Cloning and characterization of the gene for Escherichia coli seryl-tRNA synthetase

An orthogonal seryl-tRNA synthetase/tRNA pair for noncanonical amino acid mutagenesis in Escherichia coli

We report the development of the orthogonal amber-suppressor pair Archaeoglobus fulgidus seryl-tRNA (Af-tRNA^Ser)/Methanosarcina mazei seryl-tRNA synthetase (MmSerRS) in Escherichia coli. Furthermore, the crystal structure of MmSerRS was solved at 1.45 Å resolution, which should enable structure-guided engineering of its active site to genetically encode small, polar noncanonical amino acids (ncAAs).

Regulation of Serine, Glycine, and One-Carbon Biosynthesis

The biosynthesis of serine, glycine, and one-carbon (C1) units constitutes a major metabolic pathway in Escherichia coli and Salmonella enterica serovar Typhimurium. C1 units derived from serine and glycine are used in the synthesis of purines, histidine, thymine, pantothenate, and methionine and in the formylation of the aminoacylated initiator fMet-TRNAfMet used to start translation in E. coli and serovar Typhimurium. The need for serine, glycine, and C1 units in many cellular functions makes it necessary for the genes encoding enzymes for their synthesis to be carefully regulated to meet the changing demands of the cell for these intermediates. This review discusses the regulation of the following genes: serA, serB, and serC; gly gene; gcvTHP operon; lpdA; gcvA and gcvR; and gcvB genes. Threonine utilization (the Tut cycle) constitutes a secondary pathway for serine and glycine biosynthesis. L-Serine inhibits the growth of E. coli cells in GM medium, and isoleucine releases this growth inhibition. The E. coli glycine transport system (Cyc) has been shown to transport glycine, D-alanine, D-serine, and the antibiotic D-cycloserine. Transport systems often play roles in the regulation of gene expression, by transporting effector molecules into the cell, where they are sensed by soluble or membrane-bound regulatory proteins.

Serratia marcescensGene Required for Surfactant Serrawettin W1 Production Encodes Putative Aminolipid Synthetase Belonging to Nonribosomal Peptide Synthetase Family

Serrawettin W1 produced by Serratia marcescens is a surface active exolipid having various functions supporting behaviors of bacteria on surface environments. Through the genetic analyses of serrawettin-less mutants of S. marcescens 274, the swrW gene encoding putative serrawettin W1 synthetase was identified. Homology analysis of the putative SwrW demonstrated the presence of condensation, adenylation, thiolation, and thioesterase domains which are characteristic for nonribosomal peptide synthetase (NRPS). NRPSs have been known as multi-modular enzymes. Linear alignment of these modules specifying respective amino acids will enable peptide bond formation resulting in a specific amino acid sequence. Putative SwrW was uni-modular NRPS specifying only L-serine. Possible steps in this simple unimodular NRPS for biosynthesis of serrawettin W1 [ cyclo-(D-3-hydroxydecanoyl-L-seryl) (2) ] were predicted by referring to the ingenious enzymatic activity of gramicidin S synthetase (multi-modular NRPS) of Brevibacillus brevis.

Genomic organization, expression, and subcellular localization of mouse mitochondrial seryl-tRNA synthetase

We report here the identification and characterization of the mouse mitochondrial seryl-tRNA synthetase (mtSerRS). The genomic organization of mouse mtSerRS has been elucidated. The mouse mtSerRS gene containing 16 exons encodes a 519 residue protein with a strong homology to the mitochondria-like seryl-tRNA synthetase of bacteria, yeast, and other homologs. The mouse mtSerRS is ubiquitously expressed in various tissues, but more abundantly in tissues with high metabolic rates including heart and liver. Surprisingly, this gene, unlike other nuclear genes encoding mitochondrial proteins, exhibited a low expression in skeletal muscle and brain. Furthermore, immunofluorescence analysis of NIH3T3 cells expressing the mtSerRS-GFP fusion protein demonstrated that the mouse mtSerRS localizes in mitochondrion. These observations suggest that the mouse mtSerRS is an evolutionarily conserved protein involved in aminoacylation. Thus, it may play a role in the fidelity in mitochondrial translation and pathogenesis of deafness-associated mutations in the mitochondrial tRNA(Ser(UCN)).

Kinetics of the interaction of translation factor SelB from Escherichia coli with guanosine nucleotides and selenocysteine insertion sequence RNA

The kinetics of the interaction of GTP and GDP with SelB, the specific translation factor for the incorporation of selenocysteine into proteins, have been investigated using the stopped-flow method. Useful signals were obtained using intrinsic (i.e. tryptophan) fluorescence, the fluorescence of methylanthraniloyl derivatives of nucleotides, or fluorescence resonance energy transfer from tryptophan to the methylanthraniloyl group. The affinities of SelB for GTP (K(d) = 0.74 micrometer) and GDP (K(d) = 13.4 micrometer) were considerably lower than those of other translation factors. Of functional significance is the fact that the rate constant for GDP release from its complex with SelB (15 s(-)(1)) is many orders of magnitude larger than for elongation factor Tu, explaining why a GDP/GTP exchange factor is not required for the action of SelB. In contrast, the rate of release of GTP is 2 orders of magnitude slower and not significantly faster than for elongation factor Tu. Using a fluorescently labeled 17-nucleotide RNA minihelix that represents a binding site for the protein and that is part of the fdhF selenocysteine insertion sequence element positioned immediately downstream of the UGA triplet coding for selenocysteine incorporation, the kinetics of the interaction were studied. The high affinity of the interaction (K(d) approximately 1 nm) appeared to be increased even further when selenocysteyl-tRNA(Sec) was bound to SelB, but to be independent of the presence or nature of the guanosine nucleotide at the active site. These results suggest that the affinity of SelB for its RNA binding site is maximized when charged tRNA is bound and decreases to allow dissociation and reading of codons downstream of the selenocysteine codon after selenocysteine peptide bond formation.

Identification and characterisation of the selenocysteine-specific translation factor SelB from the archaeon Methanococcus jannaschii

Selenocysteine insertion into archaeal selenopolypeptides is directed through an mRNA structure (the SECIS element) situated in the 3' non-translated region like in eukaryotes. To elucidate the mechanism how this element affects decoding of an in-frame UGA with selenocysteine the open reading frames of the genome of Methanococcus jannaschii were searched for the existence of a homolog to the bacterial specialized translation factor SelB. The product of the open reading frame MJ0495 was identified as the archaeal SelB homolog on the basis of the following characteristics: (1) MJ0495 possesses sequence features characteristic of bacterial SelB; (2) purified MJ0495 displays guanine nucleotide binding properties like SelB; and (3) it preferentially binds selenocysteyl-tRNA(Sec). In contrast to bacterial SelB, however, no binding of MJ0495 protein to the SECIS element of the mRNA was found under the experimental conditions employed which correlates with the fact that MJ0495 lacks the C-terminal domain of the bacterial SelB protein known to bind the SECIS element. It is speculated that in Archaea the functions of bacterial SelB are distributed over at least two proteins, one, serving as the specific translation factor, like MJ0495, and another one, binding to the SECIS which interacts with the ribosome and primes it to decode UGA.

tRNA leucine identity and recognition sets

Transfer RNAs (tRNAs) are grouped into two classes based on the structure of their variable loop. In Escherichia coli, tRNAs from three isoaccepting groups are classified as type II. Leucine tRNAs comprise one such group. We used both in vivo and in vitro approaches to determine the nucleotides that are required for tRNA(Leu) function. In addition, to investigate the role of the tRNA fold, we compared the in vivo and in vitro characteristics of type I tRNA(Leu) variants with their type II counterparts.A minimum of six conserved tRNA(Leu) nucleotides were required to change the amino acid identity and recognition of a type II tRNA(Ser) amber suppressor from a serine to a leucine residue. Five of these nucleotides affect tRNA tertiary structure; the G15-C48 tertiary "Levitt base-pair" in tRNA(Ser) was changed to A15-U48; the number of nucleotides in the alpha and beta regions of the D-loop was changed to achieve the positioning of G18 and G19 that is found in all tRNA(Leu); a base was inserted at position 47n between the base-paired extra stem and the T-stem; in addition the G73 "discriminator" base of tRNA(Ser) was changed to A73. This minimally altered tRNA(Ser) exclusively inserted leucine residues and was an excellent in vitro substrate for LeuRS. In a parallel experiment, nucleotide substitutions were made in a glutamine-inserting type I tRNA (RNA(SerDelta); an amber suppressor in which the tRNA(Ser) type II extra-stem-loop is replaced by a consensus type I loop). This "type I" swap experiment was successful both in vivo and in vitro but required more nucleotide substitutions than did the type II swap. The type I and II swaps revealed differences in the contributions of the tRNA(Leu) acceptor stem base-pairs to tRNA(Leu) function: in the type I, but not the type II fold, leucine specificity was contingent on the presence of the tRNA(Leu) acceptor stem sequence. The type I and II tRNAs used in this study differed only in the sequence and structure of the variable loop. By altering this loop, and thereby possibly introducing subtle changes into the overall tRNA fold, it became possible to detect otherwise cryptic contributions of the acceptor stem sequence to recognition by LeuRS. Possible reasons for this effect are discussed.

Linkage map of Escherichia coli K-12, edition 10: the traditional map

This map is an update of the edition 9 map by Berlyn et al. (M. K. B. Berlyn, K. B. Low, and K. E. Rudd, p. 1715-1902, in F. C. Neidhardt et al., ed., Escherichia coli and Salmonella: cellular and molecular biology, 2nd ed., vol. 2, 1996). It uses coordinates established by the completed sequence, expressed as 100 minutes for the entire circular map, and adds new genes discovered and established since 1996 and eliminates those shown to correspond to other known genes. The latter are included as synonyms. An alphabetical list of genes showing map location, synonyms, the protein or RNA product of the gene, phenotypes of mutants, and reference citations is provided. In addition to genes known to correspond to gene sequences, other genes, often older, that are described by phenotype and older mapping techniques and that have not been correlated with sequences are included.

Genomic organization, cDNA sequence, bacterial expression, and purification of human seryl-tRNA synthase

In this paper, we report the cDNA sequence and deduced primary sequence for human cytosolic seryl-tRNA synthetase, and its expression in Escherichia coli. Two human brain cDNA clones of different origin, containing overlapping fragments coding for human seryl-tRNA synthetase were sequenced: HFBDN14 (fetal brain clone); and IB48 (infant brain clone). For both clones the 5' region of the cDNA was missing. This 5' region was obtained via PCR methods using a human brain 5' RACE-Ready cDNA library. The complete cDNA sequence allowed us to define primers to isolate and characterize the intron/exon structure of the serS gene, consisting of 10 introns and 11 exons. The introns' sizes range from 283 bp to more than 3000 bp and the size of the exons from 71 bp to 222 bp. The availability of the gene structure of the human enzyme could help to clarify some aspects of the molecular evolution of class-II aminoacyl-tRNA synthetases. The human seryl-tRNA synthetase has been expressed in E. coli, purified (95% pure as determined by SDS/PAGE) and kinetic parameters have been measured for its substrate tRNA. The human seryl-tRNA synthetase sequence (514 amino acid residues) shows significant sequence identity with seryl-tRNA synthetases from E. coli (25%), Saccharomyces cerevisiae (40%), Arabidopsis thaliana (41%) and Caenorhabditis elegans (60%). The partial sequences from published mammalian seryl-tRNA synthetases are very similar to the human enzyme (94% and 92% identity for mouse and Chinese hamster seryl-tRNA synthetase, respectively). Human seryl-tRNA synthetase, similar to several other class-I and class-II human aminoacyl-tRNA synthetases, is clearly related to its bacterial counterparts, independent of an additional C-terminal domain and a N-terminal insertion identified in the human enzyme. In functional studies, the enzyme aminoacylates calf liver tRNA and prokaryotic E. coli tRNA.

Only one nucleotide insertion to the long variable arm confers an efficient serine acceptor activity upon Saccharomyces cerevisiae tRNA(Leu) in vitro

Several tRNA species have a long variable arm composed of over ten nucleotides, which are relevant to those specific to serine, leucine and tyrosine in prokaryotes, while there are only serine and leucine-specific tRNAs in eukaryotes. To clarify the evolutionary aspects of the identity determination mechanism of these tRNAs, the tRNA(Ser) recognition in Saccharomyces cerevisiae was studied. Unmodified tRNA(Leu) transcript had serylation ability of low efficiency, but native tRNA(Leu) did not, indicating that some modification of tRNA(Leu) serves as a negative identity determinant for seryl-tRNA synthetase. Changing the discriminator base did not seriously affect the serine accepting efficiency. The tRNA(Leu) transcript possessing the variable arm of tRNA(Ser) was efficiently aminoacylated with serine. Eventually, it was found that only one nucleotide insertion to the variable arm of tRNA(Leu) was sufficient to confer an efficient serine accepting activity. The mode of serine tRNA recognition is similar to that in Escherichia coli in that the end of the long variable arm, but not the anticodon or discriminator base, is important. However, S. cerevisiae seryl-tRNA synthetase adopts a substantially different mechanism for rejection of tRNA(Leu) from that of its E. coli counterpart.

Creation of libraries with long ORFs by polymerization of a microgene

We describe a novel method for constructing pools of DNA sequences that encode large proteins with molecular diversity. Sets of primer pairs that form 8 to 10 complementary base pairs in the 3' region and have double mismatch pairs at their 3'-OH ends were designed so that primer dimers recreated short stretches of DNA (microgenes) devoid of termination codons. Cycles of denaturation and elongation reactions with a pair of primers, four dNTPs, and 3'-5' exo+ thermostable DNA polymerase gave head-to-tail polymers of the primer dimer unit (microgene) whose sizes exceeded 12 kb. No template was required in this reaction, but mismatched nucleotides at 3'-OH ends of the primers were critical for efficient polymerization. At end-joining junctions of a microgene, nucleotide insertions and deletions randomly occurred, resulting in combinatorial libraries of three reading frames from a single microgene. Further molecular diversity could be incorporated by using a mixture of primers. The resultant polymers have long ORFs whose products have a repetitious nature that could facilitate the formation of higher structures of translated products. Thus, microgene polymers may be used as a source of libraries for in vitro protein evolution experiments. Ligation of a microgene is apparently related to the nonhomologous recombination of double-strand breaks in DNA that has been shown to be catalyzed by DNA polymerases. We named this polymerization reaction the "microgene polymerization reaction."

Characterization of a temperature-sensitive Escherichia coli mutant and revertants with altered seryl-tRNA synthetase activity

A mutation in the structural gene coding for seryl-tRNA synthetase in temperature-sensitive Escherichia coli K28 has been reported to alter the level of enzyme expression at high temperature (R. J. Hill and W. Konigsberg, J. Bacteriol. 141:1163-1169, 1980). We identified this mutation as a C-->T transition in the first base of codon 386, resulting in a replacement of histidine by tyrosine. The steady-state levels of serS mRNA in K28 and in the wild-type strains are very similar. Pulse-chase labeling experiments show a difference in protein stability, but not one important enough to account for the temperature sensitivity of K28. The main reason for the temperature sensitivity of K28 appears to be the low level of specific activity of the mutant synthetase at nonpermissive temperature, not a decreased expression level. Spontaneous temperature-resistant revertants were selected which were found to have about a fivefold-higher level of SerRS than the K28 strain. We identified the mutation responsible for the reversion as being upstream from the -10 sequence in the promoter region. The steady-state levels of serS mRNA in the revertants are significantly higher than that in the parental strain.

Codon-reading specificity of an unmodified form of Escherichia coli tRNA1Ser in cell-free protein synthesis

Unmodified tRNA molecules are useful for many purposes in cell-free protein biosynthesis, but there is little information about how the lack of tRNA post-transcriptional modifications affects the coding specificity for synonymous codons. In the present study, we prepared an unmodified form of Escherichia coli tRNA1Ser, which originally has the cmo5UGA anticodon (cmo5U = uridine 5-oxyacetic acid) and recognizes the UCU, UCA and UCG codons. The codon specificity of the unmodified tRNA was tested in a cell-free protein synthesis directed by designed mRNAs under competition conditions with the parent tRNA1Ser. It was found that the unmodified tRNA with the UGA anti-codon recognizes the UCA codon nearly as efficiently as the modified tRNA. The unmodified tRNA recognized the UCU codon with low, but detectable efficiency, whereas no recognition of the UCC and UCG codons was detected. Therefore, the absence of modifications makes this tRNA more specific to the UCA codon by remarkably reducing the efficiencies of wobble reading of other synonymous codons, without a significant decrease in the UCA reading efficiency.

Variant minihelix RNAs reveal sequence-specific recognition of the helical tRNA(Ser) acceptor stem by E.coli seryl-tRNA synthetase

Aminoacylation rate determinations for a series of variant RNA minihelix substrates revealed that Escherichia coli seryl-tRNA synthetase (SerRS) recognizes the 1--72 through 5--68 base pairs of the E.coli tRNA(Ser) acceptor stem with the major recognition elements clustered between positions 2--71 and 4--69. The rank order of effects of canonical base pair substitutions at each position on kcat/Km was used to assess the involvement of major groove functional groups in recognition. Conclusions based on the biochemical data are largely consistent with the interactions revealed by the refined structure of the homologous Thermus thermophilus tRNA(Ser)-SerRS complex that Cusack and colleagues report in the accompanying paper. Disruption of an end-on hydrophobic interaction between the major groove C5(H) of pyrimidine 69 and an aromatic side chain of SerRS is shown to significantly decrease kcat/Km of a minihelix substrate. This type of interaction provides a means by which proteins can recognize the binary information of 'degenerate' sequences, such as the purine-pyrimidine base pairs of tRNA(Ser). The 3--70 base pair is shown to contribute to recognition by SerRS even though it is not contacted specifically by the protein. The latter effect derives from the organization of the specific contacts that SerRS makes with the neighboring 2--71 and 4--69 acceptor stem base pairs.

The C-terminal extension of yeast seryl-tRNA synthetase affects stability of the enzyme and its substrate affinity

Saccharomyces cerevisiae seryl-tRNA synthetase (SerRS) contains a 20-amino acid C-terminal extension, which is not found in prokaryotic SerRS enzymes. A truncated yeast SES1 gene, lacking the 60 base pairs that encode this C-terminal domain, is able to complement a yeast SES1 null allele strain; thus, the C-terminal extension in SerRS is dispensable for the viability of the cell. However, the removal of the C-terminal peptide affects both stability of the enzyme and its affinity for the substrates. The truncation mutant binds tRNA with 3.6-fold higher affinity, while the Km for serine is 4-fold increased relative to the wild-type SerRS. This indicates the importance of the C-terminal extension in maintaining the overall structure of SerRS.

Wide cross-species aminoacyl-tRNA synthetase replacement in vivo: yeast cytoplasmic alanine enzyme replaced by human polymyositis serum antigen

Because of variations in tRNA sequences in evolution, tRNA synthetases either do not acylate their cognate tRNAs from other organisms or execute misacylations which can be deleterious in vivo. We report here the cloning and primary sequence of a 958-aa Saccharomyces cerevisiae alanyl-tRNA synthetase. The enzyme is a close homologue of the human and Escherichia coli enzymes, particularly in the region of the primary structure needed for aminoacylation of RNA duplex substrates based on alanine tRNA acceptor stems with a G3.U70 base pair. An ala1 disrupted allele demonstrated that the gene is essential and that, therefore, ALA1 encodes an enzyme required for cytoplasmic protein synthesis. Growth of cells harboring the ala1 disrupted allele was restored by a cDNA clone encoding human alanyl-tRNA synthetase, which is a serum antigen for many polymyositis-afflicted individuals. The human enzyme in extracts from rescued yeast was detected with autoimmune antibodies from a polymyositis patient. We conclude that, in spite of substantial differences between human and yeast tRNA sequences in evolution, strong conservation of the G3.U70 system of recognition is sufficient to yield accurate aminoacylation in vivo across wide species distances.

Structure, function and evolution of seryl-tRNA synthetases: implications for the evolution of aminoacyl-tRNA synthetases and the genetic code

Two aspects of the evolution of aminoacyl-tRNA synthetases are discussed. Firstly, using recent crystal structure information on seryl-tRNA synthetase and its substrate complexes, the coevolution of the mode of recognition between seryl-tRNA synthetase and tRNA(ser) in different organisms is reviewed. Secondly, using sequence alignments and phylogenetic trees, the early evolution of class 2 aminoacyl-tRNA synthetases is traced. Arguments are presented to suggest that synthetases are not the oldest of protein enzymes, but survived as RNA enzymes during the early period of the evolution of protein catalysts. In this view, the relatedness of the current synthetases, as evidenced by the division into two classes with their associated subclasses, reflects the replacement of RNA synthetases by protein synthetases. This process would have been triggered by the acquisition of tRNA 3' end charging activity by early proteins capable of activating small molecules (e.g., amino acids) with ATP. If these arguments are correct, the genetic code was essentially frozen before the protein synthetases that we know today came into existence.

Seryl-tRNA synthetase from Escherichia coli: functional evidence for cross-dimer tRNA binding during aminoacylation

Escherichia coli seryl-tRNA synthetase (SerRS) is a homo-dimeric class II aminoacyl-tRNA synthetase. Each subunit is composed of two distinct domains: the N-terminal domain is a 60 A long, arm-like coiled coil structure built up of two antiparallel alpha-helices, whereas the C-terminal domain, the catalytic core, is an alpha-beta structure overlying a seven-stranded antiparallel beta-sheet. Deletion of the arm-like domain (SerRS delta 35-97) does not affect the amino acid activation step of the reaction, but reduces aminoacylation activity by more than three orders of magnitude. In the present study, it was shown that the formation of heterodimers from two aminoacylation defective homodimers, the N-terminal deletion and an active site mutant (SerRS E355Q), restored charging activity. The aminoacylation activity in a mixture containing the heterodimers was compared to that of solutions containing the same concentrations of homodimer. The activity of the mixture was eight times higher than the activities of the homodimer solutions, and reached 50% of the theoretical value that would be expected if 50% of the mixture was in the heterodimer form and assuming that a heterodimer contains only one active site. These results are in full agreement with the structural analysis of E. coli SerRS complexed with its cognate tRNA and provide functional evidence for the cross-dimer binding of tRNA in solution.

Seryl-tRNA synthetase from Escherichia coli: implication of its N-terminal domain in aminoacylation activity and specificity

Escherichia coli seryl-tRNA synthetase (SerRS) a dimeric class II aminoacyl-tRNA synthetase with two structural domains charges specifically the five iso-acceptor tRNA(ser) as well as the tRNA(sec) (selC product) of E. coli. The N-terminal domain is a 60 A long arm-like coiled coil structure built of 2 long antiparallel a-h helices, whereas the C-terminal domain is a alpha-beta structure. A deletion of the N-terminal arm of the enzyme does not affect the amino acid activation step of the reaction, but reduces dramatically amino-acylation activity. The Kcat/Km value for the mutant enzyme is reduced by more than 4 orders of magnitude, with a nearly 30 fold increased Km value for tRNA(ser). An only slightly truncated mutant form (16 amino acids of the tip of the arm replaced by a glycine) has an intermediate aminoacylation activity. Both mutant synthetases have lost their specificity for tRNA(ser) and charge also non-cognate type 1 tRNA(s). Our results support the hypothesis that class II synthetases have evolved from an ancestral catalytic core enzyme by adding non-catalytic N-terminal or C-terminal tRNA binding (specificity) domains which act as determinants for cognate and anti-determinants for non-cognate tRNAs.

Coexpression of eukaryotic tRNASer and yeast seryl-tRNA synthetase leads to functional amber suppression in Escherichia coli

In order to gain insight into the conservation of determinants for tRNA identity between organisms, Schizosaccharomyces pombe and human amber suppressor serine tRNA genes have been examined for functional expression in Escherichia coli. The primary transcripts, which originated from E. coli plasmid promoters, were processed into mature tRNAs, but they were poorly aminoacylated in E. coli and thus were nonfunctional as suppressors in vivo. However, coexpression of cloned Saccharomyces cerevisiae seryl-tRNA synthetase led to efficient suppression in E. coli. This shows that some, but not all, determinants specifying the tRNASer identity are conserved in evolution.

Contributions of discrete tRNA(Ser) domains to aminoacylation by E.coli seryl-tRNA synthetase: a kinetic analysis using model RNA substrates

The aminoacylation kinetics of T7 transcripts representing defined regions of Escherichia coli serine tRNAs were determined using purified E.coli seryl-tRNA synthetase (SerRS) and the kinetic values were used to estimate the relative contribution of various tRNA(Ser) domains to recognition by SerRS. The analysis revealed that the extra stem/loop structure, characteristic of type II tRNAs such as tRNA(Ser), is the domain which makes the largest contribution to kcat/Km of aminoacylation. Moreover, Km of aminoacylation was increased by a factor of about 1000 when the extra stem/loop was changed to the consensus sequence of type I tRNA extra loops indicating that the stem structure contributes significantly to the binding of tRNA(Ser) to SerRS. A model RNA, which represents only the tRNA(Ser) coaxial acceptor-T psi C stem/loop domain, was also specifically aminoacylated by SerRS having a kcat/Km about 1000-fold greater than background levels. A significant portion of the contribution of this domain to aminoacylation is attributable to the acceptor stem sequence making the acceptor stem the second most important domain for recognition by SerRS. Finally, kcat/Km was essentially unchanged when the entire anticodon stem/loop of tRNA(Ser) was deleted indicating that neither the anticodon nucleotides nor the surrounding stem/loop structure are important for recognition by SerRS.

Termination of translation in bacteria may be modulated via specific interaction between peptide chain release factor 2 and the last peptidyl-tRNA(Ser/Phe)

The 5' context of 671 Escherichia coli stop codons UGA and UAA has been compared with the context of stop-like codons (UAC, UAU and CAA for UAA; UGG, UGC, UGU and CGA for UGA). We have observed highly significant deviations from the expected nucleotide distribution: adenine is over-represented whereas pyrimidines are under-represented in position -2 upstream from UAA. Uridine is over-represented in position -3 upstream from UGA. Lysine codons are preferable immediately prior to UAA. A complete set of codons for serine and the phenylalanine UUC codon are preferable immediately 5' to UGA. This non-random codon distribution before stop codons could be considered as a molecular device for modulation of translation termination. We have found that certain fragment of E. coli release factor 2 (RF2) (amino acids 93-114) is similar to the amino acid sequences of seryl-tRNA synthetase (positions 10-19 and 80-93) and of beta (small) subunit (positions 72-94) of phenylalanyl-tRNA synthetase from E. coli. Three-dimensional structure of E. coli seryl-tRNA synthetase is known [1]: Its N-terminus represents an antiparallel alpha-helical coiled-coil domain and contains a region homologous to RF2. On the basis of the above-mentioned results we assume that a specific interaction between RF2 and the last peptidyl-tRNA(Ser/Phe) occurs during polypeptide chain termination in prokaryotic ribosomes.

Yeast seryl-tRNA synthetase expressed in Escherichia coli recognizes bacterial serine-specific tRNAs in vivo

The Saccharomyces cerevisiae serS gene which encodes seryl-tRNA synthetase (SerRS) was expressed in Escherichia coli from the promoter and the ribosome binding sequences contained in its own 5'-flanking region. The low level of yeast SerRS in the prokaryotic host was sufficient to permit in vivo complementation of two temperature-sensitive E. coli serS mutants at the nonpermissive temperature. Thus, yeast SerRS can aminoacylate E. coli tRNA(Ser) species in vivo. Yeast SerRS, isolated from an overexpressing E. coli strain by a rapid two-step purification on FPLC, aminoacylated E. coli tRNA with serine much more poorly (relative kcat/Km = 2 x 10(-4)) than its homologous tRNAs. DL-Serine hydroxamate, an inhibitor of E. coli SerRS, inhibits yeast SerRS in vivo and in vitro with an inhibition constant (Ki) of 2.7 mM, a value 90-fold higher than that for E. coli SerRS.

Crystallization of the seryl-tRNA synthetase:tRNAS(ser) complex of Escherichia coli

Crystals of the complex between seryl-tRNA synthetase and tRNA(2ser) from Escherichia coli have been obtained from ammonium sulphate solutions. The crystals are of the 1:2 enzyme:tRNA complex, belong to the space group C222(1), have cell dimensions of a = 128.9 A, b = 164.9 A, c = 127.3 A and diffract anisotropically from 3.5 to 4.5 A. An X-ray diffraction data set to 4 A has been collected. The combination of molecular replacement using the refined structure of the catalytic domain of the native enzyme, data from a heavy atom derivative and solvent flattening was used to produce a map at 4 A resolution. This shows that a tRNA molecule binds across the dimer, the anticodon stem and loop do not contact the protein and the helical arm of the enzyme contacts the T psi C loop and the long extra arm of the tRNA.

Asparaginyl-tRNA synthetase from the Escherichia coli temperature-sensitive strain HO202. A proline replacement in motif 2 is responsible for a large increase in Km for asparagine and ATP

The Escherichia coli K12 mutant gene, asnS40, coding for asparaginyl-tRNA synthetase (AsnRS) in the temperature-sensitive strain HO202, was isolated from genomic DNA using the Polymerase Chain Reaction. DNA sequencing revealed that the mutant enzyme differs from the wild-type AsnRS by two amino acids, but only the P231L replacement leads to a change in aminoacylation activity. In the ATP-PPi exchange reaction at 37 degrees C the purified P231L enzyme has a more than 50-fold increased Km value for asparagine compared to the wild-type enzyme, while the Km value for ATP is increased 8-fold. In the aminoacylation reaction the mutant enzyme shows also significantly increased Km values for asparagine and ATP. Interestingly Pro-231 is part of the conserved motif 2 in class II aminoacyl-tRNA synthetases (Eriani, G., Delarue, M., Poch, O., Gangloff, J. and Moras, D. (1990) Nature 347, 203-206), indicating that this motif might be involved in all class II enzymes in amino acid activation.

Human histidyl-tRNA synthetase: recognition of amino acid signature regions in class 2a aminoacyl-tRNA synthetases

We have determined the sequence of cDNA for the human histidyl-tRNA synthetase (HRS) in a hepatoma cell line and confirmed it in fetal myoblast and fibroblast cell lines. The newly determined sequence differs in 48 places, including insertions and deletions, from a previously published sequence. By sequence specific probing and by direct sequencing, we have established that only the newly determined sequence is present in genomic DNA and we have sequenced 500 hundred bases upstream of the translation start site. The predicted amino acid sequence now clearly demonstrates all three motifs recognized in class 2 aminoacyl-tRNA synthetases. Alignment of E. coli, yeast, and when available, mammalian predicted amino acid sequences for three of the four members of the class 2a subgroup (his, pro, ser, and thr) shows strong preservation of amino acid specific signature regions proximal to motif 2 and proximal to motif 3. These probably represent the active site binding regions for the proximal acceptor stem and for the amino acid. The first two exons of human HRS contain a 32 amino acid helical motif, first described in human QRS, a class 1 synthetase, which is found also in a yeast RNA polymerase, a rabbit termination factor, and both bovine and human WRS, suggesting that it may be an RNA binding motif.

Entropies of coding and noncoding sequences of DNA and proteins

The entropies of protein coding genes from Escherichia coli were calculated according to Boltzmann's formula. Entropies of the coding regions were compared to the entropies of noncoding or miscoding ones. With nucleotides as code units, the entropies of the coding regions, when compared to the entropies of complete sequences (leader and coding region as well as trailer), were seen to be lower but with a marginal statistical significance. With triplets of nucleotides as code units, the entropies of correct reading frames were significantly lower than the entropies of frameshifts +1 and -1. With amino acids as code units, the results were opposite: Biologically functional proteins had significantly higher entropies than proteins translated from the frameshifted sequences. We attempt to explain this paradox with the hypothesis that the genetic code may have the ability of lowering information content (increasing entropy) of proteins while translating them from DNA. This ability might be beneficial to bacteria because it would make the functional proteins more probable (having a higher entropy) than nonfunctional proteins translated from frameshifted sequences.

Cysteinyl-tRNA synthetase is a direct descendant of the first aminoacyl-tRNA synthetase

The gene encoding the cysteinyl-tRNA synthetase of E. coli was cloned from an E. coli genomic library made in lambda 2761, a lambda vector which can integrate and which carries a chloramphenicol resistance gene. A thermosensitive cysS mutant of E. coli was lysogenised and chloramphenicol-resistant colonies able to grow at 42 degrees C were selected to isolate phages containing the wild-type cysS gene. The sequence of the gene was determined. It codes for a 461 amino-acid protein and includes the sequences HIGH and KMSK known to be involved in the ATP and tRNA binding respectively of class I synthetases. The cysteinyl enzyme has segments in common with the cytoplasmic leucyl-tRNA synthetase of Neurospora crassa, the tryptophanyl-tRNA synthetase of Bacillus stearothermophilus, and the phenylalanyl-tRNA synthetase of Saccharomyces cerevisiae. Sequence comparisons show that the amino end of the cysteinyl-tRNA synthetase has similarities with prokaryotic elongation factors Tu; this region is close to the equivalent acceptor binding domain of the glutaminyl-tRNA synthetase of E. coli. There is a further similarity with the seryl enzyme (a class II enzyme) which has led us to propose that both classes had a common origin and that this was the ancestor of the cysteinyl-tRNA synthetase.

Interaction of Escherichia coli tRNA(Ser) with its cognate aminoacyl-tRNA synthetase as determined by footprinting with phosphorothioate-containing tRNA transcripts

A footprinting technique using phosphorothioate-containing RNA transcripts has been developed and applied to identify contacts between Escherichia coli tRNA(Ser) and its cognate aminoacyl-tRNA synthetase. The cloned gene for the tRNA was transcribed in four reactions in which a different NTP was complemented by 5% of the corresponding nucleoside 5'-O-(1-thiotriphosphate). The phosphorothioate groups of such transcripts are cleaved by reaction with iodine to permit sequencing of the transcripts. Footprinting was achieved by performing the same reaction with the phosphorothioate-tRNA-enzyme complex. At 1 mM iodine, selective protection of the tRNA transcripts in the cognate system was observed, with strong protection at positions 52 and 68 and weak protection at positions 46, 53, 67, 69, and 70. It is suggested that these regions of the tRNA interact with the helical arm of the synthetase.

Sequence, structural and evolutionary relationships between class 2 aminoacyl-tRNA synthetases

Class 2 aminoacyl-tRNA synthetases, which include the enzymes for alanine, aspartic acid, asparagine, glycine, histidine, lysine, phenylalanine, proline, serine and threonine, are characterised by three distinct sequence motifs 1,2 and 3 (reference 1). The structural and evolutionary relatedness of these ten enzymes are examined using alignments of primary sequences from prokaryotic and eukaryotic sources and the known three dimensional structure of seryl-tRNA synthetase from E. coli. It is shown that motif 1 forms part of the dimer interface of seryl-tRNA synthetase and motifs 2 and 3 part of the putative active site. It is further shown that the seven alpha 2 dimeric synthetases can be subdivided into class 2a (proline, threonine, histidine and serine) and class 2b (aspartic acid, asparagine and lysine), each subclass sharing several important characteristic sequence motifs in addition to those characteristic of class 2 enzymes in general. The alpha 2 beta 2 tetrameric enzymes (for glycine and phenylalanine) show certain special features in common as well as some of the class 2b motifs. In the alanyl-tRNA synthetase only motif 3 and possibly motif 2 can be identified. The sequence alignments suggest that the catalytic domain of other class 2 synthetases should resemble the antiparallel domain found in seryl-tRNA synthetase. Predictions are made about the sequence location of certain important helices and beta-strands in this domain as well as suggestions concerning which residues are important in ATP and amino acid binding. Strong homologies are found in the N-terminal extensions of class 2b synthetases and in the C-terminal extensions of class 2a synthetases suggesting that these putative tRNA binding domains have been added at a later stage in evolution to the catalytic domain.

Alanyl-tRNA synthetase from Escherichia coli, Bombyx mori and Ratus ratus. Existence of common structural features

Alanyl-tRNA synthetase from Escherichia coli, Bombyx mori and rat were examined with respect to the following functional and structural properties: the effect of substrates on sensitivity to proteolysis, secondary structure as determined by circular dichroism, amino acid composition and, in the case of the rat and insect enzymes, partial amino acid sequence determination on a 60-kDa C-terminal tryptic fragment. Digestion of the enzyme from all three sources with trypsin resulted in significant decline in aminoacyl-tRNA synthetase activity with little effect on pyrophosphate-exchange activity. In each case the presence of alanine and ATP together, but not separately, reduced the rate of digestion by trypsin; the largest effect was observed with the enzyme from rat liver. Trypsin digestion generated fragments of 47 kDa and 40 kDa with all three enzymes, but detection of significant quantities of the 47-kDa fragment from the rat enzyme required the presence of ATP and alanine. Trypsin digestion produced a fragment of 60 kDa with all three enzymes, but detection of significant quantities of this fragment with the bacterial enzyme required the presence of ATP and alanine. Limited sequence analysis of the 60-kDa fragment from the insect and rat enzymes indicated that trypsin cleaved both proteins at the same site to generate this species. Similar effects of substrates were observed when the enzymes were digested with chymotrypsin suggesting that the effects of substrates on protease sensitivity were not unique to trypsin. Circular dichroism spectra obtained for the three enzymes were qualitatively and quantitatively similar. There is some similarity in amino acid composition between the rat and insect enzymes.

A second class of synthetase structure revealed by X-ray analysis of Escherichia coli seryl-tRNA synthetase at 2.5 A

The three-dimensional crystal structure of seryl-transfer RNA synthetase from Escherichia coli, refined at 2.5 A resolution, is described. It has an N-terminal domain that forms an antiparallel alpha helical coiled-coil, stretching 60 A out into the solvent and stabilized by interhelical hydrophobic interactions and an active-site alpha-beta domain based around a seven-stranded antiparallel beta sheet. Unlike the three other known synthetase structures, the enzyme contains no classical nucleotide-binding fold, and is the first representative of a second class of aminoacyl-tRNA synthetase structures.

Closely spaced and divergent promoters for an aminoacyl-tRNA synthetase gene and a tRNA operon in Escherichia coli. Transcriptional and post-transcriptional regulation of gltX, valU and alaW

The transcription of the gltX gene encoding the glutamyl-tRNA synthetase and of the adjacent valU and alaW tRNA operons of Escherichia coli K-12 has been studied. The alaW operon containing two tRNA(GGCAla) genes, is 800 base-pairs downstream from the gltX terminator and is transcribed from the same strand. The valU operon, containing three tRNA(UACVal) and one tRNA(UUULys) (the wild-type allele of supN) genes, is adjacent to gltX and is transcribed from the opposite strand. Its only promoter is upstream from the gltX promoters. The gltX gene transcript is monocistronic and its transcription initiates at three promoters, P1, P2 and P3. The transcripts from one or more of these promoters are processed by RNase E to generate two major species of gltX mRNA, which are stable and whose relative abundance varies with growth conditions. The stability of gltX mRNA decreases in an RNase E- strain and its level increases with growth rate about three times more than that of the glutamyl-tRNA synthetase. The 5' region of these mRNAs can adopt a stable secondary structure (close to the ribosome binding site) that is similar to the anticodon and part of the dihydroU stems and loops of tRNA(Glu), and which might be involved in translational regulation of GluRS synthesis. The gltX and valU promoters share the same AT-rich and bent upstream region, whose position coincides with the position of the upstream activating sequences of tRNA and rRNA promoters to which they are similar. This suggests that gltX and valU share transcriptional regulatory mechanisms.

Molecular cloning and nucleotide sequence of the gene for Escherichia coli leucyl-tRNA synthetase

The gene for Escherichia coli leucyl-tRNA synthetase leuS has been cloned by complementation of a leuS temperature sensitive mutant KL231 with an E.coli gene bank DNA. The resulting clones overexpress leucyl-tRNA synthetase (LeuRS) by a factor greater than 50. The DNA sequence of the complete coding regions was determined. The derived N-terminal protein sequence of LeuRS was confirmed by independent protein sequencing of the first 8 aminoacids. Sequence comparison of the LeuRS sequence with all aminoacyl-tRNA synthetase sequences available reveal a significant homology with the valyl-, isoleucyl- and methionyl-enzyme indicating that the genes of these enzymes could have derived from a common ancestor. Sequence comparison with the gene product of the yeast nuclear NAM2-1 suppressor allele curing mitochondrial RNA maturation deficiency reveals about 30% homology.