasi-continuous helix of the intermolecular pseudoknot so formed. These predictions were conformed experimentally by observation of complex formation sensitivity to loop size. Complexes with optimized loop sizes had apparent bimolecular dissociation constants of approximately 100 nM with only three complementary base pairs between the respective loops. Single nucleotide substitutions that disrupted the predicted intermolecular loop-loop base-pairing abolished detectable association. Similarly, placing a gap between the short helix formed by loop-loop pairing and the adjacent acceptor stems also diminished complex formation. These experiments establish an experimental basis for microhelix association for peptide synthesis.