Primary structure of a large aminoacyl-tRNA synthetase

Elucidation of productive alanine recognition mechanism by Escherichia coli alanyl-tRNA synthetase

Alanyl-tRNA synthetase (AlaRS) incorrectly recognizes both a slightly smaller glycine and a slightly larger serine in addition to alanine, and the probability of incorrect identification is extremely low at 1/300 and 1/170, respectively. Alanine is the second smallest amino acid after glycine; however, the mechanism by which AlaRS specifically identifies small differences in side chains with high accuracy remains unknown. In this study, using a malachite green assay, we aimed to elucidate the alanine recognition mechanism of a fragment (AlaRS368N) containing only the amino acid activation domain of Escherichia coli AlaRS. This method quantifies monophosphate by decomposing pyrophosphate generated during aminoacyl-AMP production. AlaRS368N produced far more pyrophosphate when glycine or serine was used as a substrate than when alanine was used. Among several mutants tested, an AlaRS mutant in which the widely conserved aspartic acid at the 235th position (D235) near the active center was replaced with glutamic acid (D235E) increased pyrophosphate release for the alanine substrate, compared to that from glycine and serine. These results suggested that D235 is optimal for AlaRS to specifically recognize alanine. Alanylation activities of an RNA minihelix by the mutants of valine at the 214th position (V214) of another fragment (AlaRS442N), which is the smallest AlaRS with alanine charging activity, suggest the existence of the van der Waals-like interaction between the side chain of V214 and the methyl group of the alanine substrate.

Trans-editing by aminoacyl-tRNA synthetase-like editing domains

Aminoacyl-tRNA synthetases (aaRS) are ubiquitous enzymes responsible for aminoacyl-tRNA (aa-tRNA) synthesis. Correctly formed aa-tRNAs are necessary for proper decoding of mRNA and accurate protein synthesis. tRNAs possess specific nucleobases that promote selective recognition by cognate aaRSs. Selecting the cognate amino acid can be more challenging because all amino acids share the same peptide backbone and several are isosteric or have similar side chains. Thus, aaRSs can misactivate non-cognate amino acids and produce mischarged aa-tRNAs. If left uncorrected, mischarged aa-tRNAs deliver their non-cognate amino acid to the ribosome resulting in misincorporation into the nascent polypeptide chain. This changes the primary protein sequence and potentially causes misfolding or formation of non-functional proteins that impair cell survival. A variety of proofreading or editing pathways exist to prevent and correct mistakes in aa-tRNA formation. Editing may occur before the amino acid transfer step of aminoacylation via hydrolysis of the aminoacyl-adenylate. Alternatively, post-transfer editing, which occurs after the mischarged aa-tRNA is formed, may be carried out via a distinct editing site on the aaRS where the mischarged aa-tRNA is deacylated. In recent years, it has become clear that most organisms also encode factors that lack aminoacylation activity but resemble aaRS editing domains and function to clear mischarged aa-tRNAs in trans. This review focuses on these trans-editing factors, which are encoded in all three domains of life and function together with editing domains present within aaRSs to ensure that the accuracy of protein synthesis is sufficient for cell survival.

Aminoacyl-tRNA Synthetases in the Bacterial World

Aminoacyl-tRNA synthetases (aaRSs) are modular enzymes globally conserved in the three kingdoms of life. All catalyze the same two-step reaction, i.e., the attachment of a proteinogenic amino acid on their cognate tRNAs, thereby mediating the correct expression of the genetic code. In addition, some aaRSs acquired other functions beyond this key role in translation. Genomics and X-ray crystallography have revealed great structural diversity in aaRSs (e.g., in oligomery and modularity, in ranking into two distinct groups each subdivided in 3 subgroups, by additional domains appended on the catalytic modules). AaRSs show huge structural plasticity related to function and limited idiosyncrasies that are kingdom or even species specific (e.g., the presence in many Bacteria of non discriminating aaRSs compensating for the absence of one or two specific aaRSs, notably AsnRS and/or GlnRS). Diversity, as well, occurs in the mechanisms of aaRS gene regulation that are not conserved in evolution, notably between distant groups such as Gram-positive and Gram-negative Bacteria. The review focuses on bacterial aaRSs (and their paralogs) and covers their structure, function, regulation, and evolution. Structure/function relationships are emphasized, notably the enzymology of tRNA aminoacylation and the editing mechanisms for correction of activation and charging errors. The huge amount of genomic and structural data that accumulated in last two decades is reviewed, showing how the field moved from essentially reductionist biology towards more global and integrated approaches. Likewise, the alternative functions of aaRSs and those of aaRS paralogs (e.g., during cell wall biogenesis and other metabolic processes in or outside protein synthesis) are reviewed. Since aaRS phylogenies present promiscuous bacterial, archaeal, and eukaryal features, similarities and differences in the properties of aaRSs from the three kingdoms of life are pinpointed throughout the review and distinctive characteristics of bacterium-like synthetases from organelles are outlined.

Urea Unfolding Study of E. coli Alanyl-tRNA Synthetase and Its Monomeric Variants Proves the Role of C-Terminal Domain in Stability

E. coli alanyl-tRNA exists as a dimer in its native form and the C-terminal coiled-coil part plays an important role in the dimerization process. The truncated N-terminal containing the first 700 amino acids (1–700) forms a monomeric variant possessing similar aminoacylation activity like wild type. A point mutation in the C-terminal domain (G674D) also produces a monomeric variant with a fivefold reduced aminoacylation activity compared to the wild type enzyme. Urea induced denaturation of these monomeric mutants along with another alaRS variant (N461 alaRS) was studied together with the full-length enzyme using various spectroscopic techniques such as intrinsic tryptophan fluorescence, 1-anilino-8-naphthalene-sulfonic acid binding, near- and far-UV circular dichroism, and analytical ultracentrifugation. Aminoacylation activity assay after refolding from denatured state revealed that the monomeric mutants studied here were unable to regain their activity, whereas the dimeric full-length alaRS gets back similar activity as the native enzyme. This study indicates that dimerization is one of the key regulatory factors that is important in the proper folding and stability of E. coli alaRS.

Structure Determination of Natural Products by Mass Spectrometry

I review laboratory research on the development of mass spectrometric methodology for the determination of the structure of natural products of biological and medical interest, which I conducted from 1958 to the end of the twentieth century. The methodology was developed by converting small peptides to their corresponding polyamino alcohols to make them amenable to mass spectrometry, thereby making it applicable to whole proteins. The structures of alkaloids were determined by analyzing the fragmentation of a known alkaloid and then using the results to deduce the structures of related compounds. Heparin-like structures were investigated by determining their molecular weights from the mass of protonated molecular ions of complexes with highly basic, synthetic peptides. Mass spectrometry was also employed in the analysis of lunar material returned by the Apollo missions. A miniaturized gas chromatograph mass spectrometer was sent to Mars on board of the two Viking 1976 spacecrafts.

Laying the groundwork for proteomics: mass spectrometry from 1958 to 1988

The development of mass spectrometric methods in peptide and protein chemistry in the author's laboratory is reviewed, from the first determination of the amino acid sequence of small peptides in the late 1950s to its use for the determination of the primary structure of large proteins by a combination of mass spectrometry and DNA sequencing in the late 1980s. This article is part of a Special Issue entitled: 20years of Proteomics in memory of Viatliano Pallini. Guest Editors: Luca Bini, Juan J. Calvete, Natacha Turck, Denis Hochstrasser and Jean-Charles Sanchez.

Aminoacyl-tRNA Synthetases in the Bacterial World

Aminoacyl-tRNAsynthetases (aaRSs) are modular enzymesglobally conserved in the three kingdoms of life. All catalyze the same two-step reaction, i.e., the attachment of a proteinogenic amino acid on their cognate tRNAs, thereby mediating the correct expression of the genetic code. In addition, some aaRSs acquired other functions beyond this key role in translation.Genomics and X-ray crystallography have revealed great structural diversity in aaRSs (e.g.,in oligomery and modularity, in ranking into two distinct groups each subdivided in 3 subgroups, by additional domains appended on the catalytic modules). AaRSs show hugestructural plasticity related to function andlimited idiosyncrasies that are kingdom or even speciesspecific (e.g.,the presence in many Bacteria of non discriminating aaRSs compensating for the absence of one or two specific aaRSs, notably AsnRS and/or GlnRS).Diversity, as well, occurs in the mechanisms of aaRS gene regulation that are not conserved in evolution, notably betweendistant groups such as Gram-positive and Gram-negative Bacteria.Thereview focuses on bacterial aaRSs (and their paralogs) and covers their structure, function, regulation,and evolution. Structure/function relationships are emphasized, notably the enzymology of tRNA aminoacylation and the editing mechanisms for correction of activation and charging errors. The huge amount of genomic and structural data that accumulatedin last two decades is reviewed,showing how thefield moved from essentially reductionist biologytowards more global and integrated approaches. Likewise, the alternative functions of aaRSs and those of aaRSparalogs (e.g., during cellwall biogenesis and other metabolic processes in or outside protein synthesis) are reviewed. Since aaRS phylogenies present promiscuous bacterial, archaeal, and eukaryal features, similarities and differences in the properties of aaRSs from the three kingdoms of life are pinpointedthroughout the reviewand distinctive characteristics of bacterium-like synthetases from organelles are outlined.

Allosteric interaction of nucleotides and tRNA(ala) with E. coli alanyl-tRNA synthetase

Alanyl-tRNA synthetase, a dimeric class 2 aminoacyl-tRNA synthetase, activates glycine and serine at significant rates. An editing activity hydrolyzes Gly-tRNA(ala) and Ser-tRNA(ala) to ensure fidelity of aminoacylation. Analytical ultracentrifugation demonstrates that the enzyme is predominately a dimer in solution. ATP binding to full length enzyme (ARS875) and to an N-terminal construct (ARS461) is endothermic (ΔH = 3-4 kcal mol(-1)) with stoichiometries of 1:1 for ARS461 and 2:1 for full-length dimer. Binding of aminoacyl-adenylate analogues, 5'-O-[N-(L-alanyl)sulfamoyl]adenosine (ASAd) and 5'-O-[N-(L-glycinyl)sulfamoyl]adenosine (GSAd), are exothermic; ASAd exhibits a large negative heat capacity change (ΔC(p) = 0.48 kcal mol(-1) K(-1)). Modification of alanyl-tRNA synthetase with periodate-oxidized tRNA(ala) (otRNA(ala)) generates multiple, covalent, enzyme-tRNA(ala) products. The distribution of these products is altered by ATP, ATP and alanine, and aminoacyl-adenylate analogues (ASAd and GSAd). Alanyl-tRNA synthetase was modified with otRNA(ala), and tRNA-peptides from tryptic digests were purified by ion exchange chromatography. Six peptides linked through a cyclic dehydromoropholino structure at the 3'-end of tRNA(ala) were sequenced by mass spectrometry. One site lies in the N-terminal adenylate synthesis domain (residue 74), two lie in the opening to the editing site (residues 526 and 585), and three (residues 637, 639, and 648) lie on the back side of the editing domain. At least one additional modification site was inferred from analysis of modification of ARS461. The location of the sites modified by otRNA(ala) suggests that there are multiple modes of interaction of tRNA(ala) with the enzyme, whose distribution is influenced by occupation of the ATP binding site.

Substrate specificity and catalysis by the editing active site of Alanyl-tRNA synthetase from Escherichia coli

Aminoacyl-tRNA synthetases (ARSs) enhance the fidelity of protein synthesis through multiple mechanisms, including hydrolysis of the adenylate and cleavage of misacylated tRNA. Alanyl-tRNA synthetase (AlaRS) limits misacylation with glycine and serine by use of a dedicated editing domain, and a mutation in this activity has been genetically linked to a mouse model of a progressive neurodegenerative disease. Using the free-standing Pyrococcus horikoshii AlaX editing domain complexed with serine as a model and both Ser-tRNA(Ala) and Ala-tRNA(Ala) as substrates, the deacylation activities of the wild type and five different Escherichia coli AlaRS editing site substitution mutants were characterized. The wild-type AlaRS editing domain deacylated Ser-tRNA(Ala) with a k(cat)/K(M) of 6.6 × 10(5) M(-1) s(-1), equivalent to a rate enhancement of 6000 over the rate of enzyme-independent deacylation but only 12.2-fold greater than the rate with Ala-tRNA(Ala). While the E664A and T567G substitutions only minimally decreased k(cat)/K(M,) Q584H, I667E, and C666A AlaRS were more compromised in activity, with decreases in k(cat)/K(M) in the range of 6-, 6.6-, and 15-fold. C666A AlaRS was 1.7-fold more active on Ala-tRNA(Ala) relative to Ser-tRNA(Ala), providing the only example of a true reversal of substrate specificity and highlighting a potential role of the coordinated zinc in editing substrate specificity. Along with the potentially serious physiological consequences of serine misincorporation, the relatively modest specificity of the AlaRS editing domain may provide a rationale for the widespread phylogenetic distribution of AlaX free-standing editing domains, thereby contributing a further mechanism to lower concentrations of misacylated tRNA(Ala).

Introduction of a leucine half-zipper engenders multiple high-quality crystals of a recalcitrant tRNA synthetase

Although Escherichia coli alanyl-tRNA synthetase was among the first tRNA synthetases to be sequenced and extensively studied by functional analysis, it has proved to be recalcitrant to crystallization. This challenge remained even for crystallization of the catalytic fragment. By mutationally introducing three stacked leucines onto the solvent-exposed side of an alpha-helix, an engineered catalytic fragment of the synthetase was obtained that yielded multiple high-quality crystals and cocrystals with different ligands. The engineered alpha-helix did not form a leucine zipper that interlocked with the same alpha-helix from another molecule. Instead, using the created hydrophobic spine, it interacted with other surfaces of the protein as a leucine half-zipper (LHZ) to enhance the crystal lattice interactions. The LHZ made crystal lattice contacts in all crystals of different space groups. These results illustrate the power of introducing an LHZ into helices to facilitate crystallization. The authors propose that the method can be unified with surface-entropy reduction and can be broadly used for protein-surface optimization in crystallization.

Unique protein architecture of alanyl-tRNA synthetase for aminoacylation, editing, and dimerization

Alanyl-tRNA synthetase (AlaRS) specifically recognizes the major identity determinant, the G3:U70 base pair, in the acceptor stem of tRNA(Ala) by both the tRNA-recognition and editing domains. In this study, we solved the crystal structures of 2 halves of Archaeoglobus fulgidus AlaRS: AlaRS-DeltaC, comprising the aminoacylation, tRNA-recognition, and editing domains, and AlaRS-C, comprising the dimerization domain. The aminoacylation/tRNA-recognition domains contain an insertion incompatible with the class-specific tRNA-binding mode. The editing domain is fixed tightly via hydrophobic interactions to the aminoacylation/tRNA-recognition domains, on the side opposite from that in threonyl-tRNA synthetase. A groove formed between the aminoacylation/tRNA-recognition domains and the editing domain appears to be an alternative tRNA-binding site, which might be used for the aminoacylation and/or editing reactions. Actually, the amino acid residues required for the G3:U70 recognition are mapped in this groove. The dimerization domain consists of helical and globular subdomains. The helical subdomain mediates dimerization by forming a helix-loop-helix zipper. The globular subdomain, which is important for the aminoacylation and editing activities, has a positively-charged face suitable for tRNA binding.

Distinct domains of tRNA synthetase recognize the same base pair

Synthesis of proteins containing errors (mistranslation) is prevented by aminoacyl transfer RNA synthetases through their accurate aminoacylation of cognate tRNAs and their ability to correct occasional errors of aminoacylation by editing reactions. A principal source of mistranslation comes from mistaking glycine or serine for alanine, which can lead to serious cell and animal pathologies, including neurodegeneration. A single specific G.U base pair (G3.U70) marks a tRNA for aminoacylation by alanyl-tRNA synthetase. Mistranslation occurs when glycine or serine is joined to the G3.U70-containing tRNAs, and is prevented by the editing activity that clears the mischarged amino acid. Previously it was assumed that the specificity for recognition of tRNA(Ala) for editing was provided by the same structural determinants as used for aminoacylation. Here we show that the editing site of alanyl-tRNA synthetase, as an artificial recombinant fragment, targets mischarged tRNA(Ala) using a structural motif unrelated to that for aminoacylation so that, remarkably, two motifs (one for aminoacylation and one for editing) in the same enzyme independently can provide determinants for tRNA(Ala) recognition. The structural motif for editing is also found naturally in genome-encoded protein fragments that are widely distributed in evolution. These also recognize mischarged tRNA(Ala). Thus, through evolution, three different complexes with the same tRNA can guard against mistaking glycine or serine for alanine.

Alanyl-tRNA synthetase crystal structure and design for acceptor-stem recognition

Early work on aminoacylation of alanine-specific tRNA (tRNA(Ala)) by alanyl-tRNA synthetase (AlaRS) gave rise to the concept of an early "second genetic code" imbedded in the acceptor stems of tRNAs. A single conserved and position-specific G:U base pair in the tRNA acceptor stem is the key identity determinant. Further understanding has been limited due to lack of a crystal structure of the enzyme. We determined a 2.14 A crystal structure of the 453 amino acid catalytic fragment of Aquifex aeolicus AlaRS. It contains the catalytic domain characteristic of class II synthetases, a helical domain with a hairpin motif critical for acceptor-stem recognition, and a C-terminal domain of a mixed alpha/beta fold. Docking of tRNA(Ala) on AlaRS shows critical contacts with the three domains, consistent with previous mutagenesis and functional data. It also suggests conformational flexibility within the C domain, which might allow for the positional variation of the key G:U base pair seen in some tRNA(Ala)s.

RNA recognition by designed peptide fusion creates "artificial" tRNA synthetase

The genetic code was established through aminoacylations of RNA substrates that emerged as tRNAs. The 20 aminoacyl-tRNA synthetases (one for each amino acid) are ancient proteins, the active-site domain of which catalyzes formation of an aminoacyl adenylate that subsequently reacts with the 3' end of bound tRNA. Binding of tRNA depends on idiosyncratic (to the particular synthetase) domains and motifs that are fused to or inserted into the conserved active-site domain. Here we take the domain for synthesis of alanyl adenylate and fuse it to "artificial" peptide sequences (28 aa) that were shown previously to bind to the acceptor arm of tRNAAla. Certain fusions confer aminoacylation activity on tRNAAla and on hairpin microhelices modeled after its acceptor stem. Aminoacylation was sensitive to the presence of a specific G:U base pair known to be a major determinant of tRNAAla identity. Aminoacylation efficiency and specificity also depended on the specific peptide sequence. The results demonstrate that barriers to RNA-specific aminoacylations are low and can be achieved by relatively simple peptide fusions. They also suggest a paradigm for rationally designed specific aminoacylations based on peptide fusions.

Four decades of structure determination by mass spectrometry: from alkaloids to heparin

The early (1950's and 1960's) use of mass spectrometry in natural products chemistry and its evolution to the present significance in biochemistry is recounted. This methodology allowed the facile and speedy determination of the structure of a number of indole alkaloids, such as sarpagine, quebrachamine, and two groups isolated from the roots of Aspidosperma quebracho blanco. At the same time, the first strategy for the sequencing of small peptides by mass spectrometry was demonstrated. It slowly advanced, over a period of two decades, to an important alternative of the ubiquitous automated Edman degradation. Further advances in methodology and instrumentation established mass spectrometry as today's indispensable tool for the characterization of proteins in biochemistry and biology. A new concept of the ionization of highly acidic compounds as the protonated complexes with basic peptides, which allows the accurate determination of the molecular weights of the former, a highly sensitive method for the sequencing of heparin fragments and related sulfated glycosaminoglycans was developed more recently.

Assembly of a catalytic unit for RNA microhelix aminoacylation using nonspecific RNA binding domains

An assembly of a catalytic unit for aminoacylation of an RNA microhelix is demonstrated here. This assembly may recapitulate a step in the historical development of tRNA synthetases. The class-defining domain of a tRNA synthetase is closely related to the primordial enzyme that catalyzed synthesis of aminoacyl adenylate. RNA binding elements are imagined to have been added so that early RNA substrates could be docked proximal to the activated amino acid. RNA microhelices that recapitulate the acceptor stem of modern tRNAs are potential examples of early substrates. In this work, we examined a fragment of Escherichia coli alanyl-tRNA synthetase, which catalyzes aminoacyl adenylate formation but is virtually inactive for catalysis of RNA microhelix aminoacylation. Fusion to the fragment of either of two unrelated nonspecific RNA binding domains activated microhelix aminoacylation. Although the fusion proteins lacked the RNA sequence specificity of the natural enzyme, their activity was within 1-2 kcal.mol(-1) of a truncated alanyl-tRNA synthetase that has aminoacylation activity sufficient to sustain cell growth. These results show that, starting with an activity for adenylate synthesis, barriers are relatively low for building catalytic units for aminoacylation of RNA helices.

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.

Alanyl-tRNA synthetase gene of the extreme acidophilic chemolithoautotrophic Thiobacillus ferrooxidans is highly homologous to alaS genes from all living kingdoms but cannot be transcribed from its promoter in Escherichia coli

The alaS gene of Thiobacillus ferrooxidans has been cloned and sequenced and its expression in Escherichia coli and T. ferrooxidans analysed. The same genomic organization to that in E. coli (recA-recX-alaS) has been found in T. ferrooxidans. The recA and alaS genes cannot be transcribed from their own promoters in E. coli. In addition to the well-known homology at the protein level between AlaS proteins from various organisms, a strong homology was found between all the known alaS genes from bacteria, archaea and eucarya. Two regions, one of which corresponds to the catalytic core, are particularly well-conserved at the nucleotide sequence level, a possible indication of strong constraints during evolution on these parts of the genes.

Human alanyl-tRNA synthetase: conservation in evolution of catalytic core and microhelix recognition

The class II Escherichia coli and human alanyl-tRNA synthetases cross-acylate their respective tRNAs and require, for aminoacylation, an acceptor helix G3:U70 base pair that is conserved in evolution. We report here the primary structure and expression in the yeast Pichia of an active human alanyl-tRNA synthetase. The N-terminal 498 amino acids of the 968-residue polypeptide have substantial (41%) identity with the E. coli protein. A closely related region encompasses the class-defining domain of the E. coli enzyme and includes the part needed for recognition of the acceptor helix. As a result, previously reported mutagenesis, modeling, domain organization, and biochemical characterization on the E. coli protein appear valid as a template for the human protein. In particular, we show that both the E. coli enzyme and the human enzyme purified from Pichia aminoacylate 9-base pair RNA duplexes whose sequences are based on the acceptor stems of either E. coli or human alanine tRNAs. In contrast, the sequences of the two enzymes completely diverge in an internal portion of the C-terminal half that is essential for tetramer formation by the E. coli enzyme, but that is dispensable for microhelix aminoacylation. This divergence correlates with the expressed human enzyme behaving as a monomer. Thus, the region of close sequence similarity may be a consequence of strong selective pressure to conserve the acceptor helix G3:U70 base pair as an RNA signal for alanine.

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.

Architectures of class-defining and specific domains of glutamyl-tRNA synthetase

The crystal structure of a class I aminoacyl-transfer RNA synthetase, glutamyl-tRNA synthetase (GluRS) from Thermus thermophilus, was solved and refined at 2.5 A resolution. The amino-terminal half of GluRS shows a geometrical similarity with that of Escherichia coli glutaminyl-tRNA synthetase (GlnRS) of the same subclass in class I, comprising the class I-specific Rossmann fold domain and the intervening subclass-specific alpha/beta domain. These domains were found to have two GluRS-specific, secondary-structure insertions, which then participated in the specific recognition of the D and acceptor stems of tRNA(Glu) as indicated by mutagenesis analyses based on the docking properties of GluRS and tRNA. In striking contrast to the beta-barrel structure of the GlnRS carboxyl-terminal half, the GluRS carboxyl-terminal half displayed an all-alpha-helix architecture, an alpha-helix cage, and mutagenesis analyses indicated that it had a role in the anticodon recognition.

Functional dissection of a predicted class-defining motif in a class II tRNA synthetase of unknown structure

A core of eight beta-strands and three alpha-helices was recently predicted for the active site domain of Escherichia coli alanyl-tRNA synthetase, an enzyme of unknown structure [Ribas de Pouplana, L1., Buechter, D. D., Davis, M. W., & Schimmel, P. (1993) Protein Sci. 2, 2259-2262; Shi, J.-P., Musier-Forsyth, K., & Schimmel, P. (1994) Biochemistry 26, 5312-5318]. A critical part of this predicted structure is two antiparallel beta-strands and an intervening loop that make up the second of three highly degenerate sequence motifs that are characteristic of the class II aminoacyl-tRNA synthetases. We present here an in vivo and in vitro analysis of 21 rationally designed mutations in the predicted 34-amino acid motif 2 of E. coli alanyl-tRNA synthetase. Although this motif in E. coli alanyl-tRNA synthetase is of a different size than and has only two sequence identities with the analogous motif in yeast aspartyl- and Thermus thermophilus seryl-tRNA synthetases, whose structures are known, the functional consequences of the mutations are explainable in terms of those structures. In particular, the analysis demonstrates the importance of the predicted motif 2 in adenylate formation, distinguishes between two similar, but distinct, predicted models for this motif, and distinguishes between the functional importance of two adjacent phenylalanines in a way that strongly supports the predicted structure. The results suggest that similar analyses will be generally useful in testing models for active site regions of other class II aminoacyl-tRNA synthetases of unknown structure.

The histidyl-tRNA synthetase from Streptococcus equisimilis: overexpression in Escherichia coli, purification, and characterization

We describe the high-level expression of the Streptococcus equisimilis histidyl-tRNA synthetase gene (hisS) in Escherichia coli and the purification and characterization of the gene product. Due to a lack of an efficient E. coli ribosome binding sequence in the hisS gene, the coding region was fused in-frame to the expression vector pT7-7, thereby creating a fusion gene construct (pT7-7recIII), which is under the control of a strong bacteriophage T7 promoter. Another construct (pT-7recII) was used for low level expression of the native histidyl-tRNA synthetase (HisRS). The plasmids were electroporated into E. coli HB101, which already contained pGP1-2. After temperature induction, the fusion HisRS, which has an extra 15 amino acids between the initiator Met and the second amino acid, Lys, was expressed at a level of approximately 18% of total cell protein (approximately 50 mg/liter of bacterial culture). The fusion HisRS was purified to > 99% by a combination of anion exchange and cation exchange chromatography of the S100 fraction. The predicted MWs of the native and fusion proteins are 47,932 and 49,717, respectively. The mass of the active fusion HisRS was estimated to be 94,000 Da by Sephacryl S-200 gel filtration chromatography and 108,200 Da by nondenaturing PAGE. Both methods show that the functional enzyme is a dimer of two identical subunits. SDS-PAGE analysis of purified fusion HisRS with or without reduction showed a single band of M(r) = 53.7 kDa.

Identification and molecular characterization of csrA, a pleiotropic gene from Escherichia coli that affects glycogen biosynthesis, gluconeogenesis, cell size, and surface properties

Current evidence suggests that a few global regulatory factors mediate many of the extensive changes in gene expression that occur as Escherichia coli enters the stationary phase. One of the metabolic pathways that is transcriptionally activated in the stationary phase is the pathway for biosynthesis of glycogen. To identify factors that regulate glycogen biosynthesis in trans, a collection of transposon mutants was generated and screened for mutations which independently increase or decrease glycogen levels and the expression of a plasmid-encoded glgC'-lacZ fusion. The glycogen excess mutation TR1-5 was found to be pleiotropic. It led to increased expression of the genes glgC (ADPglucose pyrophosphorylase) and glgB (glycogen branching enzyme), which are representative of two glycogen synthesis operons, and the gluconeogenic gene pckA (phosphoenolpyruvate carboxykinase), and it exhibited effects on cell size and surface (adherence) properties. The mutated gene was designated csrA for carbon storage regulator. Its effect on glycogen biosynthesis was mediated independently of cyclic AMP (cAMP), the cAMP receptor protein, and guanosine 3'-bisphosphate 5'-bisphosphate (ppGpp), which are positive regulators of glgC expression. A plasmid clone of the native csrA gene strongly inhibited glycogen accumulation and affected the ability of cells to utilize certain carbon sources for growth. Nucleotide sequence analysis, complementation experiments, and in vitro expression studies indicated that csrA encodes a 61-amino-acid polypeptide that inhibits glycogen biosynthesis. Computer-assisted data base searches failed to identify genes or proteins that are homologous with csrA or its gene product.

Molecular cloning, sequence, structural analysis and expression of the histidyl-tRNA synthetase gene from Streptococcus equisimilis

The histidyl-tRNA synthetase gene (hisS) from Streptococcus equisimilis was cloned and sequenced. The gene for this aminoacyl-tRNA synthetase has an open reading frame of 1278 nucleotides. The deduced amino acid sequence encodes a protein of 426 amino acids with MW = 47,932. The protein is predicted to be soluble with a pl = 5.27. The protein sequence has extensive overall identity/similarity with the Escherichia coli and the yeast histidyl-tRNA synthetases (approximately 58% and approximately 20%, respectively). A putative promoter for gene transcription lies within two hundred nucleotides of the polypeptide start codon. The enzyme was overexpressed, to a level of about 18% of total cellular protein, as a fusion protein (containing an additional 15 amino acids) in E. coli using the pT7 expression system containing the T7 RNA polymerase/promoter (Tabor and Richardson, Proc. Natl. Acad. Sci. U.S.A. 82:1074-1078, 1985). The predicted MW for the hisS gene product is in good agreement with the size of the fusion protein determined by SDS-PAGE (M(r) = 53,700). Amino acid sequencing of the intact fusion protein and proteolytic fragments confirmed the deduced sequence of the synthetase at many positions throughout the protein. The expressed protein catalyzed the specific aminoacylation of tRNA(His) in vitro.

Aminoacylation of RNA minihelices: implications for tRNA synthetase structural design and evolution

The genetic code is based on the aminoacylation of tRNA with amino acids catalyzed by the aminoacyl-tRNA synthetases. The synthetases are constructed from discrete domains and all synthetases possess a core catalytic domain that catalyzes amino acid activation, binds the acceptor stem of tRNA, and transfers the amino acid to tRNA. Fused to the core domain are additional domains that mediate RNA interactions distal to the acceptor stem. Several synthetases catalyze the aminoacylation of RNA oligonucleotide substrates that recreate only the tRNA acceptor stems. In one case, a relatively small catalytic domain catalyzes the aminoacylation of these substrates independent of the rest of the protein. Thus, the active site domain may represent a primordial synthetase in which polypeptide insertions that mediate RNA acceptor stem interactions are tightly integrated with determinants for aminoacyl adenylate synthesis. The relationship between nucleotide sequences in small RNA oligonucleotides and the specific amino acids that are attached to these oligonucleotides could constitute a second genetic code.

A metal-binding motif implicated in RNA recognition by an aminoacyl-tRNA synthetase and by a retroviral gene product

A randomly generated mutation in Escherichia coli alanine tRNA synthetase compensates for a mutation in its cognate tRNA. The enzyme's mutation occurs next to a Cys-X2-Cys-X6-His-X2-His metal-binding motif that is distinct from the zinc finger motif found in some DNA-binding proteins. Instead, the synthetase's metal binding domain resembles the Cys-X2-Cys-X4-His-X4-Cys metal-binding domain of the gag gene product of retroviruses. For Ala-tRNA synthetase, the metal bound at the Cys-His motif is important specifically for the tRNA-dependent step of catalysis, and the enzyme-tRNA interaction is dependent on the geometry of metal co-ordination to the enzyme. These data, and the demonstrated sensitivity of RNA packaging to mutations in the metal-binding domain of the gag gene product of retroviruses, suggest that an aminoacyl-tRNA synthetase and retroviruses have adopted a related metal-binding motif for RNA recognition.

Evidence for a "cysteine-histidine box" metal-binding site in an Escherichia coli aminoacyl-tRNA synthetase

Escherichia coli alanyl-tRNA synthetase contains the sequence Cys-X2-Cys-X6-His-X2-His. This motif is distinct from the zinc fingers of DNA-binding proteins but has some similarity to the Cys-X2-Cys-X4-His-X4-Cys zinc-binding motif of retroviral gag proteins, where it has a role in RNA packaging. In Ala-tRNA synthetase, this sequence is located in an amino-terminal domain which has the site for docking the acceptor end of the tRNA near the bound aminoacyl adenylate and is immediately adjacent in the sequence to the location of a mutation that affects the specificity of tRNA recognition. We show here that Ala-tRNA synthetase contains approximately 1 mol of zinc/mol of polypeptide and that addition of the zinc chelator 1,10-phenanthroline inhibits its aminoacylation activity. Conservative mutations of specific cysteine or histidine residues in the "Cys-His box" destabilize and inactivate the enzyme, whereas mutations of intervening amino acids do not inactivate. The possibility that this motif can bind zinc (or cobalt) was demonstrated with a synthetic 22 amino acid peptide that is based on the sequence of the alanine enzyme. The peptide-cobalt complex has the spectral characteristics of tetrahedral coordination geometry. The results establish that the Cys-His box motif of Ala-tRNA synthetase has the potential to form a specific complex with zinc (at least in the context of a synthetic peptide analogue) and suggest that this motif is important for enzyme stability/activity.

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.

Aerobic inactivation of Rhizobium meliloti NifA in Escherichia coli is mediated by lon and two newly identified genes, snoB and snoC

The Rhizobium meliloti NifA protein is an oxygen-sensitive transcriptional regulator of nitrogen fixation genes. Regulation of NifA activity by oxygen occurs at the transcriptional level through fixLJ and at the posttranslational level through the sensitivity of NifA to oxygen. We have previously reported that the NifA protein is sensitive to oxygen in Escherichia coli as well as in R. meliloti. To investigate whether the posttranslational regulation of NifA is dependent on host factors conserved between R. meliloti and E. coli, we carried out a Tn5 mutagenesis of E. coli and isolated mutants with increased NifA activity under aerobic conditions. Fifteen insertion mutations occurred at three unlinked loci. One locus is the previously characterized lon gene; the other two loci, which we have named snoB and snoC, define previously uncharacterized E. coli genes. The products of snoC and lon affect the rate of NifA degradation, whereas the product of snoB may affect both NifA degradation and inactivation. A snoB lon double mutant showed a higher level of NifA accumulation than did a lon mutant, suggesting that the snoB product affects the ability of NifA to be degraded by a lon-independent pathway. The effects of a snoC mutation and lon mutation were not additive, suggesting that the snoC and lon products function in the same degradative pathway.

Enzymatic aminoacylation of an eight-base-pair microhelix with histidine

The major determinant for the identity of alanine tRNAs is a single base pair in the acceptor helix that is proximal to the site of amino acid attachment. A 7-base-pair microhelix that recreates the acceptor helix can be charged with alanine. No other examples of charging of small helices with specific amino acids have been reported, to our knowledge. We show here that a 13-base-pair and an 8-base-pair hairpin helix that reconstruct a domain and subdomain, respectively, of histidine tRNAs can be charged with histidine. We also show that transplantation of a base pair that is unique to histidine tRNAs is sufficient to consider histidine acceptance on a domain and subdomain of alanine tRNA. Both alanine and histidine aminoacyl-tRNA synthetases retain specificity for their cognate synthetic substrates. Alanine- and histidine-specific microhelices may resemble a system that arose early in the evolution of charging and coding.

Mutations conferring resistance to azide in Escherichia coli occur primarily in the secA gene

Mutant strains of Escherichia coli were screened for the ability to grow on L agar plates containing 3.4 or 4.6 mM sodium azide. Most mutants had mutations located in the leucine region, presumably at the azi locus. Two of these mutants were found to have a mutation in the secA gene, but expression of the resistance phenotype also required the presence of upstream gene X. While a plasmid carrying the X-secA mutant gene pair was able to confer azide resistance to a sensitive host, a similar plasmid harboring the wild-type secA allele rendered a resistant strain sensitive to azide, indicating codominance of the two alleles. That azide inhibits SecA is consistent with the fact that SecA has ATPase activity, an activity that is often prone to inhibition by azide.

Synthetic peptide model of an essential region of an aminoacyl-tRNA synthetase

A 40 amino acid sequence of the unsolved structure of Escherichia coli alanine-tRNA synthetase is essential for tRNA binding and encodes an immunological determinant that cross-reacts with antibodies raised against a eukaryote (insect Bombyx mori) alanine enzyme. The secondary structure of this sequence is predicted to be an amphiphilic alpha-helix that includes one aspartyl and eight glutamyl side chain carboxyl groups. The antibody reactivity and the conformation of a synthetic peptide model of this region (Glu346 to Ser385) were investigated. In addition, double Arg----Gln and Leu----Ala substitutions were separately placed in the enzyme on the hydrophilic and hydrophobic face, respectively, of the predicted helix. These mutations conserve the polar/nonpolar character of each face and retain the potential for helix formation. Circular dichroism spectra of the synthetic peptide model demonstrate the potential for amphiphilic helix formation for the segment from Glu346 to Ser385. The behavior of the mutations in the enzyme, together with earlier data and immunological assays presented here, suggests that one face of the putative helix is an antigenic region of the surface of the enzyme where it contributes to the interaction with alanine tRNA and that the specific sequence of the helix is an important determinant of enzyme stability.

Homology of lysS and lysU, the two Escherichia coli genes encoding distinct lysyl-tRNA synthetase species

In Escherichia coli, two distinct lysyl-tRNA synthetase species are encoded by two genes: the constitutive lysS gene and the thermoinducible lysU gene. These two genes have been isolated and sequenced. Their nucleotide and deduced amino acid sequences show 79% and 88% identity, respectively. Codon usage analysis indicates the lysS product being more efficiently translated than the lysU one. In addition, the lysS sequence exactly coincides with the sequence of herC, a gene which is part of the prfB-herC operon. In contrast to the recent proposal of Gampel and Tzagoloff (1989, Proc. Natl. Acad. Sci. USA 86, 6023-6027), the lysU sequence is distinct from the open reading frame located adjacent to frdA, although large homologies are shared by these two genes.

Molecular dissection of a transfer RNA and the basis for its identity

The recognition of transfer RNAs (tRNAs) by aminoacyl tRNA synthetases establishes the connection between amino acids and trinucleotides. However, for E. coli alanine tRNA the trinucleotide sequence which specifies alanine is not important for recognition. Instead a single base pair is a major determinant for the identity of this tRNA. Even a synthetic RNA microhelix with seven base pairs can be aminoacylated if it includes the major determinant.