Mechanism of the ribosome-dependent uncoupled GTPase reaction catalyzed by polypeptide chain elongation factor G.

At low NH4-+ concentrations, 50S ribosomal subunits from E. coli were fully active in the absence of 30S ribosomal subunits, in forming a complex with the polypeptide chain elongation factor G (EF-G) and guanine nucleotide (ternary complex formation), and also in supporting EF-G dependent hydrolysis of GTP (uncoupled GTPase reaction). However, both activities were markedly inhibited on increasing the concentration of the monovalent cation, and at 160 mM NH4-+, the optimal concentration for polypeptide synthesis in a cell-free system, almost no activity was observed with 50S ribosomes alone. It was found that the inhibitory effect of NH4-+ was reversed by addition of 30S subunits. Thus, at 160 mM NH4-+, only 70S ribosomes were active in supporting the above two EF-G dependent reactions, whereas at 20 mM NH4-+, 50S ribosomes were almost as active as 70S ribosomes. Kinetic studies on inhibition by NH4-+ of the formation of 50S ribosome-EF-G-guanine nucleotide complex, indicated that the inhibition was due to reduction in the number of active 50S ribosomes which were capable of interacting with EF-G and GTP at higher concentrations of NH4-+. The inhibitory effects of NH4-+ on ternary complex formation and the uncoupled GTPase reaction were markedly influenced by temperature, and were much greater at 0 degrees than at 30 degrees. A conformational change of 50S subunits through association with 30S subunits is suggested.     

A model for the aminoacyl-tRNA binding site of eukaryotic elongation factor 1 alpha.

Eukaryotic elongation factor 1 alpha (EF-1 alpha) binds all the aminoacyl-tRNAs except the initiator tRNA in a GTP-dependent manner. While the GTP binding site is delineated by the three GTP binding consensus elements, less is known about the aminoacyl-tRNA binding sites. In order to better understand this site, we have initiated cross-linking and protease mapping studies of the EF-1 alpha-GTP-aminoacyl-tRNA complex. Two different chemical cross-linking reagents, trans-diaminedichloroplatinum(II) and diepoxybutane, were used to cross-link four different aminoacyl-tRNA species to EF-1 alpha. A series of peptides were obtained, located predominantly in domains II and III. The ability of aminoacyl-tRNA to protect protease digestion sites was also monitored, and domain II was found to be protected from digestion by aminoacyl-tRNA. Last, an aminoacyl-tRNA analog with a reactive group on the aminoacyl side chain, N epsilon-bromoacetyl-Lys-tRNA, was cross-linked to EF-1 alpha. This reagent cross-liked to histidine 296 in a GTP-dependent manner and thus localizes the aminoacyl group adjacent to domain II. A model is developed for aminoacyl-tRNA binding to EF-1 alpha based on its similarity to the prokaryotic factor EF-Tu, for which an x-ray crystal structure is available.     

The site of interaction of aminoacyl-tRNA with elongation factor Tu

We have used RNases T1, T2 and A to digest two aminoacyl-tRNAs, Escherichia coli Phe-tRNAPhe and E. coli Met- tRNAMetm both in the naked forms and in ternary complexes with E. coli elongation factor Tu (EF-Tu) and GTP. An analysis of the 'footprinting' results has led to an interpretation that has localized the part of the three-dimensional structure of aminoacyl-tRNA covered by the protein in the ternary complex. In terms of the three-dimensional structure of tRNA established for yeast tRNAPhe, EF-Tu covers the aa-end, aa-stem, T-stem, and extra loop on the side of the L-shaped tRNA that exposes the extra loop.     

Analysis of binding site hot spots on the surface of Ras GTPase

We have recently discovered an allosteric switch in Ras, bringing an additional level of complexity to this GTPase whose mutants are involved in nearly 30% of cancers. Upon activation of the allosteric switch, there is a shift in helix 3/loop 7 associated with a disorder to order transition in the active site. Here, we use a combination of multiple solvent crystal structures and computational solvent mapping (FTMap) to determine binding site hot spots in the “off” and “on” allosteric states of the GTP-bound form of H-Ras. Thirteen sites are revealed, expanding possible target sites for ligand binding well beyond the active site. Comparison of FTMaps for the H and K isoforms reveals essentially identical hot spots. Furthermore, using NMR measurements of spin relaxation, we determined that K-Ras exhibits global conformational dynamics very similar to those we previously reported for H-Ras. We thus hypothesize that the global conformational rearrangement serves as a mechanism for allosteric coupling between the effector interface and remote hot spots in all Ras isoforms. At least with respect to the binding sites involving the G domain, H-Ras is an excellent model for K-Ras and probably N-Ras as well. Ras has so far been elusive as a target for drug design. The present work identifies various unexplored hot spots throughout the entire surface of Ras, extending the focus from the disordered active site to well-ordered locations that should be easier to target.     

The class II aminoacyl-tRNA synthetases and their active site: Evolutionary conservation of an ATP binding site

Previous sequence analyses have suggested the existence of two distinct classes of aminoacyl-tRNA synthetase. The partition was established on the basis of exclusive sets of sequence motifs (Eriani et al. [1990] Nature 347:203–306). X-ray studies have now well defined the structural basis of the two classes: the class I enzymes share with dehydrogenases and kinases the classic nucleotide binding fold called the Rossmann fold, whereas the class II enzymes possess a different fold, not found elsewhere, built around a six-stranded antiparallel -sheet. The two classes of synthetases catalyze the same global reaction that is the attachment of an amino acid to the tRNA, but differ as to where on the terminal adenosine of the tRNA the amino acid is placed: class I enzymes act on the 2 hydroxyl whereas the class II enzymes prefer the 3 hydroxyl group. The three-dimensional structure of aspartyl-tRNA synthetase from yeast, a typical class II enzyme, is described here, in relation to its function. The crucial role of the sequence motifs in substrate binding and enzyme structure is high-lighted. Overall these results underline the existence of an intimate evolutionary link between the aminoacyl-tRNA synthetases, despite their actual structural diversity.Based on a presentation made at a workshop— Aminoacyl-tRNA Synthetases and the Evolution of the Genetic Code—held at Berkeley, CA, July 17–20, 1994 Correspondence to: G. Eriani     

Electrostatic potential of aminoacyl-tRNA synthetase navigates tRNA on its pathway to the binding site

In the first stage of a diffusion-controlled enzymatic reaction, aminoacyl-tRNA synthetases (aaRSs) interact with cognate tRNAs forming non-specific encounters. The aaRSs catalyzing the same overall aminoacylation reaction vary greatly in subunit organization, structural domain composition and amino acid sequence. The diffusional association of aaRS and tRNA was found to be governed by long-range electrostatic interactions when the homogeneous negative potential of tRNA fits to the patches of positive potential produced by aaRS; one patch for each tRNA substrate molecule. Considering aaRS as a molecule with anisotropic reactivity and on the basis of continuum electrostatics and Smoluchowski's theory, the reaction conditions for tRNA-aaRS diffusional encounters were formulated. The domains, categorized as enzymatically relevant, appeared to be non-essential for field sculpturing at long distances. On the other hand, a set of complementary domains exerts primary control on the aaRS isopotential surface formation. Subdividing the aaRS charged residues into native, conservative and non-conservative subsets, we evaluated the contribution of each group to long-range electrostatic potential. Surprisingly, the electrostatic potential landscapes generated by native and non-conservative subsets are fairly similar, thus suggesting the non-conservative subset is developed specifically for efficient tRNA attraction.     

Sodium binding site of factor Xa: role of sodium in the prothrombinase complex

The nature of residue 225 on a consensus loop in serine proteases determines whether a protease can bind Na(+). Serine proteases with a Pro at this position are unable to bind Na(+), but those with a Tyr or Phe can bind Na(+). Factor Xa (FXa), the serine protease of the prothrombinase complex, contains a Tyr at this position. Na(+) is also known to stimulate the amidolytic activity of FXa toward cleavage of small synthetic substrates, but the role of Na(+) in the prothrombinase complex has not been investigated. In this study, we engineered a Gla-domainless form of FX (GDFX) in which residue Tyr(225) was replaced with a Pro. We found that Na(+) stimulated the cleavage rate of chromogenic substrates by FXa or GDFXa approximately 8-24-fold with apparent dissociation constants [K(d(app))] of 37 and 182 mM in the presence and absence of Ca(2+), respectively. In contrast, Na(+) minimally affected the cleavage rate of these substrates by the mutant, and no K(d(app)) for Na(+) binding to the mutant could be estimated. Unlike the wild-type enzyme, the reactivity of the mutant with antithrombin was independent of Na(+) and impaired approximately 32-fold. Ca(2+) improved the reactivity of the mutant with antithrombin approximately 5-fold. Affinity of the mutant for binding to factor Va was weakened and its ability to activate prothrombin was severely impaired. Further studies with the wild-type prothrombinase complex revealed that FXa binds to factor Va with a similar K(d(app)) of 1. 1-1.8 nM in the presence of Na(+), K(+), Li(+), Ch(+), and Tris(+) and that the catalytic efficiency of prothrombinase is enhanced less than 1.5-fold by the specific effect of Na(+) in the reaction buffer. These results suggest that (1) the loop including residue 225 (225-loop) is a Na(+) binding site in FXa, (2) the Na(+)- and Ca(2+)-binding loops of FXa are allosterically linked, and (3) the Tyr conformer of the 225-loop is critical for factor Xa function; however, both Na(+)-bound and Na(+)-free forms of factor Xa in the prothrombinase complex can efficiently activate prothrombin.     

Guanyl cyclase activity in the EF-T elongation factor of Escherichia coli]

Highly purified EF-Ts from E. coli does contain guanylate cyclase activity, which is absent from other purified transfer factors, such as EF-Tu and EF-G. Guanylate cyclase activity has been characterized by its sensitivity to inhibitors and substrate specificity. Although the physicochemical properties of guanylate cyclase are closely related to those of EF-Ts, it does not appear to be a contaminant of this transfer factor, but a specific enzyme. The possible role of guanylate cyclase in protein synthesis is discussed.     

Definition of a factor Va binding site in factor Xa

We reported previously that residue 347 in activated fX (fXa) contributes to binding of the cofactor, factor Va (fVa) (Rudolph, A. E., Porche-Sorbet, R. and Miletich, J. P. (2000) Biochemistry 39, 2861-2867). Four additional residues that participate in fVa binding have now been identified by mutagenesis. All five resulting fX species, fX(R306A), fX(E310N), fX(R347N), fX(K351A), and fX(K414A), are activated and inhibited normally. However, the rate of inhibition by antithrombin III in the presence of submaximal concentrations of heparin is reduced for all the enzymes. In the absence of fVa, all of the enzymes bind and activate prothrombin similarly except fXa(E310N), which has a reduced apparent affinity ( approximately 3-fold) for prothrombin compared with wild type fXa (fXa(WT)). In the absence of phospholipid, fVa enhances the catalytic activity of fXa(WT) significantly, but the response of the variant enzymes was greatly diminished. On addition of 100 nm PC:PS (3:1) vesicles, fVa enhanced fXa(WT), fXa(R306A), and fXa(E310N) similarly, whereas fXa(R347N), fXa(K351A), and fXa(K414A) demonstrated near-normal catalytic activity but reduced apparent affinity for fVa under these conditions. All enzymes function similarly to fXa(WT) on activated platelets, which provide saturating fVa on an ideal surface. Loss of binding affinity for fVa as a result of the substitutions in residues Arg-347, Lys-351, and Lys-414 was verified by a competition binding assay. Thus, Arg-347, Lys-351, and Lys-414 are likely part of a core fVa binding site, whereas Arg-306 and Glu-310 serve a less critical role.     

The stereochemical course of the ribosome-dependent GTPase reaction of elongation factor G from Escherichia coli

The stereochemical course of the ribosome-dependent GTPase reaction of elongation factor G from Escherichia coli has been determined. Guanosine 5'-(gamma-thio)triphosphate stereospecifically labeled with 17O and 18O in the gamma-position was hydrolyzed in the presence of the elongation factor and ribosomes. The configuration of the product, inorganic [16O, 17O, 18O]thiophosphate ws analyzed by 31P NMR after its stereospecific incorporation into adenosine 5'-(beta-thio)triphosphate. The analysis showed that the hydrolysis proceeds with inversion of configuration at the transferred phosphorus atom. It is therefore likely that the hydrolysis occurs in a single step by direct, in-line transfer of the phosphorus from GDP to a water oxygen, without a phosphoenzyme intermediate.     

Mapping of the factor Xa binding site on factor Va by site-directed mutagenesis

Activated coagulation factor V functions as a cofactor to factor Xa in the conversion of prothrombin to thrombin. Based on the introduction of extra carbohydrate side chains in recombinant factor V, we recently proposed several regions in factor Va to be important for factor Xa binding. To further define which residues are important for factor Xa binding, we prepared fifteen recombinant factor V variants in which clusters of charged amino acid residues were mutated, mainly to alanines. The factor V variants were expressed in COS-1 cells, and their functional properties evaluated in a prothrombinase-based assay, as well as in a direct binding test. Four of the factor V variants, 501A/510A/511D, 501A/510A/511D/513A, 513A/577A/578A, and 501A/510A/511D/513A/577A/578A exhibited markedly reduced factor Xa-cofactor activity tested in the prothrombinase assay, and reduced binding affinity as judged by the direct binding assay. These factor Va variants were normally cleaved at Arg-506 by activated protein C, and the interaction between the factor Xa-factor Va complex and prothrombin was unaffected by the introduced mutations. Based on the integration of all available data, we propose a key factor Xa binding surface to be centered on Arg-501, Arg-510, Ala-511, Asp-513, Asp-577, and Asp-578 in the factor Va A2 domain. These residues form an elongated charged factor Xa binding cluster on the factor Va surface.     

The mechanism of action of virginiamycin M on the binding of aminoacyl-tRNA to ribosomes directed by elongation factor Tu

Mitochondrial DNA from Ustilago cynodontis has been investigated in several of its properties. Its dG + dC content is equal to 33.5%; its buoyant density (1.698 g/cm3) is higher, by 5 mg/cm3, and its melting temperature (82.5 degrees C) is lower than expected for a bacterial DNA having the same base composition; the first derivative of its melting curve indicates a large compositional heterogeneity, its molarity of elution from hydroxyapatite is high, 0.28 M phosphate, and allows its partial separation from nuclear DNA. Degradation by micrococcal nuclease indicates that about 25% of the DNA is formed by stretches having no more than 15% dG + dC. Finally, the unit size of mitochondrial genome is about 50 X 10(6). In most of its properties, the mitochondrial genome of U. cynodontis presents strong analogies with that of Saccharomyces cerevisiae. A parallel investigation on mitochondrial DNA from Acanthamoeba castellanii which has as genome unit size of only 27 X 10(6), has shown that this shares with the former the dG + dC content (32.9%), the melting temperature (82.5 degrees C), a large compositional heterogeneity and a very similar pattern of micrococcal nuclease degradation; its buoyant density (1.692 g/cm3) and its molarity of elution from hydroxyapatite (0.25 M phosphate) are, however, normal, probably because of a different short-sequence pattern and the fact that its dA + dT-rich stretches are shorter, on the average.     

Assessing the role of tryptophan residues in the binding site

Instead of looking at the interfacial area as a measure of the extent of a protein--protein recognition site, a new procedure has been developed to identify the importance of a specific residue, namely tryptophan, in the binding process. Trp residues which contribute more towards the free energy of binding have their accessible surface area reduced, on complex formation, for both the main-chain and side-chain atoms, whereas for the less important residues the reduction is restricted only to the aromatic ring of the side chain. The two categories of residues are also distinguished by the presence or absence of hydrogen bonds involving the Trp residue in the complex. A comparison of the observed change in the accessible surface area with the value calculated using an analytical expression provides another way of characterizing the Trp residues critical for binding and this has been used to identify such residues involved in binding non-proteinaceous molecules in protein structures.     

Porphyrin binding and distortion and substrate specificity in the ferrochelatase reaction: the role of active site residues

The specific insertion of a divalent metal ion into tetrapyrrole macrocycles is catalyzed by a group of enzymes called chelatases. Distortion of the tetrapyrrole has been proposed to be an important component of the mechanism of metallation. We present the structures of two different inhibitor complexes: (1) N-methylmesoporphyrin (N-MeMP) with the His183Ala variant of Bacillus subtilis ferrochelatase; (2) the wild-type form of the same enzyme with deuteroporphyrin IX 2,4-disulfonic acid dihydrochloride (dSDP). Analysis of the structures showed that only one N-MeMP isomer out of the eight possible was bound to the protein and it was different from the isomer that was earlier found to bind to the wild-type enzyme. A comparison of the distortion of this porphyrin with other porphyrin complexes of ferrochelatase and a catalytic antibody with ferrochelatase activity using normal-coordinate structural decomposition reveals that certain types of distortion are predominant in all these complexes. On the other hand, dSDP, which binds closer to the protein surface compared to N-MeMP, does not undergo any distortion upon binding to the protein, underscoring that the position of the porphyrin within the active site pocket is crucial for generating the distortion required for metal insertion. In addition, in contrast to the wild-type enzyme, Cu²⁺-soaking of the His183Ala variant complex did not show any traces of porphyrin metallation. Collectively, these results provide new insights into the role of the active site residues of ferrochelatase in controlling stereospecificity, distortion and metallation.     

Significance of the third tRNA binding site, the E site, on E. coli ribosomes for the accuracy of translation: an occupied E site prevents the binding of non-cognate aminoacyl-tRNA to the A site.

The E site (exit site for deacyl-tRNA) has been shown to be allosterically linked to the A site (aminoacyl-tRNA binding site), in that occupation of the E site reduces the affinity of the A site, and vice versa, whereas the intervening peptidyl-tRNA binding site (P site) keeps its high affinity. Here the question is analysed of whether or not the low affinity state of the A site caused by an occupied E site is of importance for the ribosomal accuracy of the aminoacyl-tRNA selection. In a poly(U) dependent system with high accuracy in poly(Phe) synthesis, the acceptance of the cognate ternary complex Phe-tRNA--EF-Tu--GTP (which has the correct anticodon with respect to the codon at the A site) was compared with the competing acceptance of ternary complexes with near-cognate Leu-tRNA(Leu) (which has a similar anticodon) or non-cognate Asp-tRNA(Asp) (which has a dissimilar anticodon), by monitoring the formation of AcPhePhe, AcPheLeu or AcPheAsp, respectively. Cognate (but not near-cognate) occupation of the E site reduced synthesis of the 'wrong' dipeptide AcPheLeu only marginally relative to that of the cognate AcPhe2, whereas the formation of AcPheAsp was decreased as much as 14-fold, thereby reducing it to the background level. It follows that the allosteric interplay between E and A sites, i.e. the low affinity of the A site induced by the occupation of the E site, excludes the interference of non-cognate complexes in the decoding process and thus reduces the number of aminoacyl-tRNA species competing for A site binding by an order of magnitude.(ABSTRACT TRUNCATED AT 250 WORDS)