End Of tRNA Research Articles

Multiple magnesium ions in the ribonuclease P reaction mechanism.

The ribozyme ribonuclease (RNase) P cleaves precursor transcripts to produce the mature 5'-end of tRNAs. This hydrolysis reaction has a divalent cation requirement that is primarily catalytic, rather than structural; RNase P can be considered a metalloenzyme. Kinetic analysis shows that the RNase P catalytic mechanism has a cooperative dependence upon Mg2+ concentration. At least three Mg2+ ions are required for optimal activity, suggesting a multiple metal ion mechanism. The 2'-OH at the site of substrate cleavage may act as a ligand for a catalytically important Mg2+: deoxyribose substitution reduces the apparent number of Mg2+ bound from three to two and increases the apparent dissociation constant for Mg2+ from the micromolar to the millimolar range. In addition to these cation effects, the deoxyribose substitution reduces the rate of catalysis by 3400-fold; substitution with 2'-O-methyl at the cleavage site reduces the catalytic rate 10(6)-fold. If we presume no significant conformational effects of the substitutions, these results suggest that the 2'-OH serves as hydrogen-bond donor. The kinetic analysis of the catalytic mechanism is based upon the characterization of the pH dependence of the reaction. There is a hyperbolic (saturable) dependence on hydroxide concentration, with the half-maximal rate achieved at pH 8.0-8.5. The rate of the cleavage step is about 200 min-1 at pH 8.0, which is 500-fold faster than the steady-state parameter kcat.

Substitution of the 3' terminal adenosine residue of transfer RNA in vivo.

We have altered by site-directed mutagenesis the 3' terminal adenosine residue of a tRNA(Tyrsu3+) gene encoded on a single-copy plasmid and examined the consequences of these substitutions on suppressor activity in vivo. Our data show that mutant su3 genes containing 3'-CCC, -CCG, or -CCU termini instead of -CCA can be efficiently transcribed and processed in Escherichia coli to generate functional suppressor tRNAs. However, in contrast to normal tRNA genes, both tRNA nucleotidyltransferase and exoribonuclease activities are required to obtain suppression by the mutant tRNAs, indicating that removal of the incorrect 3' terminal residue and resynthesis of the normal -CCA terminus are occurring in this situation. In addition, a low level of suppressor activity and tRNA repair was found in cells devoid of tRNA nucleotidyltransferase, suggesting that an additional activity able to partially repair the 3' end of tRNA is present in E. coli. The use of mutant strains lacking one or several exoribonucleases revealed that the various RNAses have very different specificities for removal of incorrect 3' residues and that these differ greatly from their action on CCA-ending tRNA. These data show that the 3' terminal adenosine residue is necessary for tRNA function in vivo and that cells can compensate for its alteration by changes in the normal pathway of tRNA metabolism.

TRNA-rRNA interactions and peptidyl transferase.

The extent to which ribosomal RNA is directly involved in the function of ribosomes has important implications for both the mechanism of translation and the molecular origins of life. Detailed evidence has accumulated that places the anticodon and acceptor ends of tRNA in close proximity to conserved features of rRNA in the ribosome. Recent studies are providing evidence that these features are important for ribosomal function.

Reverse transcriptase of human immunodeficiency virus can use either human tRNA(3Lys) or Escherichia coli tRNA(2Gln) as a primer in an in vitro primer-utilization assay.

Although the reverse transcriptase (RT) of human immunodeficiency virus (HIV) uses human tRNA(3Lys) as a primer of viral genome DNA synthesis in vivo, HIV RT binds Escherichia coli glutamine tRNA and in vitro-made human lysine tRNA with nearly equivalent affinities. We show that HIV RT can use either tRNA(3Lys) or tRNA(2Gln) as a primer for DNA synthesis in vitro without the addition of any other host or viral proteins. E. coli tRNA(2Gln) can serve as a primer for HIV RT if a primer-binding site sequence complementary to the 3' end of tRNA(2Gln) is at the 3' end of the template. With this reduced template, the specificity of binding the proper tRNA is due to base-pairing between a bound tRNA to the primer-binding site of the viral RNA template rather than sequence-specific recognition of tRNA(3Lys) by RT. If an 8-nucleotide viral sequence 3' to the primer-binding site is included in the template, then addition of Zn2+ or Co2+ is required for tRNA(3Lys)-primed synthesis, and tRNA(2Gln) now fails to prime synthesis. The latter result implies that a template sequence adjacent to the primer-binding site and containing 6 nucleotides complementary to the anticodon loop of human tRNA(3Lys) plays an active role in tRNA discrimination.

TRNA‐like structures

The structurally and functionally best known RNA molecule is undoubtedly transfer RNA (tRNA). tRNA owes its name to the central role it performs in protein biosynthesis: it mediates the transfer of amino acids to the ribosome. In this process the amino acid is bound to the 3′-CCA end of tRNA by an aminoacyl-tRNA synthetase. The charged tRNA forms additionally a ternary complex with GTP and an elongation factor, like the prokaryotic EF-Tu or the eukaryotic EF-1α. This complex enters the ribosome, where tRNA with its an-ticodon interacts specifically with one of the codon triplets of the messenger RNA (mRNA). Subsequently, the amino acid is covalently bound to the C-terminus of a growing polypeptide chain. This short description of protein biosynthesis reveals that tRNA interacts with many components of this process. To understand these interactions at the molecular level is the main objective of many studies of molecular biologists.

Class II Aminoacyl Transfer Rna Synthetases: Crystal Structure of Yeast Aspartyl-trna Synthetase Complexed with tRNA Asp

The crystal structure of the binary complex tRNA(Asp)-aspartyl tRNA synthetase from yeast was solved with the use of multiple isomorphous replacement to 3 angstrom resolution. The dimeric synthetase, a member of class II aminoacyl tRNA synthetases (aaRS's) exhibits the characteristic signature motifs conserved in eight aaRS's. These three sequence motifs are contained in the catalytic site domain, built around an antiparallel beta sheet, and flanked by three alpha helices that form the pocket in which adenosine triphosphate (ATP) and the CCA end of tRNA bind. The tRNA(Asp) molecule approaches the synthetase from the variable loop side. The two major contact areas are with the acceptor end and the anticodon stem and loop. In both sites the protein interacts with the tRNA from the major groove side. The correlation between aaRS class II and the initial site of aminoacylation at 3'-OH can be explained by the structure. The molecular association leads to the following features: (i) the backbone of the GCCA single-stranded portion of the acceptor end exhibits a regular helical conformation; (ii) the loop between residues 320 and 342 in motif 2 interacts with the acceptor stem in the major groove and is in contact with the discriminator base G and the first base pair UA; and (iii) the anticodon loop undergoes a large conformational change in order to bind the protein. The conformation of the tRNA molecule in the complex is dictated more by the interaction with the protein than by its own sequence.

Sites of interaction of the CCA end of peptidyl-tRNA with 23S rRNA.

Oligonucleotide fragments derived from the 3' CCA terminus of acylated tRNA, such as CACCA-(AcPhe), UACCA-(AcLeu), and CAACCA-(fMet), bind specifically to ribosomes in the presence of sparsomycin and methanol [Monro, R. E., Celma, M. L. & Vazquez, D. (1969) Nature (London) 222, 356-358]. All three oligonucleotides protect a characteristic set of bases in 23S rRNA from chemical probes: G2252, G2253, A2439, A2451, U2506, and U2585. A2602 shows enhanced reactivity. These account for most of the same bases that are protected when peptidyl-tRNA analogues such as AcPhe-tRNA are bound to the ribosomal P site, and correspond precisely to those bases whose protection is abolished by removal of the 3'-CA end of tRNA. We conclude that most of the observed interactions between tRNA and 23S rRNA in the 50S ribosomal P site involve the conserved CCA terminus of tRNA. Sparsomycin may inhibit protein synthesis by stabilizing interaction between the peptidyl-CCA and the 23S P site, preventing formation of the intermediate A/P hybrid state.

Interaction of the tRNAPhe acceptor end with the synthetase involves a sequence common to yeast and Escherichia coli phenylalanyl-tRNA synthetases

Modified lysines resulting from the cross-linking of the 3' end of tRNA(Phe) to yeast phenylalanyl-tRNA synthetase (an enzyme with an alpha 2 beta 2 structure) have been characterized by sequencing the labeled chymotryptic peptides that were isolated by means of gel filtration and reversed-phase chromatography. The analysis showed that Lys131 and Lys436 in the alpha subunit are the target sites of periodate-oxidized tRNA(Phe). Mutant protein with a Lys----Asn substitution established that each lysine contributes to the binding of the tRNA but is not essential for catalysis. The major labeled lysine (K131) belongs to the sequence IALQDKL (residues 126-132), which shares three identities with the peptide sequence ADKL found around the tRNAox-labeled Lys61 in the large subunit of Escherichia coli phenylalanyl-tRNA synthetase [Hountondji, C., Schmitter, J. M., Beauvallet, C., & Blanquet, S. (1987) Biochemistry 26, 5433-5439].

RNase T affects Escherichia coli growth and recovery from metabolic stress

To determine the essentiality and role of RNase T in RNA metabolism, we constructed an Escherichia coli chromosomal rnt::kan mutation by using gene replacement with a disrupted, plasmid-borne copy of the rnt gene. Cell extracts of a strain with mutations in RNases BN, D, II, and I and an interuppted rnt gene were devoid of RNase T activity, although they retained a low level (less than 10%) of exonucleolytic activity on tRNA-C-C-[14C]A due to two other unidentified RNases. A mutant lacking tRNA nucleotidyltransferase in addition to the aforementioned RNases accumulated only about 5% as much defective tRNA as did RNase T-positive cells, indicating that this RNase is responsible for essentially all tRNA end turnover in E. coli. tRNA from rnt::kan strains displayed a slightly reduced capacity to be aminoacylated, raising the possibility that RNase T may also participate in tRNA processing. Strains devoid of RNase T displayed slower growth rates than did the wild type, and this phenotype was accentuated by the absence of the other exoribonucleases. A strain lacking RNase T and other RNases displayed a normal response to UV irradiation and to the growth of bacteriophages but was severely affected in its ability to recover from a starvation regimen. The data demonstrate that the absence of RNase T affects the normal functioning of E. coli, but it can be compensated for to some degree by the presence of other RNases. Possible roles of RNase T in RNA metabolism are discussed.

RNase P RNA inCandida glabratamitochondria is transcribed with substrate tRNAs

The biosynthesis of some mitochondrial enzymes requires contributions of both the mitochondrial and nuclear genomes. The ribonucleoprotein enzyme Ribonuclease P (RNase P) is composed of a mitochondrial encoded RNA and nuclear coded protein in many yeasts, including C. glabrata. We have determined that there are at least two sites of transcription initiation that contribute to the expression of the mitochondrial RNase P RNA. A nonanucleotide promoter sequence is located upstream of the initiator tRNA while the other site of initiation of transcription is at an undetermined upstream site. An analysis of the transcripts from the region of the RNase P gene demonstrates directly that the RNase P RNA is present in large primary transcripts and located between the precursors to the initiator tRNAf(Met) and tRNA(Pro) genes. Thus this enzyme subunit is synthesized with some of its substrate tRNAs. An activity with cleavage site specificity like a previously described endonuclease that cleaves near the 3' end of tRNAs, RNase P activity and one or more additional endonucleases or exonucleases not described previously are required to convert the primary transcript to its final functional RNAs.

Movement of tRNA but not the nascent peptide during peptide bond formation on ribosomes

The results from experiments involving nonradiative energy transfer indicate that a fluorescent probe on the 5'-end of tRNA(Phe) moves more than 20 A towards probes on ribosomal protein L1 as a peptide bond is formed during the peptidyl transferase reaction on Escherichia coli ribosomes. The peptide itself moves no more than a few angstroms during peptide bond formation, as judged by the movement of fluorescent probes attached to the phenylalanine amino group of phenylalanyl-tRNA. Other results demonstrate that an analogue of peptidyl-tRNA, deacylated tRNA, and puromycin can be bound simultaneously to the same ribosome, indicating that there are three physically distinct sites to which tRNA is bound during the reaction steps by which peptides are elongated. The results appear to be consistent with the displacement model of peptide elongation.

Nucleotides that determine Escherichia coli tRNA(Arg) and tRNA(Lys) acceptor identities revealed by analyses of mutant opal and amber suppressor tRNAs.

We have constructed an opal suppressor system in Escherichia coli to complement an existing amber suppressor system to study the structural basis of tRNA acceptor identity, particularly the role of middle anticodon nucleotide at position 35. The opal suppressor tRNA contains a UCA anticodon and the mRNA of the suppressed protein (which is easily purified and sequenced) contains a UGA nonsense triplet. Opal suppressor tRNAs of two tRNA(Arg) isoacceptor sequences each gave arginine in the suppressed protein, while the corresponding amber suppressors with U35 in their CUA anticodons each gave arginine plus a second amino acid in the suppressed protein. Since C35 but not U35 is present in the anticodon of wild-type tRNA(Arg) molecules, while the first anticodon position contains either C34 or U34, these results establish that C35 contributes to tRNA(Arg) acceptor identity. Initial characterizations of opal suppressor tRNA(Arg) mutants by suppression efficiency measurements suggest that the fourth nucleotide from the 3' end of tRNA(Arg) (A73 or G73 in different isoacceptors) also contributes to tRNA(Arg) acceptor identity. Wild-type and mutant versions of opal and amber tRNA(Lys) suppressors were examined, revealing that U35 and A73 are important determinants of tRNA(Lys) acceptor identity. Several possibilities are discussed for the general significance of having tRNA acceptor identity in the same positions in different tRNA acceptor types, as exemplified by positions 35 and 73 in tRNA(Arg) and tRNA(Lys).

Mutant of the glutamine transfer RNA gene as UGA suppressor in Escherichia coli

A UGA suppressor derived from a glutamine tRNA gene of Escherichia coli K12 was isolated and characterized. Phages carrying the suppressor su+2UGA could be obtained only from a hybrid transducing phage, h80cI857psu+2oc, but not from the original transducing phage lambda cI857psu+2oc. By DNA sequence analysis, it was found that the su+2 UGA suppressor obtained has two mutations; one is in the anticodon (TTA----TCA), as expected, and the other (C----T) is at the 7th position from the 3' end of tRNA(2Gln). The significance of these mutations and the lethal effect on phage lambda of the increased amounts of UGA suppressor tRNAs are discussed.

A highly repetitive and transcribable sequence in the tortoise genome is probably a retroposon

On in vitro transcription of total genomic DNA of the tortoise (Geoclemys reevessi), a discrete-sized RNA of 6.5S was obtained that represented a highly repetitive and transcribable sequence in the tortoise genome. Three sequences of the 6.5S RNA gene were sequenced, and a consensus sequence was deduced from these three sequences and one reported previously [Endoh, H & Okada, N. (1986) Proc. Natl Acad. Sci. USA 83, 251-255]. The 5' part of the gene showed close similaries to lysine (rabbit) and threonine (mouse) tRNAs (overall similarity 68-70%), so this tortoise sequence may have evolved from one of these tRNAs. The consensus sequence retained the expected CCA triplet at the 3' end of tRNA, but not at the 3' end of tDNA, supporting the idea that the tRNA-related region of the gene was generated via an RNA intermediate. The 5' and 3' flanking sequences of the four genes were found to be completely different from each other. Fingerprint analysis and S1 nuclease mapping analysis also showed that sequence boundaries of tortoise repetitive units exactly corresponded to RNA species. These results, together with data obtained by Southern blot hybridization, indicated that the 6.5S RNA genes are dispersed in the tortoise genome. Therefore, generation of the tRNA-related region of the gene and amplification of the whole unit of the gene are both RNA-mediated events. The existence of this tortoise sequence suggests that short interspersed sequences are more common in eukaryotic genomes than had previously been thought.

Conversion of aminoacylation specificity from tRNATyrto tRNASerin vitro

The discrimination mechanism between tRNA(Ser) and tRNA(Tyr) was studied using various in vitro transcripts of E. coli tRNATyr variants. The insertion of only two nucleotides into the variable stem of tRNA(Tyr) generates serine charging activity. The acceptor activities of some of the tRNA(Tyr) mutants with insertions in the long variable arm were enhanced by changes in nucleotides at positions 9 and/or 20B, which are possible elements for dictating the orientation of the long variable arm. These findings suggest that the long variable arm is involved in recognition by seryl-tRNA synthetase in spite of sequence and length variations shown within tRNA(Ser) isoacceptors, and eventually serves as a determinant for selection from other tRNA species. Changing the anticodon from GUA to the serine anticodon GGA resulted in a marked decrease in tyrosine charging activity, but this mutant did not show any serine charging activity. The discriminator base, the fourth base from the 3' end of tRNA, was also important for aminoacylation with tyrosine. Complete specificity change in vitro was facilitated by insertion of three nucleotides into the variable arm plus two nucleotide changes at positions 9 and 73.

Intermediate states in the movement of transfer RNA in the ribosome.

Direct chemical 'footprinting' shows that translocation of transfer RNA occurs in two discrete steps. During the first step, which occurs spontaneously after the formation of the peptide bond, the acceptor end of tRNA moves relative to the large ribosomal subunit resulting in 'hybrid states' of binding. During the second step, which is promoted by elongation factor EF-G, the anticodon end of tRNA, along with the messenger RNA, moves relative to the small ribosomal subunit.

Recognition of tRNA by the Enzyme ATP/CTP:tRNA Nucleotidyltransferase: Interference by Nucleotides Modified with Diethyl Pyrocarbonate or Hydrazine

Abstract Treatment of tRNA with diethyl pyrocarbonate or hydrazine prior to incubation with the enzyme ATP/CTP:tRNA nucleotidyltransferase and [alpha-32P]ATP results in exclusion of modified bases from labeled molecules. Purines modified with diethyl pyrocarbonate, which interfere with enzyme recognition, cluster at the corner of the tRNA molecule, where the D- and psi-loops are juxtaposed in all 15 tRNAs used in this study. When the enzyme is isolated from Escherichia coli, few other sites of interference are evident near the 3'-end; when the homologous enzyme from yeast is used, more exclusions are apparent near the 3'-end. Modification of uridines with hydrazine has no effect on interaction with the enzyme, except for one uridine near the 3'-end of tRNA(Gly). Interference of enzyme activity by modified bases can be overcome by longer incubation times or increased concentrations of enzyme.

Photochemical cross-linking of yeast tRNA(Phe) containing 8-azidoadenosine at positions 73 and 76 to the Escherichia coli ribosome.

The 3'-terminal -A-C-C-A sequence of yeast tRNA(Phe) has been modified by replacing either adenosine-73 or adenosine-76 with the photoreactive analogue 8-azidoadenosine (8N3A). The incorporation of 8N3A into tRNA(Phe) was accomplished by ligation of 8-azidoadenosine 3',5'-bisphosphate to the 3' end of tRNA molecules which were shortened by either one or four nucleotides. Replacement of the 3'-terminal A76 with 8N3A completely blocked aminoacylation of the tRNA. In contrast, the replacement of A73 with 8N3A has virtually no effect on the aminoacylation of tRNA(Phe). Neither substitution hindered binding of the modified tRNAs to Escherichia coli ribosomes in the presence of poly(U). Photoreactive tRNA derivatives bound noncovalently to the ribosomal P site were cross-linked to the 50S subunit upon irradiation at 300 nm. Nonaminoacylated tRNA(Phe) containing 8N3A at either position 73 or position 76 cross-linked exclusively to protein L27. When N-acetylphenylalanyl-tRNA(Phe) containing 8N3A at position 73 was bound to the P site and irradiated, 23S rRNA was the main ribosomal component labeled, while smaller amounts of the tRNA were cross-linked to proteins L27 and L2. Differences in the labeling pattern of nonaminoacylated and aminoacylated tRNA(Phe) containing 8N3A in position 73 suggest that the aminoacyl moiety may play an important role in the proper positioning of the 3' end of tRNA in the ribosomal P site. More generally, the results demonstrate the utility of 8N3A-substituted tRNA probes for the specific labeling of ribosomal components at the peptidyltransferase center.

Fluorimetric distance determination by resonance energy transfer. Ribosome-bound transfer RNA.

Using the technique of singlet-singlet (Förster-type) resonance energy transfer, we have determined five distances in the programmed ribosome, either with the P site or with both the A and the P sites occupied. Two of the distances are new and two agree with earlier measurements; the fifth showed disagreement in detail with earlier results of others, but a consistent general trend. The distances substantiate a current model for the location of ribosomally bound tRNA, except in regard of the position of the 3' end of P-site tRNA, which seems according to our results to lie too far away from the 3' terminus of the 16 S RNA to be accommodated in the model. We present new evidence for the hypothesis that anomalously charged tRNA does not bind to the cognately programmed A site in the same way as does tRNA charged with an amino acid. Occupation of the A site restricts mobility of the 3' end of tRNA in the P site.

Structure of the yeast valyl-tRNA synthetase gene (VASI) and the homology of its translated amino acid sequence with Escherichia coli isoleucyl-tRNA synthetase.

The VASI gene encoding the valyl-tRNA synthetase from yeast was isolated and sequenced. The gene-derived amino acid sequence of yeast valyl-tRNA synthetase was found to be 23% homologous to the Escherichia coli isoleucyl-tRNA synthetase. This is the highest level of homology reported so far between two distinct aminoacyl-tRNA synthetases and is indicative of an evolutionary relationship between these two molecules. Within these homologous sequences, two functional regions could be recognized: the HIGH region which forms part of the binding site of ATP and the KMSKS region which is recognized as the consensus sequence for the binding of the 3'-end of tRNA (Hountondji, C., Dessen, Ph., and Blanquet, S. (1986) Biochemie (Paris) 68, 1071-1078). Secondary structure predictions as well as the presence of both HIGH and KMSKS regions, delineating the nucleotide-binding domain and the COOH-terminal helical domain in aminoacyl-tRNA synthetases of known three-dimensional structure, suggest that the yeast valyl-tRNA synthetase polypeptide chain can be folded into three domains: an NH2-terminal alpha-helical region followed by a nucleotide-binding topology and a COOH-terminal domain composed of alpha-helices which probably carries major sites in tRNA binding.