Elongation factor Ts can act as a steric chaperone by increasing the solubility of nucleotide binding-impaired elongation factor-Tu.

Several elongation factor (EF) Tu mutants (T25A, H22Y/T25S, D80N, D138N) that have impaired nucleotide binding show decreased solubility on overexpression in the E. coli cell, an indication that they do not fold correctly. Moreover, EF-Tu[T25A] and EF-Tu[D80N] were shown to inhibit cell growth on expression, an effect attributed to their sequestration of EF-Ts [Krab, I. M., and Parmeggiani, A. (1999) J. Biol. Chem. 274, 11132--11138; Krab, I. M., and Parmeggiani, A. (1999) Biochemistry 38, 13035--13041]. We present here results showing that the co-overexpression of EF-Ts at a 1:1 ratio dramatically improves the solubility of mutant EF-Tu, although in the case of EF-Tu[D138N]--which cannot at all bind the nucleotides available in the cell--this is a slow process. Moreover, with co-overexpression of EF-Ts, the mentioned growth inhibition is relieved. We conclude that for the formation of a correct EF-Tu structure the nucleotide plays an important role as a "folding nucleus", and also that in its absence EF-Ts can act as a folding template or steric chaperone for the correct folding of EF-Tu.     

Complete kinetic mechanism of elongation factor Tu-dependent binding of aminoacyl-tRNA to the A site of the E. coli ribosome.

The kinetic mechanism of elongation factor Tu (EF-Tu)-dependent binding of Phe-tRNAPhe to the A site of poly(U)-programmed Escherichia coli ribosomes has been established by pre-steady-state kinetic experiments. Six steps were distinguished kinetically, and their elemental rate constants were determined either by global fitting, or directly by dissociation experiments. Initial binding to the ribosome of the ternary complex EF-Tu.GTP.Phe-tRNAPhe is rapid (k1 = 110 and 60/micromM/s at 10 and 5 mM Mg2+, 20 degreesC) and readily reversible (k-1 = 25 and 30/s). Subsequent codon recognition (k2 = 100 and 80/s) stabilizes the complex in an Mg2+-dependent manner (k-2 = 0.2 and 2/s). It induces the GTPase conformation of EF-Tu (k3 = 500 and 55/s), instantaneously followed by GTP hydrolysis. Subsequent steps are independent of Mg2+. The EF-Tu conformation switches from the GTP- to the GDP-bound form (k4 = 60/s), and Phe-tRNAPhe is released from EF-Tu.GDP. The accommodation of Phe-tRNAPhe in the A site (k5 = 8/s) takes place independently of EF-Tu and is followed instantaneously by peptide bond formation. The slowest step is dissociation of EF-Tu.GDP from the ribosome (k6 = 4/s). A characteristic feature of the mechanism is the existence of two conformational rearrangements which limit the rates of the subsequent chemical steps of A-site binding.     

Mechanism of EF-Ts-catalyzed guanine nucleotide exchange in EF-Tu: contribution of interactions mediated by helix B of EF-Tu

Elongation factor Tu (EF-Tu) belongs to the family of GTP-binding proteins and requires elongation factor Ts (EF-Ts) for nucleotide exchange. Crystal structures suggested that one of the salient features in the EF-Tu x EF-Ts complex is a conformation change in the switch II region of EF-Tu that is initiated by intrusion of Phe81 of EF-Ts between His84 and His118 of EF-Tu and may result in a destabilization of Mg2+ coordination and guanine nucleotide release. In the present paper, the contribution of His84 to nucleotide release was studied by pre-steady-state kinetic analysis of nucleotide exchange in mutant EF-Tu in which His84 was replaced by Ala. Both intrinsic and EF-Ts-catalyzed nucleotide release was affected by the mutation, resulting in a 10-fold faster spontaneous GDP release and a 4-fold faster EF-Ts-catalyzed release of GTP and GDP. Removal of Mg2+ from the EF-Tu x EF-Ts complex increased the rate constant of GDP release 2-fold, suggesting a small contribution to nucleotide exchange. Together with published data on the effects of mutations interfering with other putative interactions between EF-Tu and EF-Ts, the results suggest that each of the contacts in the EF-Tu x EF-Ts complex alone contributes moderately to nucleotide destabilization, but together they act synergistically to bring about the overall 60,000-fold acceleration of nucleotide exchange in EF-Tu by EF-Ts.     

Kinetics and thermodynamics of the interaction of elongation factor Tu with elongation factor Ts, guanine nucleotides, and aminoacyl-tRNA

The exchange of elongation factor Tu (EF-Tu)-bound GTP in the presence and absence of elongation factor Ts (EF-Ts) was monitored by equilibrium exchange kinetic procedures. The kinetics of the exchange reaction were found to be consistent with the formation of a ternary complex EF-Tu X GTP X EF-Ts. The equilibrium association constants of EF-Ts to the EF-Tu X GTP complex and of GTP to EF-Tu X EF-Ts were calculated to be 7 X 10(7) and 2 X 10(6) M-1, respectively. The dissociation rate constant of GTP from the ternary complex was found to be 13 s-1. This is 500 times larger than the GTP dissociation rate constant from the EF-Tu X GTP complex (2.5 X 10(-2) s-1). A procedure based on the observation that EF-Tu X GTP protects the aminoacyl-tRNA molecule from phosphodiesterase I-catalyzed hydrolysis was used to study the interactions of EF-Tu X GTP with Val-tRNAVal and Phe-tRNAPhe. Binding constants of Phe-tRNAPhe and Val-tRNAVal to EF-Tu X GTP of 4.8 X 10(7) and 1.2 X 10(7)M-1, respectively, were obtained. The exchange of bound GDP with GTP in solution in the presence of EF-Ts was also examined. The kinetics of the reaction were found to be consistent with a rapid equilibrium mechanism. It was observed that the exchange of bound GDP with free GTP in the presence of a large excess of the latter was accelerated by the addition of aminoacyl-tRNA. On the basis of these observations, a complete mechanism to explain the interactions among EF-Tu, EF-Ts, guanine nucleotides, and aminoacyl-tRNA has been developed.     

Mitochondrial translation: elongation factor tu is essential in fission yeast and depends on an exchange factor conserved in humans but not in budding yeast

The translation elongation factor EF-Tu is a GTPase that delivers amino-acylated tRNAs to the ribosome during the elongation step of translation. EF-Tu/GDP is recycled by the guanine nucleotide exchange factor EF-Ts. Whereas EF-Ts is lacking in S. cerevisiae, both translation factors are found in S. pombe and H. sapiens mitochondria, consistent with the known similarity between fission yeast and human cell mitochondrial physiology. We constructed yeast mutants lacking these elongation factors. We show that mitochondrial translation is vital for S. pombe, as it is for human cells. In a genetic background allowing the loss of mitochondrial functions, a block in mitochondrial translation in S. pombe leads to a major depletion of mtDNA. The relationships between EF-Ts and EF-Tu from both yeasts and humans were investigated through functional complementation and coexpression experiments and by a search for suppressors of the absence of the S. pombe EF-Ts. We find that S. cerevisiae EF-Tu is functionally equivalent to the S. pombe EF-Tu/EF-Ts couple. Point mutations in the S. pombe EF-Tu can render it independent of its exchange factor, thereby mimicking the situation in S. cerevisiae.     

Mutagenesis of bacterial elongation factor Tu at lysine 136. A conserved amino acid in GTP regulatory proteins

We have studied the effects of specific amino acid replacements in EF-Tu upon the protein's interactions with guanine nucleotides and elongation factor Ts (EFTs). We found that alterations at the lysine residue of the Asn-Lys-Cys-Asp sequence, the guanine ring-binding sequence, differentially affect the protein's ability to bind guanine nucleotides. Wild type EF-Tu (Lys-136) binds GDP and GTP much more tightly than do many of the altered proteins. Replacing lysine by arginine lowers the protein's affinity for GDP by about 20-fold relative to the change in its affinity for EF-Ts. Substitutions at residue 136 by glutamine (K136Q) and glutamic acid (K136E) further lower the protein relative affinity for GDP by factors of about 4 and 10, respectively. In contrast, replacement of the residue by isoleucine (K136I) eliminates guanine nucleotide binding as well as EF-Ts binding. Apparently, the distortion of this loop by substitution at residue 136 of a bulky hydrophobic residue can hamper the binding for both substrates or disrupt the folding of the protein. All altered proteins except EF-Tu(K136I) are able to bind tRNA(Phe); however, they require much higher concentrations of GTP than wild type EF-Tu. In minimal media, Escherichia coli cells harboring plasmids encoding EF-Tu(K136E) or EF-Tu(K136Q) suffer growth retardation relative to cells bearing the same plasmid encoding wild type EF-Tu. Co-transformation of these cells with a compatible plasmid bearing the EF-Ts gene reverses this growth problem. The growth retardation effect of some of the altered proteins can be explained by their sequestering EF-Ts. These results indicate that EF-Ts is essential to the growth of E. coli and suggest a technique for studying EF-Ts mutants as well as for identifying other guanine nucleotide exchange enzymes.     

Kinetic mechanism of elongation factor Ts-catalyzed nucleotide exchange in elongation factor Tu.

The interaction of Escherichia coli elongation factor Tu (EF-Tu) with elongation factor Ts (EF-Ts) and guanine nucleotides was studied by the stopped-flow technique, monitoring the fluorescence of tryptophan 184 in EF-Tu or of the mant group attached to the guanine nucleotide. Rate constants of all association and dissociation reactions among EF-Tu, EF-Ts, GDP, and GTP were determined. EF-Ts enhances the dissociation of GDP and GTP from EF-Tu by factors of 6 x 10(4) and 3 x 10(3), respectively. The loss of Mg(2+) alone, without EF-Ts, accounts for a 150-300-fold acceleration of GDP dissociation from EF-Tu.GDP, suggesting that the disruption of the Mg(2+) binding site alone does not explain the EF-Ts effect. Dissociation of EF-Ts from the ternary complexes with EF-Tu and GDP/GTP is 10(3)-10(4) times faster than from the binary complex EF-Tu.EF-Ts, indicating different structures and/or interactions of the factors in the binary and ternary complexes. Rate constants of EF-Ts binding to EF-Tu in the free or nucleotide-bound form or of GDP/GTP binding to the EF-Tu.EF-Ts complex range from 0.6 x 10(7) to 6 x 10(7) M(-1) s(-1). At in vivo concentrations of nucleotides and factors, the overall exchange rate, as calculated from the elemental rate constants, is 30 s(-1), which is compatible with the rate of protein synthesis in the cell.     

Studies on polypeptide-chain-elongation factors from an extreme thermophile, Thermus thermophilus HB8. 2. Catalytic properties.

Catalytic properties of the elongation factors from Thermus thermophilus HB8 have been studied and compared with those of the factors from Escherichia coli. 1. The formation of a ternary guanine-nucleotide . EF-Tu . EF-Ts complex was demonstrated by gel filtration of the T. thermophilus EF-Tu . EF-Ts complex on a Sephadex G-150 column equilibrated with guanine nucleotide. The occurrence of this type of complex has not yet been proved with the factors from E. coli. 2. The dissociation constants for the complexes of T. thermophilus EF-Tu . EF-Ts with GDP and GTP were 6.1 x 10(-7) M and 1.9 x 10(-6) M respectively. On the other hand, T. thermophilus EF-Tu interacted with GDP and GTP with dissociation constants of 1.1 x 10(-9) M and 5.8 x 10(-8) M respectively. This suggests that the association of EF-Ts with EF-Tu lowered the affinity of EF-Tu for GDP by a factor of about 600 and facilitated the nucleotide exchange reaction. 3. Although the T. thermophilus EF-Tu . EF-Ts complex hardly dissociates into EF-Tu and EF-Ts, a rapid exchange was observed between free EF-Ts and the EF-Tu . EF-Ts complex using 3H-labelled EF-Ts. The exchange reaction was independent on the presence or absence of guanine nucleotides. 4. Based on the above findings, an improved reaction mechanism for the regeneration of EF-Tu . GTP from EF-Tu . GDP is proposed. 5. Studies on the functional interchangeability of EF-Tu and EF-Ts between T. thermophilus and E. coli has revealed that the factors function much more efficiently in the homologous than in the heterologous combination. 6. T. thermophilus EF-Ts could bind E. coli EF-Tu to form an EF-Tu (E. coli) . EF-Ts (T. thermophilus hybrid complex. The complex was found to exist in a dimeric form indicating that the property to form a dimer is attributable to T. thermophilus EF-Ts. On the other hand, no stable complex between E. coli EF-Ts and T. thermophilus EF-Tu has been isolated. 7. The uncoupled GTPase activity of T. thermophilus EF-G was much lower than that of E. coli EF-G. T. thermophilus EF-G formed a relatively stable binary EF-G . GDP complex, which could be isolated on a nitrocellulose membrane filter. The Kd values for EF-G . GDP and EF-G . GTP were 6.7 x 10(-7) M and 1.2 x 10(-5) M respectively. The ternary T. thermophilus EF-G . GDP . ribosome complex was again very stable and could be isolated in the absence of fusidic acid. The stability of the latter complex is probably the cause of the low uncoupled GTPase activity of T. thermophilus EF-G.     

Mechanism of elongation factor (EF)-Ts-catalyzed nucleotide exchange in EF-Tu. Contribution of contacts at the guanine base.

Nucleotide exchange in elongation factor Tu (EF-Tu) is catalyzed by elongation factor Ts (EF-Ts). Similarly to other GTP-binding proteins, the structural changes in the P loop and the Mg(2+) binding site are known to be important for nucleotide release from EF-Tu. In the present paper, we determine the contribution of the contacts between helix D of EF-Tu at the base side of the nucleotide and the N-terminal domain of EF-Ts to the catalysis. The rate constants of the multistep reaction between Escherichia coli EF-Tu, EF-Ts, and GDP were determined by stopped-flow kinetic analysis monitoring the fluorescence of either Trp-184 in EF-Tu or mant-GDP. Mutational analysis shows that contacts between helix D of EF-Tu and the N-terminal domain of EF-Ts are important for both complex formation and the acceleration of GDP dissociation. The kinetic results suggest that the initial contact of EF-Ts with helix D of EF-Tu weakens binding interactions around the guanine base, whereas contacts of EF-Ts with the phosphate binding side that promotes the release of the phosphate moiety of GDP appear to take place later. This "base-side-first" mechanism of guanine nucleotide release resembles that found for Ran x RCC1 and differs from mechanisms described for other GTPase x GEF complexes where interactions at the phosphate side of the nucleotide are released first.     

The importance of P-loop and domain movements in EF-Tu for guanine nucleotide exchange

Elongation factor Ts (EF-Ts) is the guanine nucleotide exchange factor for elongation factor Tu (EF-Tu). An important feature of the nucleotide exchange is the structural rearrangement of EF-Tu in the EF-Tu.EF-Ts complex caused by insertion of Phe-81 of EF-Ts between His-84 and His-118 of EF-Tu. In this study, the contribution of His-118 to nucleotide release was studied by pre-steady state kinetic analysis of nucleotide exchange in EF-Tu mutants in which His-118 was replaced by Ala or Glu. Intrinsic as well as EF-Ts-catalyzed release of GDP/GTP was affected by the mutations, resulting in an approximately 10-fold faster spontaneous nucleotide release and a 10-50-fold slower EF-Ts-catalyzed nucleotide release. The effects are attributed to the interference of the mutations with the EF-Ts-induced movements of the P-loop of EF-Tu and changes at the domain 1/3 interface, leading to the release of the beta-phosphate group of GTP/GDP. The K(d) for GTP is increased by more than 40 times when His-118 is replaced with Glu, which may explain the inhibition by His-118 mutations of aminoacyl-tRNA binding to EF-Tu. The mutations had no effect on EF-Tu-dependent delivery of aminoacyl-tRNA to the ribosome.     

Effects of domain exchanges between Escherichia coli and mammalian mitochondrial EF-Tu on interactions with guanine nucleotides, aminoacyl-tRNA and ribosomes.

Escherichia coli elongation factor (EF-Tu) and the corresponding mammalian mitochondrial factor, EF-Tumt, show distinct differences in their affinities for guanine nucleotides and in their interactions with elongation factor Ts (EF-Ts) and mitochondrial tRNAs. To investigate the roles of the three domains of EF-Tu in these differences, six chimeric proteins were prepared in which the three domains were systematically switched. E. coli EF-Tu binds GDP much more tightly than EF-Tumt. This difference does not reside in domain I alone but is regulated by interactions with domains II and III. All the chimeric proteins formed ternary complexes with GTP and aminoacyl-tRNA although some had an increased or decreased activity in this assay. The activity of E. coli EF-Tu but not of EF-Tumt is stimulated by E. coli EF-Ts. The presence of any one of the domains of EF-Tumt in the prokaryotic factor reduced its interaction with E. coli EF-Ts 2-3-fold. In contrast, the presence of any of the three domains of E. coli EF-Tu in EF-Tumt allowed the mitochondrial factor to interact with bacterial EF-Ts. This observation indicates that even domain II which is not in contact with EF-Ts plays an important role in the nucleotide exchange reaction. EF-Tsmt interacts with all of the chimeras produced. However, with the exception of domain III exchanges, it inhibits the activities of the chimeras indicating that it could not be productively released to allow formation of the ternary complex. The unique ability of EF-Tumt to promote binding of mitochondrial Phe-tRNAPhe to the A-site of the ribosome resides in domains I and II. These studies indicate that the interactions of EF-Tu with its ligands is a complex process involving cross-talk between all three domains.     

Effect of Thermus thermophilus elongation factor Ts on the conformation of elongation factor Tu

Affinity labeling in situ of the Thermus thermophilus elongation factor Tu (EF-Tu) nucleotide binding site was achieved with periodate-oxidized GDP (GDPoxi) or GTP (GTPoxi) in the absence and presence of elongation factor Ts (EF-Ts). Lys52 and Lys137, both reacting with GDPoxi and GTPoxi, are located in the nucleotide binding region. In the absence of EF-Ts Lys137 and to a lesser extent Lys52 were accessible to the reaction with GTPoxi. GDPoxi reacted much more efficiently with Lys52 than with Lys137 under these conditions [Peter, M. E., Wittman-Liebold, B. & Sprinzl, M. (1988) Biochemistry 27, 9132-9138]. In the presence of EF-Ts, GDPoxi reacted more efficiently with Lys137 than with Lys52, indicating that the interaction of EF-Ts with EF-Tu.GDPoxi induces a conformation resembling that of the EF-Tu.GDPoxi complex in the absence of EF-Ts. Binding of EF-Ts to EF-Tu.GDP enhances the accessibility of the Arg59-Gly60 peptide bond of EF-Tu to trypsin cleavage. Hydrolysis of this peptide bond does not interfere with the ability of EF-Ts to bind to EF-Tu. EF-Ts is protected against trypsin cleavage by interaction with EF-Tu.GDP. High concentrations of EF-Ts did not interfere significantly with aminoacyl-tRNA.EF-Tu.GTP complex formation.     

A study of the kinetic mechanism of elongation factor Ts

Elongation factor Ts (EF-Ts) catalyzes the reaction EF-Tu X GDP + nucleotide diphosphate (NDP) reversible EF-Tu X NDP + GDP where NDP is GDP, IDP, GTP, or GMP X PCP. The EF-Ts-catalyzed exchange rates were measured at a series of concentrations of EF-Tu X [3H] GDP and free nucleotide. Plotting the rate data according to the Hanes method produced a series of lines intersecting on the ordinate, a characteristic of substituted enzyme mechanisms. GDP is a competitive inhibitor of IDP exchange, a result predicted for the substituted enzyme mechanism but inconsistent with ternary complex mechanisms that involve an intermediate complex containing EF-Ts and both substrates. The exchange of both GTP and the GTP analog GMP X PCP also follow the substituted enzyme mechanism. The maximal rates of exchange of GDP and GTP are the same, which indicates that the rates of dissociation of EF-Ts from EF-Tu X GDP and EF-Tu X GTP are the same. The steady-state maximal exchange rate is slower by a factor of 20 than the previously reported rate of dissociation of GDP from EF-Ts X EF-Tu. This is interpreted to mean that the rate-determining step in the exchange reaction is the dissociation of EF-Ts from EF-Tu X GDP.     

Involvement of 30S ribosomal protein S1 in poly(U)-directed polyphenylalanine synthesis.

The effect of 30S ribosomal protein S1 on poly(U)-directed polyphenylalanine synthesis was studied using a highly purified cell-free system which was devoid of endogenous S1. The system consisted of homogeneous preparations of EF-Tu, EF-Ts, and EF-G, and 70S ribosomes from which protein S1 had been removed by poly(U)-cellulose column chromatography. It was found that protein S1 was indispensable for translation of poly(U) by an S1-depleted system at low concentrations of poly(U). On the other hand, at higher concentrations of poly(U), a considerable amount of polyphenylalanine was synthesized in the absence of added S1. The stimulatory effect of S1 was observed at all Mg2+ concentrations examined but was most pronounced at 10 mM Mg2+. Some physicochemical properties of the protein were also studied. It was demonstrated that the protein has an elongated shape with an axial ratio of approximately 8.5.     

The complex formation between Escherichia coli aminoacyl-tRNA, elongation factor Tu and GTP. The effect of the side-chain of the amino acid linked to tRNA

The interaction between Escherichia coli aminoacyl-tRNAs and elongation factor Tu (EF-Tu) x GTP was examined. Ternary complex formation with Phe-tRNAPhe and Lys-tRNALys was compared to that with the respective misaminoacylated Tyr-tRNAPhe and Phe-tRNALys. There was no pronounced difference in the efficiency of aminoacyl-tRNA x EF-Tu x GTP complex formation between Phe-tRNAPhe and Tyr-tRNAPhe. However, Phe-tRNALys was bound preferentially to EF-Tu x GTP as compared to Lys-tRNALys. This was shown by the ability of EF-Tu x GTP to prevent the hydrolysis of the aminoacyl ester linkage of the aminoacyl-tRNA species. Furthermore, gel filtration of ternary complexes revealed that the complex formed with the misaminoacylated tRNALys was also more stable than the one formed with the correctly aminoacylated tRNALys. Both misaminoacylated aminoacyl-tRNA species could participate in the ribosomal peptide elongation reaction. Poly(U)-directed synthesis of poly(Tyr) using Tyr-tRNAPhe occurred to a comparable extent as the synthesis of poly(Phe) with Phe-tRNAPhe. In the translation of poly(A) using native Lys-tRNALys, poly(Lys) reached a lower level than poly(Phe) when Phe-tRNALys was used. It was concluded that the side-chain of the amino acid linked to a tRNA affects the efficiency of the aminoacyl-tRNA x EF-Tu x GTP ternary complex formation.     

Binding of the yeast phenylalanine tRNA with Escherichia coli ribosomes. Effect of the removal of a modified base from the 3'-end of the anticodon on codon-anticodon interaction

Phe-tRNAPhe+Y and N-acetyl-Phe-tRNAPhe+Y from yeast interact with prokaryotic 30S subunits and 70S ribosomes with slightly lower affinity than respective tRNA's of E. coli (decrease of standard free energy change of interaction less than 10%). The removal of Y-base from Phe-tRNAPhe+Y results in two orders of magnitude decrease of association constant of Phe-tRNAPh-Ye with P site of the 30S X poly(U) complex and one ordef of magnitude or more of that with A site. The same modification decreases the association constants of Phe-tRNAPhe-Y and N-acetyl-Phe-tRNAPhe-Y 60 and 15 times respectively with P site of the 70S X poly(U) complex. In the absence of poly(U) the affinity of N-acetyl-Phe-tRNAPhe-Y to P-site of 70S ribosome was 20-fold lower than that of native N-acetyl-Phe-tRNAPhe+Y. The sign of interaction enthalpy of N-acetyl-Phe-tRNAPhe+/-Y and Phe-tRNAPhe-Y changes below 6-7 degrees C exposing the hydrophobic part of P-site interactions. Similar removal of Y-base does not change both the enthalpy of interaction with P-site and magnesium concentration dependence.     

Effects of mutations of conserved Lys-155 and Thr-156 residues in the phosphate-binding glycine-rich sequence of the F1-ATPase beta subunit of Escherichia coli.

beta Lys-155 in the glycine-rich sequence of the beta subunit of Escherichia coli F1-ATPase has been shown to be near the gamma-phosphate moiety of ATP by affinity labeling (Ida, K., Noumi, T., Maeda, M., Fukui, T., and Futai, M. (1991) J. Biol. Chem. 266, 5424-5429). For examination of the roles of beta Lys-155 and beta Thr-156, mutants (beta Lys-155-->Ala, Ser, or Thr; beta Thr-156-->Ala, Cys, Asp, or Ser; beta Lys-155/beta Thr-156-->beta Thr-155/beta Lys-156; and beta Thr-156/beta Val-157-->beta Ala-156/beta Thr-157) were constructed, and their properties were studied extensively. The beta Ser-156 mutant was active in ATP synthesis and had approximately 1.5-fold higher membrane ATPase activity than the wild type. Other mutants were defective in ATP synthesis, had < 0.1% of the membrane ATPase activity of the wild type, and showed no ATP-dependent formation of an electrochemical proton gradient. The mutants had essentially the same amounts of F1 in their membranes as the wild type. Purified mutant enzymes (beta Ala-155, beta Ser-155, beta Ala-156, and beta Cys-156) showed low rates of multisite (< 0.02% of the wild type) and unisite (< 1.5% of the wild type) catalyses. The k1 values of the mutant enzymes for unisite catalysis were lower than that of the wild type: not detectable with the beta Ala-156 and beta Cys-156 enzymes and 10(2)-fold lower with the beta Ala-155 and beta Ser-155 enzymes. The beta Thr-156-->Ala or Cys enzyme showed an altered response to Mg2+, suggesting that beta Thr-156 may be closely related to Mg2+ binding. These results suggest that beta Lys-155 and beta Thr-156 are essential for catalysis and are possibly located in the catalytic site, although beta Thr-156 could be replaced by a serine residue.     

Catalytic effects of elongation factor Ts on polypeptide synthesis

The kinetic parameters which characterize the interaction between elongation factor Tu (EF-Tu) and elongation factor Ts (EF-Ts) have been determined in a poly(uridylic acid)-primed translation system. The EF-Ts catalyzed release of GDP from EF-Tu was measured independently in a nucleotide exchange assay. We conclude that the rate-limiting step for the EF-Tu cycle in protein synthesis in the absence of EF-Ts is the release of GDP. By adding EF-Ts the time of this step is reduced from 90 s to 30 ms. Half maximal rate is obtained at an EF-Ts concentration of 2.5 x 10⁻⁶ M.     

The identification of a domain in Escherichia coli elongation factor Tu that interacts with elongation factor Ts.

A method has been developed to search for the elongation factor Tu (EF-Tu) domain(s) that interact with elongation factor Ts (EF-Ts). This method is based on the suppression of Escherichia coli EF-Tu-dominant negative mutation K136E, a mutation that exerts its effect by sequestering EF-Ts. We have identified nine single-amino acid- substituted suppression mutations in the region 146-199 of EF-Tu. These mutations are R154C, P168L, A174V, K176E, D181G, E190K, D196G, S197F, and I199V. All suppression mutations but one (R154C) significantly affect EF-Tu's ability to interact with EF-Ts under equilibrium conditions. Moreover, with the exception of mutation A174V, the GDP affinity of EF-Tu appears to be relatively unaffected by these mutations. These results suggest that the domain of residues 154 to 199 on EF-Tu is involved in interacting with EF-Ts. These suppression mutations are also capable of suppressing dominant negative mutants N135D and N135I to various degrees. This suggests that dominant negative mutants N135D and N135I are likely to have the same molecular basis as the K136E mutation. The method we have developed in this study is versatile and can be readily adapted to map other regions of EF-Tu. A model of EF-Ts-catalyzed guanine-nucleotide exchange is discussed.     

白色念珠菌CYP51蛋白功能性氨基酸残基定点突变、蛋白表达及活性测定

实验设计了白色念珠菌CYP51蛋白功能性氨基酸残基突变体Y118A、Y118F、Y118T、S378A、S378T、H310A、H310R, 并转入基因工程菌D12667中表达。用Western及紫外分光光度法定性、定量检测蛋白, 用GC-MS法测定蛋白代谢活性。结果表明, 成功表达目标蛋白, 蛋白诱导表达量接近微粒体蛋白总量的25%。活性测定表明, 表达的野生型蛋白保持其对天然底物的代谢能力; 相较于野生型蛋白, 突变体蛋白代谢活性不同程度改变, 最多可下降1/2左右。因此, 本研究中成功表达了野生型和