Molecular cloning and sequence determination of the tuf gene coding for the elongation factor Tu of Thermus thermophilus HB8

The tuf gene, which encodes the elongation factor Tu (EF-Tu) of Thermus thermophilus HB8, and its flanking regions were cloned and sequenced. The gene encoding EF-G was found upstream of the 5' end of the tuf gene. The tuf gene of T. thermophilus HB8 had a very high G + C content and 84.5% of the third base in codon usage was either G or C. The deduced primary structure of the EF-Tu was composed of 405 amino acid residues with a Mr = 44658. A comparison of the amino acid sequence of EF-Tu from T. thermophilus HB8 with those of Escherichia coli and Saccharomyces cerevisiae mitochondria showed a very high sequence homology (65-70%). Two Cys residues out of the three found in E. coli EF-Tu had been replaced with Val in T. thermophilus HB8 EF-Tu. An extra amino acid sequence of ten residues, consisting predominantly of basic amino acids (Met-182-Gly-191), which does not occur in EF-Tu of E. coli, was found in T. thermophilus HB8.     

Comparative analysis of ribosomal protein L5 sequences from bacteria of the genus Thermus.

The genes for the ribosomal 5S rRNA binding protein L5 have been cloned from three extremely thermophilic eubacteria, Thermus flavus, Thermus thermophilus HB8 and Thermus aquaticus (Jahn et al, submitted). Genes for protein L5 from the three Thermus strains display 95% G/C in third positions of codons. Amino acid sequences deduced from the DNA sequence were shown to be identical for T flavus and T thermophilus, although the corresponding DNA sequences differed by two T to C transitions in the T thermophilus gene. Protein L5 sequences from T flavus and T thermophilus are 95% homologous to L5 from T aquaticus and 56.5% homologous to the corresponding E coli sequence. The lowest degrees of homology were found between the T flavus/T thermophilus L5 proteins and those of yeast L16 (27.5%), Halobacterium marismortui (34.0%) and Methanococcus vannielii (36.6%). From sequence comparison it becomes clear that thermostability of Thermus L5 proteins is achieved by an increase in hydrophobic interactions and/or by restriction of steric flexibility due to the introduction of amino acids with branched aliphatic side chains such as leucine. Alignment of the nine protein sequences equivalent to Thermus L5 proteins led to identification of a conserved internal segment, rich in acidic amino acids, which shows homology to subsequences of E coli L18 and L25. The occurrence of conserved sequence elements in 5S rRNA binding proteins and ribosomal proteins in general is discussed in terms of evolution and function.     

Nucleotide sequence and characteristics of the gene for L-lactate dehydrogenase of Thermus aquaticus YT-1 and the deduced amino acid sequence of the enzyme

The gene for L-lactate dehydrogenase (LDH) from Thermus aquaticus YT-1 was cloned in Escherichia coli, using the Thermus caldophilus LDH gene as a hybridization probe, and its complete nucleotide sequence was determined. The LDH gene comprised 930 base pairs, starting with a GTG initiation codon. Its sequence had high homology (85.8% identity) with the LDH gene of T. caldophilus. The G + C content of the T. aquaticus gene was 70.9%, higher than that of the chromosomal DNA (67.4%). In particular, that in the third position of the codons used was 91.0%, similar to the T. caldophilus gene. The primary structure of T. aquaticus LDH was deduced from the nucleotide sequence of the LDH gene. It comprises 310 amino acid residues, as does T. caldophilus LDH, and its molecular mass was calculated to be 33,210 daltons. The amino acid sequence of the T. aquaticus LDH had 87.1% identity with that of the T. caldophilus LDH. At 23 positions, the respective residues differed in charge and polarity. These differences must be related to the differences in kinetic properties between the two enzymes. The constructed plasmid overproduced the T. aquaticus LDH in E. coli.     

Affinity labeling of the GDP/GTP binding site in Thermus thermophilus elongation factor Tu

Elongation factor Tu from Thermus thermophilus was treated successively with periodate-oxidized GDP or GTP and cyanoborohydride. Covalently modified cyanogen bromide or trypsin fragments of the protein were isolated, and the position of their modification was determined. Lysine residues 52 and 137 were heavily labeled, lysine-137 being considerably more reactive in the GTP form as compared to the GDP form of the protein. These residues are in the proximity of the GDP/GTP binding site. Lys-325 was also labeled, but to a lower extent. The part of the EF-Tu containing residue 52 is missing in crystallized EF-Tu.GDP from Escherichia coli [Jurnak, F. (1985) Science (Washington, D.C.) 230, 32-36]. These results place the part of T. thermophilus EF-Tu corresponding to the missing fragment in E. coli EF-Tu in the vicinity of the nucleotide binding site and allow its role in the interaction with aminoacyl-tRNA and elongation factor Ts to be evaluated. Cross-linking of EF-Tu.GDP by irradiation at 257 nm showed that a sequence of 10 amino acids residues which is found in the Thermus thermophilus elongation factor Tu but not in other homologous bacterial proteins is located in the vicinity of the GDP/GTP binding site.     

Sequence and identification of the nucleotide binding site for the elongation factor Tu from Thermus thermophilus HB8.

Two structural genes for the Thermus thermophilus elongation factor Tu (tuf) were identified by cross-hybridization with the tufA gene from E. coli. The sequence of one of these tuf genes, localized on a 6.6 kb Bam HI fragment, was determined and confirmed by partial protein sequencing of an authentic elongation factor Tu from T. thermophilus HB8. Expression of this tuf gene in E. coli minicells provided a low amount of immuno-precipitable thermophilic EF-Tu. Affinity labeling of the T. thermophilus EF-Tu and sequence comparison with homologous proteins from other organisms were used to identify the guanosine-nucleotide binding domain.     

Cloning and nucleotide sequences of the mdh and sucD genes from Thermus aquaticus B

A 3 kb DNA fragment containing the gene (mdh) encoding malate dehydrogenase (MDH) from the thermophile Thermus aquaticus B was cloned in Escherichia coli and its nucleotide sequence determined. Comparative analysis showed the nucleotide sequence to be very closely related to that determined for the Thermus flavus mdh gene and flanking regions, with no differences between the predicted amino acid sequences of the MDHs. A proximal open reading frame, identified as the sucD gene, and the mdh gene may be parts of the same operon in T. aquaticus B. Expression of the T. aquaticus B mdh gene in E. coli was found to be at a relatively low level. A simple method for purification of thermostable MDH from the E. coli clone containing the T. aquaticus B mdh gene is presented.     

Functionally important sites in the elongation factor EF-Tu from Thermus aquaticus: analysis of fine structural changes upon binding of guanosine-3'-triphosphate and guanosine-3'-diphosphate]

High-resolution data were used to analyze conformational changes of the main chain in two functional states of the ribosome elongation factor EF-Tu from Thermus aquaticus: the inactive state with guanosine-3'-diphosphate and the active state with guanosine-3'-triphosphate. Earlier only major changes in the effector loop of the domain I were determined. In this paper, all rearrangements in the main chain were observed upon shifting of C alpha-atoms from 1 to 8 A for each of the three protein domains. It was shown that these changes occur in numerous regions. New regions of changes were found, and they were located mostly in the loops of protein domains. Some of them are in the regions of interdomain interactions, others correlate with the known functionally important regions of EF-Tu binding with EF-Ts, aminoacyl-tRNA and the ribosome. Most changes induced by the conformational signal transfer from the guanosine-3'-triphosphate binding site occur just in the regions that are important for further stages of the factor functioning. The signal is transferred from domain I to domains II and III via interdomain contacts, predetermining fine fitting of functionally important regions to be involved in the following stages of the elongation cycle. The greatest part of the detected changes occurs in conservative residues of the whole family of bacterial factors, and only some of them are specific. This approach may prove useful for predetermining potential functionally important sites in other proteins.     

Streptococcus pneumoniae DNA polymerase I lacks 3'-to-5' exonuclease activity: localization of the 5'-to-3' exonucleolytic domain.

The Streptococcus pneumoniae polA gene was altered at various positions by deletions and insertions. The polypeptides encoded by these mutant polA genes were identified in S. pneumoniae. Three of them were enzymatically active. One was a fused protein containing the first 11 amino acid residues of gene 10 from coliphage T7 and the carboxyl-terminal two-thirds of pneumococcal DNA polymerase I; it possessed only polymerase activity. The other two enzymatically active proteins, which contained 620 and 351 amino acid residues from the amino terminus, respectively, lacked polymerase activity and showed only exonuclease activity. These two polymerase-deficient proteins and the wild-type protein were hyperproduced in Escherichia coli and purified. In contrast to the DNA polymerase I of Escherichia coli but similar to the corresponding enzyme of Thermus aquaticus, the pneumococcal enzyme appeared to lack 3'-to-5' exonuclease activity. The 5'-to-3' exonuclease domain was located in the amino-terminal region of the wild-type pneumococcal protein. This exonuclease activity excised deoxyribonucleoside 5'-monophosphate from both double- and single-stranded DNAs. It degraded oligonucleotide substrates to a decameric final product.     

The recA gene from the thermophile Thermus aquaticus YT-1: cloning, expression, and characterization.

We have cloned, expressed, and purified the RecA analog from the thermophilic eubacterium Thermus aquaticus YT-1. Analysis of the deduced amino acid sequence indicates that the T. aquaticus RecA is structurally similar to the Escherichia coli RecA and suggests that RecA-like function has been conserved in thermophilic organisms. Preliminary biochemical analysis indicates that the protein has an ATP-dependent single-stranded DNA binding activity and can pair and carry out strand exchange to form a heteroduplex DNA under reaction conditions previously described for E. coli RecA, but at 55 to 65 degrees C. Further characterization of a thermophilically derived RecA protein should yield important information concerning DNA-protein interactions at high temperatures. In addition, a thermostable RecA protein may have some general applicability in stabilizing DNA-protein interactions in reactions which occur at high temperatures by increasing the specificity (stringency) of annealing reactions.     

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

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

Mutagenesis of glutamine 290 in Escherichia coli and mitochondrial elongation factor Tu affects interactions with mitochondrial aminoacyl-tRNAs and GTPase activity

Elongation factor Tu (EF-Tu) is responsible for the delivery of the aminoacyl-tRNAs (aa-tRNA) to the ribosome during protein synthesis. The primary sequence of domain II of EF-Tu is highly conserved. However, several residues thought to be important for aa-tRNA binding in this domain are not conserved between the mammalian mitochondrial and bacterial factors. One of these residues is located at position 290 (Escherichia coli numbering). Residue 290 is Gln in most of the prokaryotic factors but is conserved as Leu (L338) in the mammalian mitochondrial factors. This residue is in a loop contacting the switch II region of domain I in the GTP-bound structure. It also helps to form the binding pocket for the 5' end of the aa-tRNA in the ternary complex. In the present work, Leu338 was mutated to Gln (L338Q) in EF-Tu(mt). The complementary mutation was created at the equivalent position in E. coli EF-Tu (Q290L). EF-Tu(mt) L338Q functions as effectively as wild-type EF-Tu(mt) in poly(U)-directed polymerization with both prokaryotic and mitochondrial substrates and in ternary complex formation assays with E. coli aa-tRNA. However, the L338Q mitochondrial variant has a reduced affinity for mitochondrial Phe-tRNA(Phe). E. coli EF-Tu Q290L is more active in poly(U)-directed polymerization with both mitochondrial and prokaryotic substrates and has a higher GTPase activity in both the absence and presence of ribosomes. Surprisingly, while E. coli EF-Tu Q290L is more active in polymerization with mitochondrial Phe-tRNA(Phe), this variant has low activity in the formation of a stable ternary complex with mitochondrial aa-tRNA.     

Directed mutagenesis identifies amino acid residues involved in elongation factor Tu binding to yeast Phe-tRNAPhe

The co-crystal structure of Thermus aquaticus elongation factor Tu.guanosine 5'- [beta,gamma-imido]triphosphate (EF-Tu.GDPNP) bound to yeast Phe-tRNA(Phe) reveals that EF-Tu interacts with the tRNA body primarily through contacts with the phosphodiester backbone. Twenty amino acids in the tRNA binding cleft of Thermus Thermophilus EF-Tu were each mutated to structurally conservative alternatives and the affinities of the mutant proteins to yeast Phe-tRNA(Phe) determined. Eleven of the 20 mutations reduced the binding affinity from fourfold to >100-fold, while the remaining ten had no effect. The thermodynamically important residues were spread over the entire tRNA binding interface, but were concentrated in the region which contacts the tRNA T-stem. Most of the data could be reconciled by considering the crystal structures of both free EF-Tu.GTP and the ternary complex and allowing for small (1.0 A) movements in the amino acid side-chains. Thus, despite the non-physiological crystallization conditions and crystal lattice interactions, the crystal structures reflect the biochemically relevant interaction in solution.     

Studies on polypeptide-chain-elongation factors from an extreme thermophile, Thermus thermophilus HB8. 3. Molecular properties.

Molecular properties of the polypeptide chain elongation factors from Thermus thermophilus HB8 have been investigated and compared with those from Escherichia coli. 1. As expected, the factors purified from T. thermophilus were exceedingly heat-stable. Even free EF-Tu not complexed with GDP was stable after heating for 5 min at 60 degrees C. 2. GDP binding activity of T. thermophilus EF-Tu was also stable in various protein denaturants, such as 5.5 M urea, 1.5 M guanidine-HCl, and 4 M LiCl. 3. Amino acid compositions of EF-Tu and EF-G from T. thermophilus were similar to those from E. coli. On the other hand, amino acid composition of T. thermophilus EF-Ts was considerably different from that of E. coli EF-Ts. 4. In contrast to E. coli EF-Tu, T. thermophilus EF-Tu contained no free sulfhydryl group, but one disulfide bond. The disulfide bond was cleaved by sodium borohydride or sodium sulfite under native conditions. The heat stability of the reduced EF-Tu . GDP, as measured by GDP binding activity, did not differ from that of the untreated EF-Tu . GDP. 5. T. thermophilus EF-Ts contained, in addition to one disulfide bond, a sulfhydryl group which could be titrated only after complete denaturation of the protein. 6. Under native conditions one sulfhydryl group of T. thermophilus EF-G was titrated with p-chloromercuribenzoate, while the rate of reaction was very sluggish. The sulfhydryl group appears to be essential for interaction with ribosomes, whereas the ability to form a binary GDP . EF-G complex was not affected by its modification. The protein contained also one disulfide bond. 7. Circular dichroic spectra of EF-Tu from T. thermophilus and E. coli were very similar. Binding of GDP or GTP caused a similar spectral change in both. T. thermophilus and E. coli EF-Tu. On the other hand, the spectra of T. thermophilus EF-G and E. coli EF-G were significantly different, the content of ordered structure being higher in the former as compared to the latter.     

Thermostable repair enzyme for oxidative DNA damage from extremely thermophilic bacterium, Thermus thermophilus HB8.

The mutM (fpg) gene, which encodes a DNA glycosylase that excises an oxidatively damaged form of guanine, was cloned from an extremely thermophilic bacterium, Thermus thermophilus HB8. Its nucleotide sequence encoded a 266 amino acid protein with a molecular mass of approximately 30 kDa. Its predicted amino acid sequence showed 42% identity with the Escherichia coli protein. The amino acid residues Cys, Asn, Gln and Met, known to be chemically unstable at high temperatures, were decreased in number in T.thermophilus MutM protein compared to those of the E.coli one, whereas the number of Pro residues, considered to increase protein stability, was increased. The T.thermophilus mutM gene complemented the mutability of the E.coli mutM mutY double mutant, suggesting that T. thermophilus MutM protein was active in E.coli. The T.thermophilus MutM protein was overproduced in E.coli and then purified to homogeneity. Size-exclusion chromatography indicated that T. thermophilus MutM protein exists as a more compact monomer than the E.coli MutM protein in solution. Circular dichroism measurements indicated that the alpha-helical content of the protein was approximately 30%. Thermus thermophilus MutM protein was stable up to 75 degrees C at neutral pH, and between pH 5 and 11 and in the presence of up to 4 M urea at 25 degrees C. Denaturation analysis of T.thermophilus MutM protein in the presence of urea suggested that the protein had at least two domains, with estimated stabilities of 8.6 and 16.2 kcal/mol-1, respectively. Thermus thermophilus MutM protein showed 8-oxoguanine DNA glycosylase activity in vitro at both low and high temperatures.     

Functional implications related to the gene structure of the elongation factor EF-Tu from Halobacterium marismortui.

The primary structure of the gene for the elongation factor EF-Tu from the halophilic archaebacterium Halobacterium marismortui (hEF-Tu) is described. It is the first gene of a halophilic elongation factor EF-Tu to be sequenced. When the sequence of hEF-Tu is compared to that of homologous proteins from other organisms, the highest identity (61%) is found with EF-Tu from Methanococcus vannielii, a non-halophilic archaebacterium. In the search for halophilic characteristics therefore the most appropriate comparison is with the M. vannielii sequence. The excess of acidic amino acid residues in the hEF-Tu sequence (already observed in the composition of other halophilic proteins) results to a large extent from changes of Lys, Asn or Gln to Asp or Glu. A structural analysis algorithm applied to the halophilic sequence places these acidic residues on the surface of the protein. The corresponding residues in the crystal structure of the first domain of EF-Tu from E. coli (the only EF-Tu structure available) are grouped in patches on the protein surface, in each of which several residues that may be far apart in the sequence come quite close to each other in the tertiary structure.     

Thermus aquaticus ATCC 33923 amylomaltase gene cloning and expression and enzyme characterization: production of cycloamylose

The amylomaltase gene of the thermophilic bacterium Thermus aquaticus ATCC 33923 was cloned and sequenced. The open reading frame of this gene consisted of 1,503 nucleotides and encoded a polypeptide that was 500 amino acids long and had a calculated molecular mass of 57,221 Da. The deduced amino acid sequence of the amylomaltase exhibited a high level of homology with the amino acid sequence of potato disproportionating enzyme (D-enzyme) (41%) but a low level of homology with the amino acid sequence of the Escherichia coli amylomaltase (19%). The amylomaltase gene was overexpressed in E. coli, and the enzyme was purified. This enzyme exhibited maximum activity at 75 degrees C in a 10-min reaction with maltotriose and was stable at temperatures up to 85 degrees C. When the enzyme acted on amylose, it catalyzed an intramolecular transglycosylation (cyclization) reaction which produced cyclic alpha-1,4-glucan (cycloamylose), like potato D-enzyme. The yield of cycloamylose produced from synthetic amylose with an average molecular mass of 110 kDa was 84%. However, the minimum degree of polymerization (DP) of the cycloamylose produced by T. aquaticus enzyme was 22, whereas the minimum DP of the cycloamylose produced by potato D-enzyme was 17. The T. aquaticus enzyme also catalyzed intermolecular transglycosylation of maltooligosaccharides. A detailed analysis of the activity of T. aquaticus ATCC 33923 amylomaltase with maltooligosaccharides indicated that the catalytic properties of this enzyme differ from those of E. coli amylomaltase and the plant D-enzyme.     

Molecular cloning and nucleotide sequence of 3-isopropylmalate dehydrogenase gene (leuB) from an extreme thermophile, Thermus aquaticus YT-1

A gene (leuB) coding for 3-isopropylmalate dehydrogenase [EC 1.1.1.85] from an extreme thermophile, Thermus aquaticus YT-1 was cloned in Escherichia coli and the nucleotide sequence was determined. It contains an open reading frame of 1,035 bp encoding 344 amino acid residues. The homology with that from T. thermophilus HB8 is 87.0% in nucleotide and 91.3% in amino acid sequences. No overlapped gene was found in the present leuB gene, in contrast to the previous prediction that Thermus leuD gene is overlapped with leuB [Croft et al. (1987) Mol. Gen. Genet. 210, 490-497]. Substitutions in the primary structure which are unique for the thermophile sequences are discussed in relation to the unusual stability of the thermophile dehydrogenase based on amino acid sequence comparison of 9 microorganisms including thermophiles and mesophiles.     

Mapping the effector region in Thermus thermophilus elongation factor Tu

Native elongation factor Tu from Thermus thermophilus is initially attacked by various endoproteases in a region spanning amino acid residues 40-70. By comparing the hydrolysis rates of nucleotide-free and GDP-bound EF-Tu, only a small difference was observed for the tryptic cleavage at Arg-59. Protease V-8 attacks Glu-55 only in a GDP/GTP form, whereas this enzyme exclusively hydrolyze Asn-64 in nucleotide-free EF-Tu, even when the protein had been previously cleaved at Arg-59. Binding of GDP leads to a 42-fold decreased rate of hydrolysis by the Lys-C protease at Lys-52. It also reduces the accessibility of Lys-275 to trypsin, reflecting a "long-range" effect from nucleotide binding domain I to domain II. Only slight differences were observed in the rate of hydrolysis at all positions in the GDP- versus the GTP-bound form. The intrinsic GTPase activity was slightly reduced in trypsin-treated EF-Tu, significantly impaired in EF-Tu cleaved at Lys-52, and completely abolished in EF-Tu cleaved at Asn-64. No ribosome-induced GTPase activity was observed for protease-cleaved EF-Tu's. Treatment of these proteins with periodate-oxidized GDP or GTP followed by cyanoborohydride led to covalent modification of the new N-terminus located exclusively within region 52-60. The highest reactivity was shown by the N-terminus of Glu-56. Additionally, lysine residues in the native protein sensitive to affinity labeling [Peter, M.E., Wittmann-Liebold, B., & Sprinzl, M. (1988) Biochemistry 27, 9132-9139] lost their reactivity upon cleavage of EF-Tu in region 52-60, suggesting an altered structure of the cleaved protein.(ABSTRACT TRUNCATED AT 250 WORDS)     

Interactions of Escherichia coli thioredoxin, the processivity factor, with bacteriophage T7 DNA polymerase and helicase

Escherichia coli thioredoxin binds to a unique flexible loop of 71 amino acid residues, designated the thioredoxin binding domain (TBD), located in the thumb subdomain of bacteriophage T7 gene 5 DNA polymerase. The initial designation of thioredoxin as a processivity factor was premature. Rather it remodels the TBD for interaction with DNA and the other replication proteins. The binding of thioredoxin exposes a number of basic residues on the TBD that lie over the duplex region of the primer-template and increases the processivity of nucleotide polymerization. Two small solvent-exposed loops (loops A and B) located within TBD electrostatically interact with the acidic C-terminal tail of T7 gene 4 helicase-primase, an interaction that is enhanced by the binding of thioredoxin. Several basic residues on the surface of thioredoxin in the polymerase-thioredoxin complex lie in close proximity to the TBD. One of these residues, lysine 36, is located proximal to loop A. The substitution of glutamate for lysine has a dramatic effect on the binding of gene 4 helicase to a DNA polymerase-thioredoxin complex lacking charges on loop B; binding is decreased 15-fold relative to that observed with wild-type thioredoxin. This defective interaction impairs the ability of T7 DNA polymerase-thioredoxin together with T7 helicase to mediate strand displacement synthesis. This is the first demonstration that thioredoxin interacts with replication proteins other than T7 DNA polymerase.     

High resolution crystal structure of bovine mitochondrial EF-Tu in complex with GDP

The crystal structure of bovine mitochondrial elongation factor Tu (EF-Tu) in complex with GDP has been determined at a resolution of 1. 94 A. The structure is similar to that of EF-Tu:GDP from Escherichia coli and Thermus aquaticus, but the orientation of the GDP-binding domain 1 is changed relative to domains 2 and 3. Sixteen conserved water molecules common to EF-Tu and other G-proteins in the GDP-binding site are described. These water molecules create a network linking separated parts of the binding pocket. Mitochondrial EF-Tu binds nucleotides less tightly than prokaryotic EF-Tu possibly due to an increased mobility in regions close to the GDP-binding site. The C-terminal extension of mitochondrial EF-Tu has structural similarities with DNA recognising zinc fingers suggesting that the extension may be involved in recognition of RNA.