Properties of isolated domains of the elongation factor Tu from Thermus thermophilus HB8

Differential Contribution of Protein Factors and 70S Ribosome to Elongation

The growth of the polypeptide chain occurs due to the fast and coordinated work of the ribosome and protein elongation factors, EF-Tu and EF-G. However, the exact contribution of each of these components in the overall balance of translation kinetics remains not fully understood. We created an in vitro translation system Escherichia coli replacing either elongation factor with heterologous thermophilic protein from Thermus thermophilus. The rates of the A-site binding and decoding reactions decreased an order of magnitude in the presence of thermophilic EF-Tu, indicating that the kinetics of aminoacyl-tRNA delivery depends on the properties of the elongation factor. On the contrary, thermophilic EF-G demonstrated the same translocation kinetics as a mesophilic protein. Effects of translocation inhibitors (spectinomycin, hygromycin B, viomycin and streptomycin) were also similar for both proteins. Thus, the process of translocation largely relies on the interaction of tRNAs and the ribosome and can be efficiently catalysed by thermophilic EF-G even at suboptimal temperatures.

Elfamycins: inhibitors of elongation factor-Tu

Elfamycins are a relatively understudied group of antibiotics that target the essential process of translation through impairment of EF-Tu function. For the most part, the utility of these compounds has been as laboratory tools for the study of EF-Tu and the ribosome, as their poor pharmacokinetic profile and solubility has prevented implementation as therapeutic agents. However, due to the slowing of the antibiotic pipeline and the rapid emergence of resistance to approved antibiotics, this group is being reconsidered. Some researchers are using screens for novel naturally produced variants, while others are making directed, systematic chemical improvements on publically disclosed compounds. As an example of the latter approach, a GE2270 A derivative, LFF571, has completed phase 2 clinical trials, thus demonstrating the potential for elfamycins to become more prominent antibiotics in the future.

Water around thermophilic proteins: the role of charged and apolar atoms

The thermal response of three proteins with mesophilic, thermophilic and hyperthermophilic character hints at the essential role played in thermostability by the protein-water interface. The formation of spanning water clusters enveloping the macromolecule and their resistance to thermal stress is shown to correlate with the charge distribution at the protein surface; in particular our findings suggest an effective role of the superficial charge distribution in stabilizing the global connectivity of the hydration water.

Molecular paleoscience: systems biology from the past

Experimental paleomolecular biology, paleobiochemistry, and paleogenetics are closely related emerging fields that infer the sequences of ancient genes and proteins from now-extinct organisms, and then resurrect them for study in the laboratory. The goal of paleogenetics is to use information from natural history to solve the conundrum of modern genomics: How can we understand deeply the function of biomolecular structures uncovered and described by modern chemical biology? Reviewed here are the first 20 cases where biomolecular resurrections have been achieved. These show how paleogenetics can lead to an understanding of the function of biomolecules, analyze changing function, and put meaning to genomic sequences, all in ways that are not possible with traditional molecular biological studies.

Explanation of the stability of thermophilic proteins based on unique micromorphology

Two mesophilic/thermophilic variants of the G-domain of the elongation factor Tu were studied via molecular dynamics simulations. By analyzing the simulation data via the Voronoi space tessellation, we have found that the two proteins have the same macromolecular packing, while the water-exposed surface area is larger for the thermophile. A larger coordination with water is probably due to a peculiar corrugation of the exposed surface of this species. From an enthalpic point of view, the thermophile shows a larger number of intramolecular hydrogen bonds, stronger electrostatic interactions, and a flatter free-energy landscape. Overall, the data suggest that the specific hydration state enhances macromolecular fluctuations but, at the same time, increases thermal stability.

Random gene dissection: a tool for the investigation of protein structural organization

To investigate the domain structure of proteins and the function of individual domains, proteins are usually subjected to limited proteolysis, followed by isolation of protein fragments and determination of their functions. We have developed an approach we call random gene dissection (RGD) for the identification of functional protein domains and their interdomain regions as well as their in vivo complementing fragments. The approach was tested on a two-domain protein, the type IIS restriction endonuclease BfiI. The collection of BfiI insertional mutants was screened for those that are endonucleolytically active and thus induce the SOS DNA repair response. Sixteen isolated mutants of the wild-type specificity contained insertions that were dispersed in a relatively large region of the target recognition domain. They split the gene into two complementing parts that separately were unable to induce the SOS DNA repair response. In contrast, all 19 mutants of relaxed specificity contained the cassette inserted into a very narrow interdomain region that connects BfiI domains responsible for DNA recognition and for cleavage. As expected, only the N-terminal fragment of BfiI was required to induce SOS response. Our results demonstrate that RGD can be used as a general method to identify complementing fragments and functional domains in enzymes.

Thermostability of multidomain proteins: elongation factors EF-Tu from Escherichia coli and Bacillus stearothermophilus and their chimeric forms

Recombinant mesophilic Escherichia coli (Ec) and thermophilic Bacillus stearothermophilus (Bst) elongation factors EF-Tus, their isolated G-domains, and six chimeric EF-Tus composed of domains of either EF-Tu were prepared, and their GDP/GTP binding activities and thermostability were characterized. BstEF-Tu and BstG-domain bound GDP and GTP with affinities in nanomolar and submicromolar ranges, respectively, fully comparable with those of EcEF-Tu. In contrast, the EcG-domain bound the nucleotides with much lower, micromolar affinities. The exchange of domains 2 and 3 had essentially no effect on the GDP-binding activity; all complexes of chimeric EF-Tus with GDP retained K(d) values in the nanomolar range. The final thermostability level of either EF-Tu was the result of a cooperative interaction between the G-domains and domains 2 + 3. The G-domains set up a "basic" level of the thermostability, which was approximately 20 degrees C higher with the BstG-domain than with the EcG-domain. This correlated with the growth temperature optimum difference of both bacteria and two distinct thermostabilization features of the BstG-domain: an increase of charged residues at the expense of polar uncharged residues (CvP bias), and a decrease in the nonpolar solvent-accessible surface area. Domains 2 + 3 contributed by further stabilization of alpha-helical regions and, in turn, the functions of the G-domains to the level of the respective growth temperature optima. Their contributions were similar irrespective of their origin but, with Ecdomains 2 + 3, dependent on the guanine nucleotide binding state. It was lower in the GTP conformation, and the mechanism involved the destabilization of the alpha-helical regions of the G-domain by Ecdomain 2.

Inferring the palaeoenvironment of ancient bacteria on the basis of resurrected proteins

Features of the physical environment surrounding an ancestral organism can be inferred by reconstructing sequences of ancient proteins made by those organisms, resurrecting these proteins in the laboratory, and measuring their properties. Here, we resurrect candidate sequences for elongation factors of the Tu family (EF-Tu) found at ancient nodes in the bacterial evolutionary tree, and measure their activities as a function of temperature. The ancient EF-Tu proteins have temperature optima of 55-65 degrees C. This value seems to be robust with respect to uncertainties in the ancestral reconstruction. This suggests that the ancient bacteria that hosted these particular genes were thermophiles, and neither hyperthermophiles nor mesophiles. This conclusion can be compared and contrasted with inferences drawn from an analysis of the lengths of branches in trees joining proteins from contemporary bacteria, the distribution of thermophily in derived bacterial lineages, the inferred G + C content of ancient ribosomal RNA, and the geological record combined with assumptions concerning molecular clocks. The study illustrates the use of experimental palaeobiochemistry and assumptions about deep phylogenetic relationships between bacteria to explore the character of ancient life.

Valine 114 replacements in archaeal elongation factor 1 alpha enhanced its ability to interact with aminoacyl-tRNA and kirromycin

Valine 114 in the D(109)AAILVVA sequence of elongation factor 1alpha from the archaeon Sulfolobus solfataricus (SsEF-1alpha) was substituted with an acidic (V114E), basic (V114K), or cavity-forming (V114A) residue, and the effects on the biochemical properties of the factor were investigated. This sequence is well-conserved among most of eukaryal and eubacterial counterparts, and in the three-dimensional structure of SsEF-1alpha, V114 is located in a hydrophobic pocket near the first GDP-binding consensus sequence G(13)XXXXGK[T,S] [Vitagliano, L., Masullo, M., Sica, F., Zagari, A., and Bocchini, V. (2001) EMBO J. 20, 5305-5311]. These mutants displayed functions absent in the wild-type factor. In fact, although they exhibited a rate in poly(Phe) incorporation almost identical to that of SsEF-1alpha, V114K and V114A exhibited an affinity for GDP and GTP higher and a capability to bind heterologous aa-tRNA stronger than that elicited by SsEF-1alpha but similar to that of eubacterial EF-Tu. V114E instead displayed not only a weaker binding capability for aa-tRNA but also a lower affinity for GDP. The intrinsic GTPase activity of V114E was drastically reduced compared to those of SsEF-1alpha, V114K, and V114A. Interestingly, the decreased intrinsic GTPase activity of V114E was partially restored by kirromycin, an effect already observed for the G13A mutant of SsEF-1alpha [Masullo, M., Cantiello, P., de Paola, B., Catanzano, F., Arcari, P., and Bocchini, V. (2002) Biochemistry 41, 628-633]. Finally, the V114A substitution showed only a marginal effect on both the thermostability and thermophilicity of SsEF-1alpha, whereas V114K and V114E replacements strongly destabilized the molecule.

Microcalorimetric study of elongation factor Tu from Thermus thermophilus in nucleotide-free, GDP and GTP forms and in the presence of elongation factor Ts

Elongation factor (EF) Tu undergoes profound nucleotide-dependent conformational changes in its functional cycle. The thermodynamic parameters of the different Thermus thermophilus EF-Tu forms, its domains I, II/III and III, were determined by microcalorimetry. Thermal transitions of the EF-Tu.GDP and EF-Tu.guanosine-5'-[beta,gamma-imido]triphosphate have a cooperative two-state character. Nucleotide removal affected the cooperativity of the thermal transition of EF-Tu. Microcalorimetric measurements of nucleotide-free EF-Tu and its separated domains showed that domains II/III have the main stabilizing role for the whole protein. Despite the fact that strong interactions between elongation factors Tu and Ts from T. thermophilus at 20 degrees C exist, the thermal transition of neither protein in the complex was significantly affected.

Stability studies of FhuA, a two-domain outer membrane protein from Escherichia coli

FhuA (MM 78.9 kDa) is an Escherichia coli outer membrane protein that transports iron coupled to ferrichrome and is the receptor for a number of bacteriophages and protein antibiotics. Its three-dimensional structure consists of a 22-stranded beta-barrel lodged in the membrane, extracellular hydrophilic loops, and a globular domain (the "cork") located within the beta-barrel and occluding it. This unexpected structure raises questions about the connectivity of the different domains and their respective roles in the different functions of the protein. To address these questions, we have compared the properties of the wild-type receptor to those of a mutated FhuA (FhuA Delta) missing a large part of the cork. Differential scanning calorimetry experiments on wild-type FhuA indicated that the cork and the beta-barrel behave as autonomous domains that unfold at 65 and 75 degrees C, respectively. Ferrichrome had a strong stabilizing effect on the loops and cork since it shifted the first transition to 71.4 degrees C. Removal of the cork destabilized the protein since a unique transition at 61.6 degrees C was observed even in the presence of ferrichrome. FhuA Delta showed an increased sensitivity to proteolysis and to denaturant agents and an impairment in phage T5 and ferrichrome binding.

Psychrophilic elongation factor Tu from the antarctic Moraxella sp. Tac II 25: biochemical characterization and cloning of the encoding gene

The elongation factor Tu was isolated from a psychrophilic eubacterial Antarctic Moraxella strain (MoEF-Tu) and its molecular and functional properties were determined. It catalyzed the synthesis of poly(Phe) and bound specifically guanine nucleotides with an affinity for GDP about 12-fold higher than that for GTP. The affinity toward guanine nucleotides was lower than that of other eubacterial EF-Tu. The intrinsic GTPase activity of MoEF-Tu was hardly detectable but was accelerated by 2 orders of magnitude in the presence of the antibiotic kirromycin (GTPase(k)). Such a property resembled Escherichia coli EF-Tu (EcEF-Tu) even though the affinity of MoEF-Tu for the antibiotic was lower. MoEF-Tu showed a thermophilicity higher than that of EcEF-Tu; its temperature for half-denaturation was 44 degrees C. The MoEF-Tu encoding gene corresponding to E. coli tufA was cloned and sequenced. The translated protein had a calculated molecular weight of 43 288 and contained the GTP-binding sequence motifs. Concerning its primary structure, MoEF-Tu showed sequence identity with E. coli and Thermus thermophilus EF-Tu equal to 84% and 74%, respectively, while the identity with EF-1 alpha from the archaeon Sulfolobus solfataricus was equal to 32%.

Interaction of fMet-tRNAfMet and fMet-AMP with the C-terminal domain of Thermus thermophilus translation initiation factor 2

Two polypeptides resistant against proteolytic digestion were identified in Thermus thermophilus translation initiation factor 2 (IF2): the central part of the protein (domains II/III), and the C-terminal domain (domain IV). The interaction of intact IF2 and the isolated proteolytic fragments with fMet-tRNAfMet was subsequently characterized. The isolated C-terminal domain was as effective in binding of the 3' end of fMet-tRNAf Met as intact IF2. N-Formylation of Met-tRNAfMet was required for its efficient binding to the C-terminal domain. This suggests that the interaction between the C-terminal domain and the 3' end of fMet-tRNAfMet is responsible for the recognition of fMet-tRNAfMet by IF2 during translation initiation. Moreover, it was demonstrated that fMet-AMP is a minimal ligand of IF2. fMet-AMP inhibits fMet-tRNAfMet binding to IF2 as well as the activity of IF2 in the stimulation of ApUpG-dependent ribosomal binding of fMet-tRNAf Met. Specific interaction of fMet-AMP with IF2 was demonstrated by 1H-NMR spectroscopy. These findings indicate that fMet-AMP and the 3' terminal fMet-adenosine of fMet-tRNAfMet use the same binding site on the C-terminal domain of IF2 and imply that the interaction between the C-terminal domain and the 3' end of fMet-tRNAfMet is primarily responsible for the fMet-tRNAfMet binding and recognition by IF2.

Functionally accepted insertions of proteins within protein domains

Experiments were designed to explore the tolerance of protein structure and folding to very large insertions of folded protein within a structural domain. Dihydrofolate reductase and beta-lactamase have been inserted in four different positions of phosphoglycerate kinase. The resultant chimeric proteins are all overexpressed, and the host as well as the inserted partners are functional. Although not explicitly designed, functional coupling between the two fused partners was observed in some of the chimeras. These results show that the tolerance of protein structures to very large structured insertions is more general than previously expected and supports the idea that the natural sequence continuity of a structural domain is not required for the folding process. These results directly suggest a new experimental approach to screen, for example, for folded protein in randomized polypeptide sequences.

A chimeric elongation factor containing the putative guanine nucleotide binding domain of archaeal EF-1 alpha and the M and C domains of eubacterial EF-Tu

A recombinant chimeric elongation factor containing the region of EF-1 alpha from Sulfolobus solfataricus harboring the site for GDP and GTP binding and GTP hydrolysis (SsG) and domains M and C of Escherichia coli EF-Tu (EcMC) was studied. SsG-EcMC did not sustain poly(Phe) synthesis in either S. solfataricus or E. coli assay system. This was probably due to the inability of the chimera to interact with aa-tRNA. The three-dimensional modeling of SsG-EcMC indicated only small structural differences compared to the Thermus aquaticus EF-Tu in the ternary complex with aa-tRNA and GppNHp, which did not account for the observed inability to interact with aa-tRNA. The addition of the nucleotide exchange factor SsEF-1 beta was not required for poly(Phe) synthesis since the chimera was already able to exchange [(3)H]GDP for GTP at very high rate even at 0 degrees C. Compared to that of SsEF-1 alpha, the affinity of the chimera for guanine nucleotides was increased and the k(cat) of the intrinsic GTPase was 2-fold higher. The heat stability of SsG-EcMC was 3 and 13 degrees C lower than that displayed by SsG and SsEF-1alpha, respectively, but 30 degrees C higher than that of EcEF-Tu. This pattern remained almost the same if the melting curves of the proteins being investigated were considered instead. The chimeric elongation factor was more thermophilic than SsG and SsEF-1 alpha up to 70 degrees C; at higher temperatures, inactivation occurred.

Conservation of the amino-terminal epitope of elongation factor Tu in eubacteria and Archaea

An epitope of elongation factor Tu (EF-Tu), which is found in organisms in both the bacterial and archaeal domains, was recently defined by mAb 900. To localize the conserved epitope within the EF-Tu molecule and to determine its sequence, SPOTScan analysis of synthetic peptides, Western blot analysis of purified EF-Tu domains and site-directed mutagenesis studies were used. Analysis of mAb 900 binding to overlapping 15-mer peptides encompassing the complete sequence of EF-Tu of Escherichia coli was inconclusive, suggesting three distinct regions may be epitopes. Western blot analysis of EF-Tu domains 1-3 of Thermus thermophilus suggested that the epitope was located at the N terminus. This was confirmed by site-directed mutagenesis of EF-Tu domain 1 of Mycoplasma hominis. By C-terminal truncation of the N-terminal 15-mer peptide the epitope was mapped to EF-Tu residues 1-6. Replacement of each of the residues in the epitope peptide demonstrated that only positions 5 and 6 were indispensable for antibody binding. These data provide evidence that the highly conserved epitope recognized by mAb 900 in the bacterial and archaeal domains is located at the very end of the N terminus of the EF-Tu molecule.

In vitro selected RNA molecules that bind to elongation factor Tu

RNA molecules which bind to elongation factor Tu from T. thermophilus were isolated from a pool of ribooligonucleotides with a randomized sequence region. These RNAs interact with elongation factor Tu in both the GTP and the GDP form. A slight preference for the GTP form of the protein was observed. The isolated RNA aptamers compete with each other for a common binding site on elongation factor Tu. This binding site is different from the binding site for aminoacyl-tRNA or the binding site for elongation factor Ts and is located on domain II of elongation factor Tu. The selected RNAs do not bind to elongation factor G. The EF-Tu binding RNAs share a short consensus sequence, 5'-ACCGAAG-3', which was also found in the alpha-sarcin domain of T. thermophilus23S rRNA. The isolated RNAs have a hairpin structure with the 5'-ACCGAAG-3' sequence located in non-base-paired regions. Chemical probing and deletion experiments indicate that the consensus sequence is required for the interaction with elongation factor Tu.

Functional role of the noncatalytic domains of elongation factor Tu in the interactions with ligands

Elongation factor (EF) Tu from Escherichia coli contains three domains, of which domain 1 (N-terminal domain) harbors the site for nucleotide binding and GTP hydrolysis. To analyze the function of domains 2 [middle (M) domain] and 3 [C-terminal (C) domain], EF-Tu(DeltaM) and EF-Tu(DeltaC) were engineered as GST-fused products and purified. Circular dichroism and thermostability showed that both constructs have conserved organized structures. Though inactive in poly(Phe) synthesis the two constructs could bind GDP and GTP with comparable micromolar affinities. Therefore, like the isolated N-terminal domain, they had lost a typical feature of EF-Tu, the >100 times stronger affinity for GDP than for GTP. EF-Tu(DeltaM) and EF-Tu(DeltaC) had an intrinsic GTPase activity comparable to that of wild-type EF-Tu. Ribosomes did not stimulate the GTPase activity of either factor, while kirromycin increased the GTPase activity of both constructs, particularly of EF-Tu(DeltaC), to a level, however, much lower than that of the intact molecule. The interaction with aa-tRNA of both mutants was >90% reduced. As a major result, their GDP-bound form could efficiently respond to EF-Ts. All four EF-Tu-specific antibiotics [kirromycin, pulvomycin, GE2270 A (=MDL 62 879), and enacyloxin IIa] retarded significantly the dissociation of EF-Tu(DeltaC).GTP, showing the same kind of effect as on EF-Tu.GTP, but they were little active on EF-Tu(DeltaM). GTP. Like EF-Tu(DeltaC).GTP, EF-Tu(DeltaM).GTP was, however, able to bind efficiently kirromycin and enacyloxin IIa, as determined via competition with EF-Ts. Together, these results enlight selective functions of domains 2 and 3, particularly toward the interaction with EF-Ts and antibiotics, and emphasize their functional cooperativity for an efficient interaction of EF-Tu with ribosomes and aa-tRNA and for maintaining the differential affinity for GTP and GDP.

Domain structure and intramolecular regulation of dynamin GTPase

Dynamin is a 100 kDa GTPase required for receptor-mediated endocytosis, functioning as the key regulator of the late stages of clathrin-coated vesicle budding. It is specifically targeted to clathrin-coated pits where it self-assembles into 'collars' required for detachment of coated vesicles from the plasma membrane. Self-assembly stimulates dynamin GTPase activity. Thus, dynamin-dynamin interactions are critical in regulating its cellular function. We show by crosslinking and analytical ultracentrifugation that dynamin is a tetramer. Using limited proteolysis, we have defined structural domains of dynamin and evaluated the domain interactions and requirements for self-assembly and GTP binding and hydrolysis. We show that dynamin's C-terminal proline- and arginine-rich domain (PRD) and dynamin's pleckstrin homology (PH) domain are, respectively, positive and negative regulators of self-assembly and GTP hydrolysis. Importantly, we have discovered that the alpha-helical domain interposed between the PH domain and the PRD interacts with the N-terminal GTPase domain to stimulate GTP hydrolysis. We term this region the GTPase effector domain (GED) of dynamin.

Characterization of the interaction between the restriction endonuclease McrBC from E. coli and its cofactor GTP

McrBC, a GTP-dependent restriction enzyme from E. coli K-12, cleaves DNA containing methylated cytosine residues 40 to 80 residues apart and 3'-adjacent to a purine residue (PumCN40-80PumC). The presence of the three consensus sequences characteristic for guanine nucleotide binding proteins in one of the two subunits of McrBC suggests that this subunit is responsible for GTP binding and hydrolysis. We show here that (i) McrB binds GTP with an affinity of 10(6) M-1 and that GTP binding stabilizes McrB against thermal denaturation. (ii) McrB binds GDP about 50-fold and ATP at least three orders of magnitude more weakly than GTP. (iii) McrB hydrolyzes GTP in the presence of Mg2+ with a steady-state rate of approximately 0.5 min-1. (iv) McrC stimulates GTP hydrolysis 30-fold, but substrate DNA has no detectable effect on the GTPase activity of McrB, neither by itself nor in the presence of McrC. (v) Substitution of N339 and N376 with alanine allowed us to identify NTAD (339 to 342) rather than NKKA (376 to 379) as the equivalent of the third consensus sequence motif characteristic for guanine nucleotide binding proteins, NKXD.

An engineered amino-terminal domain of yeast phosphoglycerate kinase with native-like structure

Previous studies have suggested that the carboxy-terminal peptide (residues 401-415) and interdomain helix (residues 185-199) of yeast phosphoglycerate kinase, a two-domain enzyme, play a role in the folding and stability of the amino-terminal domain (residues 1-184). A deletion mutant has been created in which the carboxy-terminal peptide is attached to the amino-terminal domain (residues 1-184) plus interdomain helix (residues 185-199) through a flexible peptide linker, thus eliminating the carboxy-terminal domain entirely. CD, fluorescence, gel filtration, and NMR experiments indicated that, unlike versions described previously, this isolated N-domain is soluble, monomeric, compactly folded, native-like in structure, and capable of binding the substrate 3-phosphoglycerate with high affinity in a saturable manner. The midpoint of the guanidine-induced unfolding transition was the same as that of the native two-domain protein (Cm approximately 0.8 M). The free energy change associated with guanidine-induced unfolding was one-third that of the native enzyme, in agreement with previous studies that evaluated the intrinsic stability of the N-domain and the contribution of domain-domain interactions to the stability of PGK. These observations suggest that the C-terminal peptide and interdomain helix are sufficient for maintaining a native-like fold of the N-domain in the absence of the C-domain.

The ternary complex of EF-Tu and its role in protein biosynthesis

The past year has seen a breakthrough in our structural understanding of how aminoacyl-tRNAs are selected and transported to the ribosomal A-site in order to decode genetic information contained in messenger RNA. All aminoacyl-tRNAs are recognized by the elongation factor EF-Tu in prokaryotes or EF-1alpha in eukaryotes. The recent determination of the structure of the ternary complex of aminoacyl-tRNA, EF-Tu and a GTP analogue shows how the CCA end of all aminoacyl-tRNA structures can be accommodated in a specific binding site on EF-Tu-GTP, and how part of the T-helix can be recognized by EF-Tu in a non-sequence-specific way. Furthermore, the structure of the ternary complex shows striking structural similarity to the structure of another prokaryotic elongation factor, EF-G, the tRNA translocase, in its GDP or empty form. This observation has led to the proposal of a general macromolecular mimicry of RNA and protein, which predicts elements of RNA-like structures will occur in other translation factors, such as initiation factors and release factors, that interact with similar sites on the ribosome.

Properties of truncated forms of the elongation factor 1alpha from the archaeon Sulfolobus solfataricus

Two truncated forms of the Sulfolobus solfataricus elongation factor 1alpha (SsEF-1alpha), corresponding to the putative domains G+M, Ss(GM)EF-1alpha, and G, Ss(G)EF-1alpha, have been constructed by gene engineering, produced in Escherichia coli and purified. Neither truncated form was able to sustain poly(Phe) synthesis but they were able to bind guanine nucleotides with an affinity much higher with respect to that of the intact factor. However, the difference in the affinity for GDP and GTP became progressively reduced with the extent of the truncation. The values of kcat and Km for GTP of the intrinsic GTPase of SsEF-1alpha triggered by 3.6 M NaCl were not affected by the deletions. In contrast, both Ss(GM)EF-1alpha and Ss(G)EF-1alpha were less thermostable than the intact factor; the region of the factor most responsible for the loss of resistance against heat inactivation was the C-terminal domain. On the other hand the domain M was the regulator of the thermophilicity of SsEF-1alpha since only Ss(G)EF-1alpha showed a reduced thermophilicity. Remarkably, both Ss(GM)EF-1alpha and Ss(G)EF-1alpha were able to exchange [3H]GDP for GTP at a very high rate so that they were no more sensitive to the stimulatory effect of SsEF-1beta, which is the nucleotide exchange factor of SsEF-1alpha.

Ribosome-mediated translational pause and protein domain organization

Because regions on the messenger ribonucleic acid differ in the rate at which they are translated by the ribosome and because proteins can fold cotranslationally on the ribosome, a question arises as to whether the kinetics of translation influence the folding events in the growing nascent polypeptide chain. Translationally slow regions were identified on mRNAs for a set of 37 multidomain proteins from Escherichia coli with known three-dimensional structures. The frequencies of individual codons in mRNAs of highly expressed genes from E. coli were taken as a measure of codon translation speed. Analysis of codon usage in slow regions showed a consistency with the experimentally determined translation rates of codons; abundant codons that are translated with faster speeds compared with their synonymous codons were found to be avoided; rare codons that are translated at an unexpectedly higher rate were also found to be avoided in slow regions. The statistical significance of the occurrence of such slow regions on mRNA spans corresponding to the oligopeptide domain termini and linking regions on the encoded proteins was assessed. The amino acid type and the solvent accessibility of the residues coded by such slow regions were also examined. The results indicated that protein domain boundaries that mark higher-order structural organization are largely coded by translationally slow regions on the RNA and are composed of such amino acids that are stickier to the ribosome channel through which the synthesized polypeptide chain emerges into the cytoplasm. The translationally slow nucleotide regions on mRNA possess the potential to form hairpin secondary structures and such structures could further slow the movement of ribosome. The results point to an intriguing correlation between protein synthesis machinery and in vivo protein folding. Examination of available mutagenic data indicated that the effects of some of the reported mutations were consistent with our hypothesis.

Limited proteolysis and amino acid replacements in the effector region of Thermus thermophilus elongation factor Tu

The effector region of the elongation factor Tu (EF-Tu) from Thermus thermophilus was modified by limited proteolysis or via site-directed mutagenesis. The biochemical properties of the obtained EF-Tu variants were investigated with respect to partial reactions of the functional cycle of EF-Tu. EF-Tu that was cleaved at the Arg59-Gly60 peptide bond [EF-Tu-(1-59)/EF-Tu-(60-405)] bound GDP, EF-Ts and aminoacyl-tRNA, had normal intrinsic GTPase activity and was active in poly(U)-dependent poly(Phe) synthesis. However, the GTPase activity of EF-Tu-(1-59)/EF-Tu-(60-405) was not stimulated by T. thermophilus 70S ribosomes, and its GTP-dissociation rate was increased compared with that of intact EF-Tu. EF-Tu cleaved at the Lys52-Ala53 peptide bond has properties similar to EF-Tu-(1-59)/EF-Tu-(60-405). By means of site-directed mutagenesis, Glu55 was replaced by Leu, Glu56 by Ala and Arg59 by Thr in T. thermophilus EF-Tu. These amino acid substitutions did not substantially affect either the affinity of EF-Tu. GTP for aminoacyl-tRNA or the interactions with GDP, GTP or EF-Ts. Similarly the intrinsic GTPase activity is not influenced. Replacement of Glu56 by Ala led to strong reduction in the ribosome-induced GTPase activity. This effect is specific since replacement of the neighbouring Glu55 by Leu did not affect the ribosome-induced GTPase activity. The results demonstrate that the structure of the effector region of EF-Tu in the vicinity of Arg59 is important for the control of the GTPase activity by ribosomes.

The ternary complex of aminoacylated tRNA and EF-Tu-GTP. Recognition of a bond and a fold

The refined crystal structure of the ternary complex of yeast Phe-tRNAPhe, Thermus aquaticus elongation factor EF-Tu and the non-hydrolyzable GTP analog, GDPNP, reveals many details of the EF-Tu recognition of aminoacylated tRNA (aa-tRNA). EF-Tu-GTP recognizes the aminoacyl bond and one side of the backbone fold of the acceptor helix and has a high affinity for all ordinary elongator aa-tRNAs by binding to this aa-tRNA motif. Yet, the binding of deacylated tRNA, initiator tRNA, and selenocysteine-specific tRNA (tRNASec) is effectively discriminated against. Subtle rearrangements of the binding pocket may occur to optimize the fit to any side chain of the aminoacyl group and interactions with EF-Tu stabilize the 3'-aminoacyl isomer of aa-tRNA. A general complementarity is observed in the location of the binding sites in tRNA for synthetases and for EF-Tu. The complex formation is highly specific for the GTP-bound conformation of EF-Tu, which can explain the effects of various mutants.