Heteronuclear NMR studies of human serum apolipoprotein A-I. Part I. Secondary structure in lipid-mimetic solution

Class I aminoacyl-tRNA synthetases have been thought to be single polypeptide enzymes. However, the complete genome sequence of a hyper thermophile Aquifex aeolicus suggests that the gene for leucyl-tRNA synthetases (LeuRS) is probably split into two pieces (leuS and leuS'). In this research, each gene was separately cloned and overexpressed in Escherichia coli and the protein products were examined for LeuRS activity. Leucylation activity was detected only when both gene products coexisted. Gel filtration analysis showed that the active form of A. aeolicus LeuRS has a heterodimeric (alpha/beta type) quaternary structure that is unique among class I aminoacyl-tRNA synthetases.     

High-level expression and single-step purification of leucyl-tRNA synthetase from Escherichia coli

A T7 promoter-based His6-tagging vector has been constructed that directs the synthesis in Escherichia coli of fusion proteins containing a stretch of six histidine residues at the N terminus. The vector allows overproduction and single-step purification of His6-fusion protein by immobilized metal (Ni2+) chelate affinity chromatography. The gene encoding leucyl-tRNA synthetase (leuS) was cloned into this vector and expressed in high level. The specific activity of the synthetase in the crude extract of E. coli JM109(DE3) transformant containing the His6-tagging vector with the gene leuS was approximately 110 times that of JM109(DE3) (the host strain without the vector). The overproduced His6-fusion leucyl-tRNA synthetase can be purified to homogeneity under native conditions within 2 h by one-step affinity chromatography with an overall yield of 55%. The His6-tag at the N terminus of leucyl-tRNA synthetase did not affect its aminoacylation activity or the secondary structure.     

Expression and characterization of the human mitochondrial leucyl-tRNA synthetase

A cDNA clone encoding the human mitochondrial leucyl-tRNA synthetase (mtLeuRS) has been identified from the EST databases. Analysis of the protein encoded by this cDNA indicates that the protein is 903 amino acids in length and contains a mitochondrial signal sequence that is predicted to encompass the first 21 amino acids. Sequence analysis shows that this protein contains the characteristic motifs of class I aminoacyl-tRNA synthetases and regions of high homology to other mitochondrial and bacterial LeuRS proteins. The mature form of this protein has been cloned and expressed in Escherichia coli. Gel filtration indicates that human mtLeuRS is active in a monomeric state, with an apparent molecular mass of 101 kDa. The human mtLeuRS is capable of aminoacylating E. coli tRNA(Leu). Its activity is inhibited at high levels of either monovalent or divalent cations. K(M) and k(cat) values for ATP:PP(i) exchange and for the aminoacylation reaction have been determined.     

Homology of yeast mitochondrial leucyl-tRNA synthetase and isoleucyl- and methionyl-tRNA synthetases of Escherichia coli

Respiratory deficient mutants of Saccharomyces cerevisiae previously assigned to complementation group G59 are pleiotropically deficient in respiratory chain components and in mitochondrial ATPase. This phenotype has been shown to be a consequence of mutations in a nuclear gene coding for mitochondrial leucyl-tRNA synthetase. The structural gene (MSL1) coding for the mitochondrial enzyme has been cloned by transformation of two different G59 mutants with genomic libraries of wild type yeast nuclear DNA. The cloned gene has been sequenced and shown to code for a protein of 894 residues with a molecular weight of 101,936. The amino-terminal sequence (30-40 residues) has a large percentage of basic and hydroxylated residues suggestive of a mitochondrial import signal. The cloned MSL1 gene was used to construct a strain in which 1 kb of the coding sequence was deleted and substituted with the yeast LEU2 gene. Mitochondrial extracts obtained from the mutant carrying the disrupted MSL1::LEU2 allele did not catalyze acylation of mitochondrial leucyl-tRNA even though other tRNAs were normally charged. These results confirmed the correct identification of MSL1 as the structural gene for mitochondrial leucyl-tRNA synthetase. Mutations in MSL1 affect the ability of yeast to grow on nonfermentable substrates but are not lethal indicating that the cytoplasmic leucyl-tRNA synthetase is encoded by a different gene. The primary sequence of yeast mitochondrial leucyl-tRNA synthetase has been compared to other bacterial and eukaryotic synthetases. Significant homology has been found between the yeast enzyme and the methionyl- and isoleucyl-tRNA synthetases of Escherichia coli. The most striking primary sequence homology occurs in the amino-terminal regions of the three proteins encompassing some 150 residues. Several smaller domains in the more internal regions of the polypeptide chains, however, also exhibit homology. These observations have been interpreted to indicate that the three synthetases may represent a related subset of enzymes originating from a common ancestral gene.     

Nuclear gene for mitochondrial leucyl-tRNA synthetase of Neurospora crassa: isolation, sequence, chromosomal mapping, and evidence that the leu-5 locus specifies structural information.

We have isolated and characterized the nuclear gene for the mitochondrial leucyl-tRNA synthetase (LeuRS) of Neurospora crassa and have established that a defect in this structural gene is responsible for the leu-5 phenotype. We have purified mitochondrial LeuRS protein, determined its N-terminal sequence, and used this sequence information to identify and isolate a full-length genomic DNA clone. The 3.7-kilobase-pair region representing the structural gene and flanking regions has been sequenced. The 5' ends of the mRNA were mapped by S1 nuclease protection, and the 3' ends were determined from the sequence of cDNA clones. The gene contains a single short intron, 60 base pairs long. The methionine-initiated open reading frame specifies a 52-amino-acid mitochondrial targeting sequence followed by a 942-amino-acid protein. Restriction fragment length polymorphism analyses mapped the mitochondrial LeuRS structural gene to linkage group V, exactly where the leu-5 mutation had been mapped before. We show that the leu-5 strain has a defect in the structural gene for mitochondrial LeuRS by restoring growth under restrictive conditions for this strain after transformation with a wild-type copy of the mitochondrial LeuRS gene. We have cloned the mutant allele present in the leu-5 strain and identified the defect as being due to a Thr-to-Pro change in mitochondrial LeuRS. Finally, we have used immunoblotting to show that despite the apparent lack of mitochondrial LeuRS activity in leu-5 extracts, the leu-5 strain contains levels of mitochondrial LeuRS protein to similar to those of the wild-type strain.     

Isolation and Partial Characterization of Temperature-Sensitive Escherichia coli Mutants with Altered Leucyl- and Seryl-Transfer Ribonucleic Acid Synthetases

Two temperature-sensitive mutants of Escherichia coli have been found in which the conditional growth is a result of a thermosensitive leucyl-transfer ribonucleic acid (tRNA) synthetase and seryl-tRNA synthetase, respectively. The corresponding genetic loci, leuS and serS, cotransduce with lip and serC, respectively. As a result of the mutationally altered leucyl-tRNA synthetase, some leucine-, valine-, and isoleucine-forming enzymes were derepressed. Thus, leucyl-tRNA synthetase is involved in the repression of the enzymes needed for the synthesis of branched-chain amino acids.     

Molecular modeling study of the editing active site of Escherichia coli leucyl-tRNA synthetase: two amino acid binding sites in the editing domain

Aminoacyl-tRNA synthetases (aaRSs) strictly discriminate their cognate amino acids. Some aaRSs accomplish this via proofreading and editing mechanisms. Mursinna and coworkers recently reported that substituting a highly conserved threonine (T252) with an alanine within the editing domain of Escherichia coli leucyl-tRNA synthetase (LeuRS) caused LeuRS to cleave its cognate aminoacylated leucine from tRNA(Leu) (Mursinna et al., Biochemistry 2001;40:5376-5381). To achieve atomic level insight into the role of T252 in LeuRS and the editing reaction of aaRSs, a series of molecular modeling studies including homology modeling and automated docking simulations were carried out. A 3D structure of E. coli LeuRS was constructed via homology modeling using the X-ray structure of Thermus thermophilus LeuRS as a template because the E. coli LeuRS structure is not available from X-ray or NMR studies. However, both the X-ray T. thermophilus and homology-modeled E. coli structures were used in our studies. Amino acid binding sites in the proposed editing domain, which is also called the connective polypeptide 1 (CP1) domain, were investigated by automated docking studies. The root mean square deviation (RMSD) for backbone atoms between the X-ray and homology-modeled structures was 1.18 A overall and 0.60 A for the editing (CP1) domain. Automated docking studies of a leucine ligand into the editing domain were performed for both structures: homology structure of E. coli LeuRS and X-ray structure of T. thermophilus LeuRS for comparison. The results of the docking studies suggested that there are two possible amino acid binding sites in the CP1 domain for both proteins. The first site lies near a threonine-rich region that includes the highly conserved T252 residue, which is important for amino acid discrimination. The second site is located in a flexible loop region surrounded by residues E292, A293, M295, A296, and M298. The important T252 residue is at the bottom of the first binding pocket.     

Valyl-tRNA synthetase gene of Escherichia coli K12. Primary structure and homology within a family of aminoacyl-TRNA synthetases

The DNA nucleotide sequence of the valS gene encoding valyl-tRNA synthetase of Escherichia coli has been determined. The deduced primary structure of valyl-tRNA synthetase was compared to the primary sequences of the known aminoacyl-tRNA synthetases of yeast and bacteria. Significant homology was detected between valyl-tRNA synthetase of E. coli and other known branched-chain aminoacyl-tRNA synthetases. In pairwise comparisons the highest level of homology was detected between the homologous valyl-tRNA synthetases of yeast and E. coli, with an observed 41% direct identity overall. Comparisons between the valyl- and isoleucyl-tRNA synthetases of E. coli yielded the highest level of homology detected between heterologous enzymes (19.2% direct identity overall). An alignment is presented between the three branched-chain aminoacyl-tRNA synthetases (valyl- and isoleucyl-tRNA synthetases of E. coli and yeast mitochondrial leucyl-tRNA synthetase) illustrating the close relatedness of these enzymes. These results give credence to the supposition that the branched-chain aminoacyl-tRNA synthetases along with methionyl-tRNA synthetase form a family of genes within the aminoacyl-tRNA synthetases that evolved from a common ancestral progenitor gene.     

Maintenance of repression control of the ilvGMEDA operon in a temperature-sensitive leucyl-transfer RNA synthetase mutant of Escherichia coli K-12 at a restrictive temperature.

The mechanism of L-leucine regulation of ilvGMEDA is thought to be by ribosome-mediated attenuation that is dependent upon the concentration of Leu-tRNA(Leu) which results from leucyl-tRNA synthetase (LeuRS) activity. The requirement for LeuRS activity in attenuation control was tested in an Escherichia coli K-12 strain containing a temperature-sensitive LeuRS and the ilvGMEDA operon with an active ilvGM. Growth of this strain at 30 degrees C followed by a shift to 37 degrees C to inactivate the LeuRS revealed that ilvGM expression decreased at the restrictive temperature whereas the downstream gene expression was slightly elevated. We suggest that ilvGM does not respond to a deattenuation signal, and that, possibly, a secondary repression/derepression mechanism exists.     

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

Seryl-tRNA synthetase is the gene product of the serS locus in Escherichia coli. Its gene has been cloned by complementation of a serS temperature sensitive mutant K28 with an E. coli gene bank DNA. The resulting clones overexpress seryl-tRNA synthetase by a factor greater than 50 and more than 6% of the total cellular protein corresponds to the enzyme. The DNA sequence of the complete coding region and the 5'- and 3' untranslated regions was determined. Protein sequence comparison of SerRS with all available aminoacyl-tRNA synthetase sequences revealed some regions of significant homology particularly with the isoleucyl- and phenylalanyl-tRNA synthetases from E. coli.     

Cytoplasmic Leucyl-Trna Synthetase of Neurospora Crassa Is Not Specified by the Leu-5 Locus

We generated a lambda gt11 Neurospora crassa cDNA library and screened the library for the cytoplasmic leucyl-tRNA synthetase (cyto LeuRS) clones using cyto LeuRS specific antibody. Two clones, lambda NCLRSC1 and lambda NCLRSC2, were obtained which have inserts of approximately 2 kbp and approximately 1.3 kbp, and which overlap by about 0.6 kbp. The following lines of evidence indicate that lambda NCLRSC1 and lambda NCLRSC2 encode parts of cyto LeuRS. (1) Antibodies affinity purified using either of the fusion proteins encoded by lambda NCLRSC1 or lambda NCLRSC2 inhibit cyto LeuRS activity. Thus, the fusion protein and cyto LeuRS share immunological determinants. (2) The same antibodies also react with an approximately 115-kDa protein, which comigrates with purified cyto LeuRS, in immunoblots of total N. crassa proteins. We used the cDNA clones to probe a N. crassa genomic DNA library and isolated two genomic DNA clones. Partial sequence analysis of cDNA and genomic DNA clones shows a methionine initiated open reading frame, which includes a stretch of amino acid residues that are highly conserved and that are at the ATP binding site in aminoacyl-tRNA synthetases. Using the cloned DNA as probe, we show that the cyto LeuRS mRNA is approximately 3900 nucleotides long. Finally, we have used restriction fragment length polymorphism mapping to show that the cyto LeuRS gene resides on the far right of linkage group II and not on linkage group V where the leu-5 mutation, which was previously reported to specify cyto LeuRS, is located.     

The peptide bond between E292-A293 of Escherichia coli leucyl-tRNA synthetase is essential for its activity.

Escherichia coli leucyl-tRNA synthetase (LeuRS) is a class I aminoacyl-tRNA synthetase that contains a large connecting polypeptide (CP1) inserted into its nucleotide binding fold, or active site. In this study, purified leucyl-tRNA synthetase was found to be cleaved between E292 and A293 in its CP1 domain. SDS-PAGE analysis showed peptides of 63 and 34 kDa in addition to the native 97.3 kDa synthetase. By internal complementation, the two peptides could form a 97.3 kDa complex similar to the native LeuRS. This complex could support the ATP approximately PP(i) exchange activity of LeuRS, but could not complement for aminoacylation. To study the function of the region around the bond of E292 and A293, four pairs of peptides resulting from different cleavage sites in CP1 were reconstituted in vivo. With the exception of the enzyme assembled from the E292-A293 cleavage site, all the reassembled LeuRSs catalyzed the aminoacylation of tRNA(Leu). Although the E292-A293-cleaved LeuRS could not catalyze aminoacylation, fluorescence titration revealed that its tRNA binding ability was almost identical to that of wild-type LeuRS. These results suggest that the region around E292-A293 may be responsible for maintaining the proper conformation of LeuRS required for the tRNA charging activity.     

Glutamyl-tRNA synthetase of Escherichia coli. Isolation and primary structure of the gltX gene and homology with other aminoacyl-tRNA synthetases

The gltX gene encoding the glutamyl-tRNA synthetase of Escherichia coli and adjacent regulatory regions was isolated and sequenced. The structural gene encodes a protein of 471 amino acids whose molecular weight is 53,810. The codon usage is that of genes highly expressed in E. coli. The amino acid sequence deduced from the nucleotide sequence of the gltX gene was confirmed by mass spectrometry of large peptides derived from the glutamyl-tRNA synthetase. The observed peptides confirm 73% of the predicted sequence, including the NH2-terminal and the COOH-terminal segments. Sequence homology between the glutamyl-tRNA synthetase and other aminoacyl-tRNA synthetases of E. coli was found in four segments. Three of them are aligned in the same order in all the synthetases where they are present, but the intersegment spacings are not constant; these ordered segments may come from a progenitor to which other domains were added. Starting from the NH2-end, the first two segments are part of a longer region of homology with the glutaminyl-tRNA synthetase, without need for gaps; its size, about 100 amino acids, is typical of a single folding domain. In the first segment, containing sequences homologous to the HIGH consensus, the homology is consistent with the following evolutionary linkage: gltX----glnS----metS----ileS and tyrS.     

Leucine tRNA family of Escherichia coli: nucleotide sequence of the supP(Am) suppressor gene.

We describe the cloning and the DNA sequence of an amber suppressor allele of the Escherichia coli leuX (supP) gene. The suppressor allele codes for a tRNA with anticodon CUA, presumably derived by a single base change from a CAA anticodon. The mature coding sequence of the leuX gene is preceded by a putative Pribnow box sequence (TATAAT) and followed by a termination signal. The sequence of the leuX-coded tRNA is compared with the sequences of the four remaining tRNALeu isoacceptors of E. coli and with two tRNALeu species from bacteriophage T4 and T5. The conserved nucleotides in these seven tRNAs recognized by E. coli leucyl-tRNA synthetase are located mainly in the aminoacyl stem and in the D-stem/loop region.     

Penicillin-binding protein 2 inactivation in Escherichia coli results in cell division inhibition, which is relieved by FtsZ overexpression.

Aminoacyl-tRNA synthetase mutants of Escherichia coli are resistant to amdinocillin (mecillinam), a beta-lactam antibiotic which specifically binds penicillin-binding protein 2 (PBP2) and prevents cell wall elongation with concomitant cell death. The leuS(Ts) strain, in which leucyl-tRNA synthetase is temperature sensitive, was resistant to amdinocillin at 37 degrees C because of an increased guanosine 5'-diphosphate 3'-diphosphate (ppGpp) pool resulting from partial induction of the stringent response, but it was sensitive to amdinocillin at 25 degrees C. We constructed a leuS(Ts) delta (rodA-pbpA)::Kmr strain, in which the PBP2 structural gene is deleted. This strain grew as spherical cells at 37 degrees C but was not viable at 25 degrees C. After a shift from 37 to 25 degrees C, the ppGpp pool decreased and cell division was inhibited; the cells slowly carried out a single division, increased considerably in volume, and gradually lost viability. The cell division inhibition was reversible when the ppGpp pool increased at high temperature, but reversion required de novo protein synthesis, possibly of septation proteins. The multicopy plasmid pZAQ, overproducing the septation proteins FtsZ, FtsA, and FtsQ, conferred amdinocillin resistance on a wild-type strain and suppressed the cell division inhibition in the leuS(Ts) delta (rodA-pbpA)::Kmr strain at 25 degrees C. The plasmid pAQ, in which the ftsZ gene is inactivated, did not confer amdinocillin resistance. These results lead us to hypothesize that the nucleotide ppGpp activates ftsZ expression and thus couples cell division to protein synthesis.     

Leucyl-tRNA synthetase consisting of two subunits from hyperthermophilic bacteria Aquifex aeolicus

In a hyperthermophilic bacterium, Aquifex aeolicus, leucyl-tRNA synthetase (LeuRS) consists of two non-identical polypeptide subunits (alpha and beta), different from the canonical LeuRS, which has a single polypeptide chain. By PCR, using genome DNA of A. aeolicus as a template, genes encoding the alpha and beta subunits were amplified and cloned in Escherichia coli. The alpha subunit could not be expressed stably in vivo, whereas the beta subunit was overproduced and purified by a simple procedure. The beta subunit was inactive in catalysis but was able to bind tRNA(Leu). Interestingly, the heterodimer alphabeta-LeuRS could be overproduced in E. coli cells containing both genes and was purified to 95% homogeneity as a hybrid dimer. The kinetics of A. aeolicus LeuRS in pre-steady and steady states and cross-recognition of LeuRS and tRNA(Leu) from A. aeolicus and E. coli were studied. Magnesium concentration, pH value, and temperature aminoacylation optima were determined to be 12 mm, 7.8, and 70 degrees C, respectively. Under optimal conditions, A. aeolicus alphabeta-LeuRS is stable up to 65 degrees C.     

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.