The glycyl-tRNA synthetase of Chlamydia trachomatis.

Aminoacyl-tRNA synthetases specifically charge tRNAs with their cognate amino acids. A prototype for the most complex aminoacyl-tRNA synthetases is the four-subunit glycyl-tRNA synthetase from Escherichia coli, encoded by two open reading frames. We examined the glycyl-tRNA synthetase gene from Chlamydia trachomatis, a genetically isolated bacterium, and identified only a single open reading frame for the chlamydial homolog (glyQS). This is the first report of a prokaryotic glycyl-tRNA synthetase encoded by a single gene.     

Equilibrium unfolding of Bombyx mori glycyl-tRNA synthetase

Unfolding of Bombyx mori glycyl-tRNA synthetase was examined by multiple spectroscopic techniques. Tryptophan fluorescence of wild type enzyme and an N-terminally truncated form (N55) increased at low concentrations of urea or guanidine-HCl followed by a reduction in intensity at intermediate denaturant concentrations; a transition at higher denaturant was detected as decreased fluorescence intensity and a red-shifted emission. Solute quenching of fluorescence indicated that tryptophans become progressively solvent-exposed during unfolding. Wild type enzyme had stronger negative CD bands between 220 and 230 nm than the mutant, indicative of greater alpha-helical content. Urea or guanidine-HCl caused a reduction in ellipticity at 222 nm at low denaturant concentration with the wild type enzyme, a transition that is absent in the mutant; both enzymes exhibited a cooperative transition at higher denaturant concentrations. Both enzymes dissociate to monomers in 1.5 m urea. Unfolding of wild type enzyme is described by a multistate unfolding and a parallel two state unfolding; the two-state component is absent in the mutant. Changes in spectral properties associated with unfolding were largely reversible after dilution to low denaturant. Unfolding of glycyl-tRNA synthetase is complex with a native state, a native-like monomer, partially unfolded states, and the unfolded state.     

Thermodynamic characterization of the multivalent binding of chartreusin to DNA

Characterization of the thermodynamics of DNA– drug interactions is a very useful part in rational drug design. Isothermal titration calorimetry (ITC), differential scanning calorimetry (DSC) and UV melting experiments have been used to analyze the multivalent (intercalation plus minor groove) binding of the antitumor antibiotic chartreusin to DNA. Using DNA UV melting studies in the presence of the ligand and the binding enthalpy determined by ITC, we determined that the binding constant for the interaction was 3.6 × 10⁵ M^–1 at 20°C, in a solution containing 18 mM Na⁺. The DNA–drug interaction was enthalpy driven, with a ΔH_b of –7.07 kcal/mol at 20°C. Binding enthalpies were determined by ITC in the 20–35°C range and used to calculate a binding-induced change in heat capacity (ΔCp) of –391 cal/mol K. We have obtained a detailed thermodynamic profile for the interaction of this multivalent drug, which makes possible a dissection of ΔG_obs into the component free energy terms. The hydrophobic transfer of the chartreusin chromophore from the solution to the DNA intercalating site is the main contributor to the free energy of binding.     

Saccharomyces cerevisiae possesses a stress-inducible glycyl-tRNA synthetase gene

Aminoacyl-tRNA synthetases are a large family of housekeeping enzymes that are pivotal in protein translation and other vital cellular processes. Saccharomyces cerevisiae possesses two distinct nuclear glycyl-tRNA synthetase (GlyRS) genes, GRS1 and GRS2. GRS1 encodes both cytoplasmic and mitochondrial activities, while GRS2 is essentially silent and dispensable under normal conditions. We herein present evidence that expression of GRS2 was drastically induced upon heat shock, ethanol or hydrogen peroxide addition, and high pH, while expression of GRS1 was somewhat repressed under those conditions. In addition, GlyRS2 (the enzyme encoded by GRS2) had a higher protein stability and a lower K(M) value for yeast tRNA(Gly) under heat shock conditions than under normal conditions. Moreover, GRS2 rescued the growth defect of a GRS1 knockout strain when highly expressed by a strong promoter at 37 °C, but not at the optimal temperature of 30 °C. These results suggest that GRS2 is actually an inducible gene that may function to rescue the activity of GRS1 under stress conditions.     

Inactivation of a glycyl-tRNA synthetase leads to an arrest in plant embryo development.

Embryo formation is the first patterning process during vegetative plant growth. Using transposons as insertional mutagens in Arabidopsis, we identified the mutant edd1 that shows embryo-defective development. The insertion mutation is lethal, arresting embryo growth between the globular and heart stages of embryonic development. The mutant phenotype cosegregates with a transposed Dissociation element. Sequences flanking the transposed element were isolated and used to isolate a full-length cDNA clone representing the wild-type EDD1 gene. Complementation of the mutant through Agrobacterium-mediated gene transfer of an EDD1 wild-type copy as well as loss of the transposon concomitant with phenotypic reversion demonstrated that the transposon had caused the mutation. Based on homology to Escherichia coli, the EDD1 gene is predicted to encode a novel glycyl-tRNA synthetase (GlyRS) that has not been identified previously in higher plants. An N-terminal portion of the plant protein is able to direct a marker protein into pea chloroplasts. Thus, the gene identified by the embryo-defective insertion mutation encodes a GlyRS homolog, probably acting within the plastidic compartment.     

Thermodynamic and kinetic characterization of ligand binding to the purine riboswitch aptamer domain

Riboswitches are cis-acting genetic regulatory elements found commonly in bacterial mRNAs that consist of a metabolite-responsive aptamer domain coupled to a regulatory switch. Purine riboswitches respond to intracellular concentrations of either adenine or guanine/hypoxanthine to control gene expression. The aptamer domain of the purine riboswitch contains a pyrimidine residue (Y74) that forms a Watson-Crick base-pairing interaction with the bound purine nucleobase ligand that discriminates between adenine and guanine. We sought to understand the structural basis of this specificity and the mechanism of ligand recognition by the purine riboswitch. Here, we present the 2,6-diaminopurine-bound structure of a C74U mutant of the xpt-pbuX guanine riboswitch, along with a detailed thermodynamic and kinetic analysis of nucleobase recognition by both the native and mutant riboswitches. These studies demonstrate clearly that the pyrimidine at position 74 is the sole determinant of purine riboswitch specificity. In addition, the mutant riboswitch binds adenine and adenine derivatives well compared with the guanine-responsive riboswitch. Under our experimental conditions, 2,6-diaminopurine binds the RNA with DeltaH=-40.3 kcal mol(-1), DeltaS=-97.6 cal mol(-1)K(-1), and DeltaG=-10.73 kcal mol(-1). A kinetic determination of the slow rate (0.15 x 10(5)M(-1)s(-1) and 2.1 x 10(5)mM(-1)s(-1) for 2-aminopurine binding the adenine-responsive mutant riboswitch and 7-deazaguanine-binding guanine riboswitch, respectively) of association under varying experimental conditions allowed us to propose a mechanism for ligand recognition by the purine riboswitch. A conformationally dynamic unliganded state for the binding pocket is stabilized first by the Watson-Crick base pairing between the ligand and Y74, and by the subsequent ordering of the J2/3 loop, enclosing the ligand within the three-way junction.     

Thermodynamic characterization of substrate and inhibitor binding to Trypanosoma brucei 6-phosphogluconate dehydrogenase

6-Phosphogluconate dehydrogenase is a potential target for new drugs against African trypanosomiasis. Phosphorylated aldonic acids are strong inhibitors of 6-phosphogluconate dehydrogenase, and 4-phospho-d-erythronate (4PE) and 4-phospho-d-erythronohydroxamate are two of the strongest inhibitors of the Trypanosoma brucei enzyme. Binding of the substrate 6-phospho-d-gluconate (6PG), the inhibitors 5-phospho-d-ribonate (5PR) and 4PE, and the coenzymes NADP, NADPH and NADP analogue 3-amino-pyridine adenine dinucleotide phosphate to 6-phospho-d-gluconate dehydrogenase from T. brucei was studied using isothermal titration calorimetry. Binding of the substrate (K(d) = 5 microm) and its analogues (K(d) =1.3 microm and K(d) = 2.8 microm for 5PR and 4PE, respectively) is entropy driven, whereas binding of the coenzymes is enthalpy driven. Oxidized coenzyme and its analogue, but not reduced coenzyme, display a half-site reactivity in the ternary complex with the substrate or inhibitors. Binding of 6PG and 5PR poorly affects the dissociation constant of the coenzymes, whereas binding of 4PE decreases the dissociation constant of the coenzymes by two orders of magnitude. In a similar manner, the K(d) value of 4PE decreases by two orders of magnitude in the presence of the coenzymes. The results suggest that 5PR acts as a substrate analogue, whereas 4PE mimics the transition state of dehydrogenation. The stronger affinity of 4PE is interpreted on the basis of the mechanism of the enzyme, suggesting that the inhibitor forces the catalytic lysine 185 into the protonated state.     

Thermodynamic characterization of interleukin-8 monomer binding to CXCR1 receptor N-terminal domain

Chemokines elicit their function by binding receptors of the G-protein-coupled receptor class, and the N-terminal domain (N-domain) of the receptor is one of the two critical ligand-binding sites. In this study, the thermodynamic basis for binding of the chemokine interleukin-8 (IL-8) to the N-domain of its receptor CXCR1 was characterized using isothermal titration calorimetry. We have shown previously that only the monomer of IL-8, and not the dimer, functions as a high-affinity ligand, so in this study we used the IL-8(1-66) deletion mutant which exists as a monomer. Calorimetry data indicate that the binding is enthalpically favored and entropically disfavored, and a negative heat capacity change indicates burial of hydrophobic residues in the complex. A characteristic feature of chemokine receptor N-domains is the large number of acidic residues, and experiments using different buffers show no net proton transfer, indicating that the CXCR1 N-domain acidic residues are not protonated in the binding process. CXCR1 N-domain peptide is unstructured in the free form but adopts a more defined structure in the bound form, and so binding is coupled to induction of the structure of the N-domain. Measurements in the presence of the osmolyte, trimethylamine N-oxide, which induces the structure of unfolded proteins, show that formation of the coupled N-domain structure involves only small DeltaH and DeltaS changes. These results together indicate that the binding is driven by packing interactions in the complex that are enthalpically favored, and are consistent with the observation that the N-domain binds in an extended form and interacts with multiple IL-8 N-loop residues over a large surface area.     

Enthalpy of nucleotides binding to myosin.

The enthalpies of binding adenosine 5'-diphosphate (ADP) and 5'-adenylyl imidodiphosphate [AMP-P(NH)P] to rabbit skeletal myosin have been measured in Pipes and Tris buffers at pH 7.8 and 15 degrees C. For ADP the enthalpy of binding was exothermic, whereas the enthalpy of binding AMP-P(NH)P, a nonhydrolyzable ATP analogue, was small and endothermic. For the reaction of ATP and myosin, the development of enthalpy was resolved into two phases: a fast endothermic phase, which is the summation of binding and hydrolysis, and a slow exothermic phase, which is associated with product-release steps. These results are discussed in terms of their implications for energy transduction.     

Thermodynamic parameters of the binding of retinol to binding proteins and to membranes

Retinol (vitamin A alcohol) is a hydrophobic compound and distributes in vivo mainly between binding proteins and cellular membranes. To better clarify the nature of the interactions of retinol with these phases which have a high affinity for it, the thermodynamic parameters of these interactions were studied. The temperature-dependence profiles of the binding of retinol to bovine retinol binding protein, bovine serum albumin, unilamellar vesicles of dioleoylphosphatidylcholine, and plasma membranes from rat liver were determined. It was found that binding of retinol to retinol binding protein is characterized by a large increase in entropy (T delta S degrees = +10.32 kcal/mol) and no change in enthalpy. Binding to albumin is driven by enthalpy (delta H degrees = -8.34 kcal/mol) and is accompanied by a decrease in entropy (T delta S degrees = -2.88 kcal/mol). Partitioning of retinal into unilamellar vesicles and into plasma membranes is stabilized both by enthalpic (delta H degrees was -3.3 and -5.5 kcal/mol, respectively) and by entropic (T delta S degrees was +4.44 and +2.91 kcal/mol, respectively) components. The implications of these finding are discussed.     

Thermodynamic characterization of ethidium bromide binding to a unique site on yeast tRNAphe.

A self-consistent thermodynamic characterization of the binding of ethidium to yeast phenylalanine-specific tRNA at 25°C, pH 7.0, in 11 nM MgCl₂, 375 nM NaCl, and 25 mM sodium phosphate has been obtained. Two ethidium molecules bind per tRNA under these conditions. The stronger site has a dissociation constant equal to 1.9 ± 0.5 μM and ΔH_dis°′ = 12 ± 1 Kcal/mol, and the weaker sites has a dissociation constant equal to 24 ± 9 μM and ΔH_dis°′ = 8.9 ± 1.5 Kcal/mol. The average calorimetric ΔH_dis°′ for the to sites 10.6 ± 0.4 kcal/mol. The thermodynamics of binding to the stranger sites are most probably the thermodynamics of interaction between A·U (6) and A·U (7), the unique site identified by Jones and Kearns. The binding is enthalpically driven and classical hydrophobic interactions do not appear to be important in the binding reaction.     

Analysis of the binding of phenylalanine to phenylalanyl-tRNA synthetase

Using the complete rate equation for the PP_i-ATP exchange reaction at equilibrium, the dissociation constants of phenylalanine (10^?5m), phenylalanine butyl ester (8 × 10^?5m), benzyl alcohol (6 × 10^?4m), phenylalaninol (2 × 10^?4m), hydrocinnamic acid (3 × 10^?3m) and glycine (>1 m) with the phenylalanyl-tRNA synthetase (Escherichia coli K12) were determined. Taking the model of Koshland (1962) for the estimation of the configurational free energy change due to proximity and orientation, and decomposing the process of binding into several thermodynamic steps, the contribution to binding of the benzyl group, glycine unit, protonated amino group, carboxylate group and joint interactions were estimated. The results are: (1) the standard free energy contributions for binding phenylalanine are benzyl group (?8.2 kcal/mol), glycine unit (?2.5 kcal/mol), protonated amino group (?0.8 kcal/mol) and carboxylate group (1 kcal/mol). (2) The standard free energy change due to the change in the interaction between the protonated amino group and carboxylate group when they are transferred from the aqueous environment to the enzyme environment is ?2.7 kcal/mol. (3) A dissociation constant for glycine of 7.5 m is calculated without the hypothesis that a conformational change occurs in the enzyme when the benzyl unit of phenylalanine binds, permitting an interaction of the enzyme with the protonated amino and/or carboxylate groups.The detection of E·AA² and E·ATP shows that a sequential addition of substrates is not necessary for binding. A comparison of the dissociation constants of E·AA (10^?5m), E·ATP (1.5 × 10^?3m), E·PP (5.5 × 10^?4m), E·I (8 × 10^?5m) and the mixed complexes E·I·ATP (6 × 10^?8m²), E·I·PP (5 × 10^?8m²) and E·AA·PP (7 × 10^?9m²), with phenylalanine butyl ester as the inhibitor, indicates no strong interaction between the binding of ATP or PP_i with the binding of phenylalanine.     

Mechanism of the difference in the binding affinity of E. coli tRNAGln to glutaminyl-tRNA synthetase caused by noninterface nucleotides in variable loop

Aminoacyl-tRNA synthetases (ARSs) distinguish their cognate tRNAs from many other kinds of tRNAs, despite the very similar tertiary structures of tRNAs. Many researchers have supported the view that this recognition is achieved by intermolecular interactions between tRNA and ARS. However, one of the aptamers of Escherichia coli glutamine specific tRNA, var-AGGU, has a higher affinity to ARS than the wild-type, although the sequence difference only lies in the variable loop located on the opposite side of the binding interface with ARS. To understand the reason for the difference in affinity, we did molecular dynamics simulations on tRNAs and their complexes with ARS. We calculated the enthalpic and entropic contributions to the binding free energy with the molecular mechanics-Poisson-Boltzmann/surface area method and found that the entropic difference plays an important role in the difference in binding free energies. During the molecular dynamics simulations, dynamic rearrangements of hydrogen bonds occurred in the tertiary core region of the wild-type tRNA, whereas they were not observed in the free var-AGGU simulation. Since the internal mobility was suppressed upon complex formation with ARS, the entropy loss in the wild-type was larger than that of the aptamer. We therefore concluded that the sequence difference in the variable loop caused the difference in the internal mobility of the tertiary core region tRNAs and led to the difference in the affinity to ARS through the entropy term.     

Internal structural features of E. coli glycyl-tRNA synthetase examined by subunit polypeptide chain fusions

In contrast to most aminoacyl-tRNA synthetases which are monomers or oligomers of a single polypeptide, Escherichia coli glycyl-tRNA synthetase has an alpha-2, beta-2 structure. The enzyme requires both subunits for catalysis of either adenylate or aminoacyl-tRNA synthesis. The head-to-tail arrangement of the alpha- and beta-chain coding regions in the genome suggests that the two-subunit protein may be tantamount to a single chain. We fused the carboxyl terminus of the alpha-chain to the amino terminus of the beta-chain, through a short peptide linker. Five different amino acid substitutions were placed in the linker. In all instances, the fusion polypeptide is stable in maxicell extracts. In a glyS null strain, a gene encoding any of the fusion proteins substitutes for the wild-type gene. Assays confirm that, in vitro, the engineered polypeptide fusion is active to within 2- to 3-fold of the wild-type, unfused chains. Oligomers of the fusion protein are observed and may be required for activity. Because the creation and limited manipulation of the artificial peptide linker region does not destroy the activity, we also conclude that the C-terminal part of the alpha-chain and the amino-terminal part of the beta-chain are not important for activity.     

Two enzymically active forms of glycyl-tRNA synthetase from Bacillus brevis. Purification and properties.

Using sucrose density centrifugation and gel filtration of a 105000 X g supernatant of Bacillus brevis two enzymic activities of glycyl-tRNA synthetase were separated. Enzyme catalyzing the aminoacylation of tRNA (E1) elutes in a high-molecular-weight region. Enzyme active in glycylhydroxamate formation (E2) elutes from a Sephadex gel column and sediments in sucrose density gradient in a region of relatively low molecular weight. The presence of two enzymic activities does not depend on the method of cell disruption; their proportion does not change when protease inhibitor (diisopropylphosphorofluoridate) is added to the extraction buffer. Both E1 and E2 were purified to a nearly homogeneous state. Sedimentation coefficients (sw,20) were found to be 8.6 S and 3.6 S and molecular weights 226000 and 66000 for E1 and E2, respectively. During storage, E1 dissociates into two components, one of which has electrophoretic mobility identical to E2. The molecular weight of the other component is about 1600000. Electrophoresis of E1 in the presence of sodium dodecylsulfate reveals two bands corresponding to molecular weights of 81000 and 30000. Under these conditions, E2 dissociates into a polypeptide with a molecular weight of 30000. Valine was found to be the N-terminal amino acid for E2 and both valine and glutamic acid were N-terminal amino acids for E1. It is concluded that E1 is a tetrameric protein consisting of two large and two small subunits (alpha2beta2). E2 is a component of E1 with a structural formula alpha2.     

One of two genes encoding glycyl-tRNA synthetase in Saccharomyces cerevisiae provides mitochondrial and cytoplasmic functions

In the yeast Saccharomyces cerevisiae, two genes (GRS1 and GRS2) encode glycyl-tRNA synthetase (GlyRS1 and GlyRS2, respectively). 59% of the sequence of GlyRS2 is identical to that of GlyRS1. Others have proposed that GRS1 and GRS2 encode the cytoplasmic and mitochondrial enzymes, respectively. In this work, we show that GRS1 encodes both functions, whereas GRS2 is dispensable. In addition, both cytoplasmic and mitochondrial phenotypes of the knockout allele of GRS1 in S. cerevisiae are complemented by the expression of the only known gene for glycyl-tRNA synthetase in Schizosaccharomyces pombe. Thus, a single gene for glycyl-tRNA synthetase likely encodes both cytoplasmic and mitochondrial activities in most or all yeast. Phylogenetic analysis shows that GlyRS2 is a predecessor of all yeast GlyRS homologues. Thus, GRS1 appears to be the result of a duplication of GRS2, which itself is pseudogene-like.     

Thermodynamics of nucleotides binding to phosphorylase b.

The effects of several chemical modifications in the AMP molecule on its interaction with phosphorylase b are examined by microcalorimetry, equilibrium dialysis, light scattering and ultracentrifuge experiments. In this work we report the results obtained for eight AMP analogues corresponding to different substituents in the puric base or in the ribose, or to different positions of the phosphate. The thermodynamic properties of the interaction between the phosphorylase b and the above mentioned nucleotides are also reported. The following conclusions were obtained: a) Except for IMP and 2'dIMP all the nucleotides studied clearly show two types of binding sites in the enzyme. b) The interaction of the nucleotide with its weaker affinity binding site is highly dependent upon chemical alterations in the puric base. c) Both the amino group in C(6) and the N(1) of the adenine in the AMP seem to play an important role in the conformational transitions induced by the nucleotide on the enzyme. d) The tetramerization of phosphorylase b in the presence of 10(-2) M AMP and in the conditions of the ultracentrifuge experiments is drastically affected by modifications in the ribose-phosphate part of the AMP molecule.     

Equilibrium binding of nicotinamide nucleotides to lactate dehydrogenases

1. No discontinuities were observed during the continuous titration with NADH of the lactate dehydrogenases of ox muscle, pig heart, pig muscle, rabbit muscle, dogfish muscle or lobster tail muscle. The binding was monitored by either the enhanced fluorescence of bound NADH or the quenched fluorescence of the protein. A single macroscopic dissociation constant, independent of protein concentration, could be used to describe the binding to each enzyme, and there was no need to postulate the involvement of molecular relaxation effects. 2. The affinity for NADH decreases only threefold between pH6 and 8.5. Above pH9 the affinity decreases more rapidly with increasing pH and is consistent with a group of about pK9.5 facilitating binding. Muscle enzymes bind NADH more weakly than does the pig heart enzyme. 3. Increasing temperature and increasing concentrations of ethanol both weaken NADH binding. 4. NADH binding is weakened by increasing ionic strength. NaCl is more effective than similar ionic strengths derived from sodium phosphate or sodium pyrophosphate. 5. Commercial NAD(+) quenches the protein fluorescence of the heart and muscle isoenzymes. Highly purified NAD(+) does not, and its binding was monitored by competition for the NADH-binding sites. A single macroscopic dissociation constant is sufficient to describe NAD(+) binding at the concentrations tested. The dissociation constant is about 0.3mm and is not sensitive to changed ionic strength and to changed pH in the range pH6-8.5.