Binding of eucaryotic elongation factor Tu to nucleic acids

The binding of eucaryotic elongation factor Tu (eEF-Tu) to nucleic acids was investigated. eEF-Tu binds to a variety of different nucleic acids with high affinity, showing a strong preference for 18 S and 28 S rRNA over transfer RNA and for ribose-containing polymers over polydeoxyribonucleotides. The factor binds at multiple sites on 28 S rRNA without strong cooperativity. eEF-Tu binds strongly to poly(G) and poly(U) but weakly, if at all, to poly(A) and poly(C). Experiments employing an airfuge demonstrate that eEF-Tu can form a quaternary complex containing the factor, 28 S rRNA, aminoacyl-tRNA, and GTP. The existence of two distinct RNA binding sites on eEF-Tu suggests that rRNA may play a role in the recognition of eEF-Tu.aminoacyl-tRNA.GTP complexes by polysomes. Support for this suggestion comes from experiments which show that poly(G) inhibits the factor-dependent binding of aminoacyl-tRNA to mRNA-programmed 80 S ribosomes. In addition, it is shown that eEF-Tu possesses an intrinsic GTPase activity which is stimulated significantly by 28 S rRNA, poly(G), and poly(U). The binding of eEF-Tu to poly(G) lowers the activation energy for eEF-Tu GTPase from 74.3 to 65.9 kJ . mol-1 and approximately doubles the Vmax of the enzymatic reaction. The results are discussed in relation to the binding of eEF-Tu to ribosomes during protein synthesis.     

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

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

Identification of cysteine-10 of protein S18 as part of the mRNA-binding site of Escherichia coli ribosomes by affinity-labeling studies with a chemically reactive A-U-G analog.

The reaction of a bromoacetamidophenyl derivative of the initiation codon A-U-G (A-U-G) with tight couples of Escherichia coli ribosomes leads to an exclusive crosslinking of label to protein S18. This crosslinking inhibits A-U-G-directed fMet-tRNAfMet binding into the puromycin-sensitive site of ribosomes and stimulates elongation-factor-dependent binding of Met-tRNAmMet. It is, therefore, concluded that protein S18 is located at or near the aminoacyl-tRNA binding site of E. coli ribosomes. Peptide as well as amino acid analysis shows that the reaction between A-U-G and ribosomes took place at cysteine-10 of protein S18. A-U-G could not be crosslinked to ribosomal proteins of the temperature-sensitive E. coli strain 258ts, where arginine-11 of protein S18 is replaced by a cysteine residue.     

Purification and characterization of Saccharomyces cerevisiae mitochondrial elongation factor Tu

Yeast mitochondrial elongation factor Tu (EF-Tu) was purified 200-fold from a mitochondrial extract of Saccharomyces cerevisiae to yield a single polypeptide of Mr = approximately 47,000. The factor was detected by complementation with Escherichia coli elongation factor G and ribosomes in an in vitro phenylalanine polymerization reaction. Mitochondrial EF-Tu, like E. coli EF-Tu, catalyzes the binding of aminoacyl-tRNA to ribosomes and possesses an intrinsic GTP hydrolyzing activity which can be activated either by kirromycin or by ribosomes. Kinetic and binding analyses of the interactions of mitochondrial EF-Tu with guanine nucleotides yielded affinity constants for GTP and GDP of approximately 5 and 25 microM, respectively. The corresponding affinity constants for the E. coli factor are approximately 0.3 and 0.003 microM, respectively. In keeping with these observations, we found that purified mitochondrial EF-Tu, unlike E. coli EF-Tu, does not contain endogenously bound nucleotide and is not stabilized by GDP. In addition, we have been unable to detect a functional counterpart to E. coli EF-Ts in extracts of yeast mitochondria and E. coli EF-Ts did not detectably stimulate amino acid polymerization with mitochondrial EF-Tu or enhance the binding of guanine nucleotides to the factor. We conclude that while yeast mitochondrial EF-Tu is functionally analogous to and interchangeable with E. coli EF-Tu, its affinity for guanine nucleotides and interaction with EF-Ts are quite different from those of E. coli EF-Tu.     

Common location of determinants in initiator transfer RNAs for initiator-elongator discrimination in bacteria and in eukaryotes

Initiator tRNAs are used exclusively for initiation of protein synthesis and not for elongation. We show that both Escherichia coli and eukaryotic initiator tRNAs have negative determinants, at the same positions, that block their activity in elongation. The primary negative determinant in E. coli initiator tRNA is the C1xA72 mismatch at the end of the acceptor stem. The primary negative determinant in eukaryotic initiator tRNAs is located in the TPsiC stem, whereas a secondary negative determinant is the A1:U72 base pair at the end of the acceptor stem. Here we show that E. coli initiator tRNA also has a secondary negative determinant for elongation and that it is the U50.G64 wobble base pair, located at the same position in the TPsiC stem as the primary negative determinant in eukaryotic initiator tRNAs. Mutation of the U50.G64 wobble base pair to C50:G64 or U50:A64 base pairs increases the in vivo amber suppressor activity of initiator tRNA mutants that have changes in the acceptor stem and in the anticodon sequence necessary for amber suppressor activity. Binding assays of the mutant aminoacyl-tRNAs carrying the C50 and A64 changes to the elongation factor EF-Tu.GTP show marginally higher affinity of the C50 and A64 mutant tRNAs and increased stability of the EF-Tu.GTP. aminoacyl-tRNA ternary complexes. Other results show a large effect of the amino acid attached to a tRNA, glutamine versus methionine, on the binding affinity toward EF-Tu.GTP and on the stability of the EF-Tu.GTP.aminoacyl-tRNA ternary complex.     

Eucaryotic elongation factors Ts is an integral component of rabbit reticulocyte elongation factor 1.

Elongation factor 1 (EF-1) was purified from rabbit reticulocytes and found to contain at least two distinct polypeptides: one of Mr 53 000 and one of Mr 30 000. The 30 000-Mr polypeptide was purified from EF-1 by treatment of the factor with 5.4 M guanidine . HCl and subsequent chromatography on DEAE-BioGel A in the presence of 5 M urea. By a number of functional criteria, the 30 000-Mr polypeptide was found to be the eucaryotic elongation factor Ts (eEF-Ts). These criteria include the ability of the polypeptide to stimulate Artemia salina eEF-Tu-dependent binding of aminoacyl-tRNA to 80-S ribosomes as well as eEF-Tu + EF-2-dependent polyphenylalanine synthesis. The reticulocyte factor also markedly increased the rate of exchange of eEF-Tu . gdp complexes with free GTP. Furthermore, rabbit antibodies to EF-1 from A. salina which was previously shown to contain eEF-Ts [Slobin, L. I. and M?ller, W. (1978) Eur. J. Biochem. 84, 69--77] were found to cross-react with reticulocyte eEF-Ts, suggesting extensive structural homology between brine shrimp and rabbit eEF-Ts. The demonstration that eEF-Ts is and integral component of EF-1 from such diverse sources as brine shrimp and rabbit reticulocytes supports the conclusion that the factor is universally present in eucaryotic EF-1.     

The inhibition of eucaryotic protein synthesis by procaryotic elongation factor Tu

The activity of elongation factor Tu (EF-Tu) from $\text{Escherichia}\text{coli}$ in eucaryotic protein synthesis systems was investigated. EF-Tu was found to inhibit polyphenylalanine synthesis when incubated with $\text{Artemia}$ 80S ribosomes, purified rabbit reticulocyte elongation factor Tu (eEF-Tu) and partially purified reticulocyte translocase enzyme, eEF-G. The inhibition could be overcome by supplying the system with additional eEF-Tu. EF-Tu also inhibited protein synthesis in rabbit reticulocyte lysates. Data presented in this report indicate that inhibition by EF-Tu results from the accumulation of ternary complexes of the protein factor, GTP and aminoacyl-tRNA which do not interact with the ribosomal A-site of 80S ribosomes under physiological conditions.     

Structural homology between elongation factors EF-Tu from Bacillus stearothermophilus and Escherichia coli in the binding site for aminoacyl-tRNA

Elongation factor EF-Tu (Mr approximately equal to 50 000) and elongation factor EF-G (Mr approximately equal to 78 000) were isolated from Bacillus stearothermophilus in a homogeneous form. The ability of EF-Tu to participate in protein synthesis is rapidly inactivated by N-tosyl-L-phenyl-alanylchloromethane (Tos-PheCH2Cl). EF-Tu X GTP is more susceptible to the inhibition by Tos-PheCH2Cl than is EF-Tu X GDP. Tos-PheCH2Cl forms a covalent equimolar complex with the factor by reacting with a cysteine residue in its molecule. The labelling of EF-Tu by the reagent irreversibly destroys its ability to bind aminoacyl-tRNA, which in turn protects the protein from this inactivation. This indicates that the modification of EF-Tu by Tos-PheCH2Cl occurs at the aminoacyl-tRNA binding site of the protein. To identify and characterize the site of aminoacyl-tRNA binding in EF-Tu, the factor was labelled with [14C]Tos-PheCH2Cl, digested with trypsin, the resulting peptides were separated by high-performance liquid chromatography and the sequence of the radioactive peptide was determined. The peptide has identical structure with an Escherichia coli EF-Tu tryptic peptide comprising the residues 75-89 and the Tos-PheCH2Cl-reactive cysteine at position 81 [Jonák, J., Petersen, T. E., Clark, B. F. C. and Rychlík, I. (1982) FEBS Lett. 150, 485-488]. Experiments on photo-oxidation of EF-Tu by visible light in the presence of rose bengal dye showed that there are apparently two histidine residues in elongation factor Tu from B. stearothermophilus which are essential for the interaction with aminoacyl-tRNA. This is clearly reminiscent of a similar situation in E. coli EF-Tu [Jonák, J., Petersen, T. E., Meloun, B. and Rychlík, I. (1984) Eur. J. Biochem. 144, 295-303]. Our results provide further evidence for the conserved nature of the site of aminoacyl-tRNA binding in elongation factor EF-Tu and show that Tos-PheCH2Cl reagent might be a favourable tool for the identification of the site in the structure of prokaryotic EF-Tus.     

Crosslinking of phenylalanyl-tRNA to the ribosomal A site via a photoaffinity probe attached to the 4-thiouridine residue is exclusively to ribosomal protein S19

Phe-tRNA of Escherichia coli, specifically derivatized at the S4U8 position with the 9 A long p-azidophenacyl photoaffinity probe, can be crosslinked to 30 S ribosomal protein when the tRNA is placed at the ribosomal A site. This protein has now been identified by immunological methods. The protein-[3H]Phe-tRNA covalent complex, obtained by extraction with 6 M-urea, was reacted separately with each of the 21 purified antisera to 30 S ribosomal proteins. The double antibody technique was used. Anti-S19 was the only antiserum able to precipitate the radioactivity, and 66 to 81% of the added radioactivity could be precipitated. The same result was obtained with three different ribosome preparations, at low as well as high crosslinking yield, with dipeptidyl-tRNA in the A site as well as aminoacyl-tRNA, and when binding and crosslinking were performed at 20 mM-Mg2+ instead of at 5 mM. Therefore, when aminoacyl-tRNA or peptidyl-tRNA is in the ribosomal A site, position 8, which is always uridine or 4-thiouridine, must be within 9 A of protein S19.     

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.     

Involvement of GTP-regulatory protein in brain prostaglandin E2 receptor and separation of the two components

The specific binding protein for prostaglandin (PG) E2 solubilized from porcine brain was sensitive to guanine nucleotides. GTP inhibited the association and enhanced the dissociation of the specific [3H]PGE2 binding. Scatchard analyses showed that GTP (10 microM) decreased the binding affinity more than 3-fold without major change in the number of binding site. Gel filtration separated the binding site from GTP-regulatory component (N). The separated binding protein had a reduced affinity to PGE2 and lost its sensitivity to GTP. The addition of the separated N restored its responsiveness to GTP, and also increased the binding affinity to the original level. These results provide direct evidence for the molecular interaction between the PGE2 binding protein and N in the brain.     

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.     

The archaeal elongation factor 1alpha bound to GTP forms a ternary complex with eubacterial and eukaryal aminoacyl-tRNA.

The archaeal Sulfolobus solfataricus elongation factor 1alpha (SsEF-1alpha) bound to GTP or to its analogue guanyl-5'-yl imido diphosphate [Gpp(NH)p] formed a ternary complex with either Escherichia coli Val-tRNAVal or Saccharomyces cerevisiae Phe-tRNAPhe as demonstrated by gel-shift and gel-filtration experiments. Evidence of such an interaction also came from the observation that SsEF-1alphaz.rad;Gpp(NH)p was able to display a protective effect against either the spontaneous deacylation or the digestion of aminoacyl-tRNA by RNase A. Protection against the deacylation of aminoacyl-tRNA allowed evaluatation of the affinity of SsEF-1alphaz. rad;Gpp(NH)p for both aminoacyl-tRNAs used. The K'd values of the ternary complex containing S. cerevisiae Phe-tRNAPhe or E. coli Val-tRNAVal were 0.3 microM and 4.4 microM, respectively. In both cases, the affinity of SsEF-1alphaz.rad;Gpp(NH)p for aminoacyl-tRNA was three orders of magnitude lower than that of the homologous eubacterial ternary complexes, but comparable with the affinity shown by the ternary complex involving eukaryal EF-1alpha [Negrutskii, B.S. & El'skaya, A.V. (1998) Prog. Nucleic Acids Res. 60, 47-77]. As already observed with eukaryal EF-1alpha, SsEF-1alpha in its GDP-bound form was also able to protect the ester bond of aminoacyl-tRNA, even though with a 10-fold lower efficiency compared with SsEF-1alphaz.rad;Gpp(NH)p. The overall results indicated that the archaeal elongation factor 1alpha shares several properties with eukaryal EF-1alpha but not with eubacterial EF-Tu.     

Fluorescence labeling of an aminoacyl-tRNA at the 3'-end and its interaction with elongation factor Tu.GTP

A new approach for the fluorescence labeling of an aminoacyl-tRNA at the 3'-end is applied to study its interaction with bacterial elongation factor Tu (EF-Tu) and GTP at equilibrium. The penultimate cytidine residue in yeast tRNATyr-C-C-A was replaced by 2-thiocytidine (s2C). The resulting tRNATyr-C-s2C-A was aminoacylated and then alkylated at the s2C residue with N-(iodoacetylaminoethyl)-5-naphthylamine-1-sulfonic acid (1,5-I-AEDANS). A greater than 100% increase in the intensity of fluorescence emission of the modified Tyr-tRNATyr-C-s2C(AEDANS)-A was observed upon interaction with EF-Tu.GTP. A ternary complex dissociation constant of 1.27 X 10(-8) M was calculated from this direct interaction. Using such fluorescent aminoacyl-tRNA, the affinity of any unmodified aminoacyl-tRNA can be determined by competition experiments. By this approach, we show here that the affinity of unmodified Tyr-tRNATyr-C-C-A is identical to that of the modified Tyr-tRNATyr. This indicates that the fluorescence labeling procedure applied does not alter the affinity of the aminoacyl-tRNA for EF-Tu.GTP. The introduction of 2-thiocytidine into nucleic acids and their labeling with spectroscopic reporter groups may provide a unique means of investigating various types of nucleic acid-protein interactions.     

Localization of the ATP binding site on alpha-tubulin

The binding site for ATP to tubulin was established by use of the photoaffinity label [gamma-32P]N3ATP. Photolysis of the analog in the presence of tubulin resulted in covalent modification of the protein as revealed by autoradiography of electropherograms. Scanning the autoradiograms showed that the ATP analog was bound mainly to the alpha subunit of the tubulin dimer; the alpha subunit was two to three times more radioactive than was the beta subunit. The location of a particular site on the alpha subunit was further defined by peptide maps. The alpha and beta subunits from affinity-labeled tubulin were separated and digested with Staphylococcus protease. Radioactivity was found predominantly in one peptide band from the alpha subunit. The location of the [gamma-32P]N3ATP binding site on the alpha subunit distinguishes it from the previously known exchangeable GTP binding site which is on the beta subunit. Moreover, excess GTP did not compete with [gamma-32P]N3ATP binding. The ATP binding site is distinct from the nonexchangeable GTP binding site. The GTP content of tubulin was the same after dialysis in 0.5 mM ATP as it was following dialysis against ATP-free buffer. Proof that the binding site for [gamma-32P]N3ATP is the same as that for ATP was obtained by competition experiments. In the presence of ATP, photolysis of the affinity analog did not label the alpha subunit preferentially.     

Affinities of tRNA binding sites of ribosomes from Escherichia coli

The binding affinities of tRNAPhe, Phe-tRNAPhe, and N-AcPhe-tRNAPhe from either Escherichia coli or yeast to the P, A, and E sites of E. coli 70S ribosomes were determined at various ionic conditions. For the titrations, both equilibrium (fluorescence) and nonequilibrium (filtration) techniques were used. Site-specific rather than stoichiometric binding constants were determined by taking advantage of the varying affinities, stabilities, and specificities of the three binding sites. The P site of poly(U)-programmed ribosomes binds tRNAPhe and N-AcPhe-tRNAPhe with binding constants in the range of 10(8) M-1 and 5 X 10(9) M-1, respectively. Binding to the A site is 10-200 times weaker, depending on the Mg2+ concentration. Phe-tRNAPhe binds to the A site with a similar affinity. Coupling A site binding of Phe-tRNAPhe to GTP hydrolysis, by the addition of elongation factor Tu and GTP, leads to an apparent increase of the equilibrium constant by at least a factor of 10(4). Upon omission of poly(U), the affinity of the P site is lowered by 2-4 orders of magnitude, depending on the ionic conditions, while A site binding is not detectable anymore. The affinity of the E site, which specifically binds deacylated tRNAPhe, is comparable to that of the A site. In contrast to P and A sites, binding to the E site is labile and insensitive to changes of the ionic strength. Omission of the mRNA lowers the affinity at most by a factor of 4, suggesting that there is no efficient codon-anticodon interaction in the E site. On the basis of the equilibrium constants, the displacement step of translocation, to be exergonic, requires that the tRNA leaving the P site is bound to the E site. Under in vivo conditions, the functional role of transient binding of the leaving tRNA to the E site, or a related site, most likely is to enhance the rate of translocation.     

Covalent cross-linking of transfer ribonucleic acid to the ribosomal P site. Mechanism and site of reaction in transfer ribonucleic acid.

The covalent cross-linking of unmodified Escherichia coli N-acetylvalyl-tRNA to the 16S RNA of Escherichia coli ribosomes upon near-UV irradiation previously reported by us [Schwartz, I., & Ofengand, J. (1978) Biochemistry 17, 2524--2530] has been studied further. Up to 70% of the unmodified tRNA, nonenzymatically bound to tight-couple ribosomes at 7 mM Mg2+, could be cross-linked by 310--335-nm light. Covalent attachment was solely to the 16S RNA. It was dependent upon both irradiation and the presence of mRNA but was unaffected by the presence or absence of 4-thiouridine in the tRNA. The kinetics of cross-linking showed single-hit behavior. Twofold more cross-linking was obtained w-th tight-couple ribosomes than with salt-washed particles. Puromycin treatment after irradiation released the bound N-acetyl[3H]valine, demonstrating that the tRNA was covalently bound at the P site and that irradiation and covalent linking did not affect the peptidyl transferase reaction. Cross-linking was unaffected by the presence of O2, argon, ascorbate (1 mM), or mercaptoethanol (10 mM). Prephotolysis of a mixture of tRNA and ribosomes in the absence of puly(U2,G) did not block subsequent cross-linking in its presence nor did it generate any long-lived chemically reactive species. There was a strong tRNA specificity. E. coli tRNA1Val and tRNA1Ser and Bacillus subtilis tRNAVal and tRNAThr could be cross-linked, but E. coli tRNA2Val, 5-fluorouracil-substituted tRNA1Val, tRNAPhe, or tRNAFMet could not. By sequence comparison of the reactive and nonreactive tRNAs, the site of attachment in the tRNA was deduced to be the 5'-anticodon base, cmo5U, or ,o5U in all of the reactive tRNAs. The attachment site in 16S RNA is described in the accompanying paper [Zimmerman, R. A., Gates, S. M., Schwartz, I., & Ofengand, J. (1979) Biochemistry (following paper in this issue)]. The link between tRNA and 16S RNA is either direct or involves mRNA bases at most two nucleotides apart since use of the trinucleotide GpUpU in place of poly(U2,G) to direct the binding and cross-linking of N-acetylvalyl-tRNA to the P site did not affect either the rate or yield of cross-linking. Both B. subtilis tRNAVal (mo5U) and E. coli tRNA1Val (cmo5U) gave the same rate and yield of cross-linking when directed by the trinucleotide GpUpU. Therefore, the presence of the charged carboxyl group in the cmo5U-containing tRNA apparently does not markedly perturb the orientation of this base with respect to its reaction partner in the 16S RNA. The cross-linking of AcVal-tRNA only takes place from the P site. At 75 mM KCl and 75 mM NH4Cl, less than 0.4% cross-linking was found at the A site, while 55.5% was obtained at the P site. However, when the salt concentration was lowered to 50 mM NH4Cl, 5% cross-linking to the A site was detected, compared to 49% at the P site. Thus, a simple change in the ionic strength of the incubation mixture was able to alter the affinity labeling pattern of the ribosome.     

Negative correlation between the abundance of Escherichia coli aminoacyl-tRNA families and their affinities for elongation factor Tu-GTP

The number of aminoacyl-tRNA molecules in Escherichia coli cells varies by about one order of magnitude from 730 (glutaminyl-tRNA) to 7900 (valyl-tRNA). Relative affinities of E. coli aminoacyl-tRNA for elongation factor Tu-GTP vary also by about one order of magnitude from 2.08 (glutaminyl-tRNA) to 0.15 (valyl-tRNA). The relationship between the abundance of all 20 aminoacyl-tRNA families in 5 E. coli strains and their affinities for elongation factor Tu-GTP was examined by statistical methods. Negative correlation between the two parameters was found. The correlation coefficient was -0.62 to -0.52 with significance level 0.01. Regression analysis give the following formula for the relation between relative abundance of aminoacyl-tRNA families (x) and their relative affinities for elongation factor Tu-GTP (y): y = 1.25 - 0.25x. The analyses indicate that those aminoacyl-tRNA families that are present in cells in low copy number exhibit higher affinity than the more abundant aminoacyl-tRNA families for elongation factor Tu-GTP. The bacterial protein biosynthetic apparatus evolved in such a way as to compensate for a low copy number of some aminoacyl-tRNAs by tight binding of the aminoacyl-tRNA to elongation factor Tu-GTP. This may assure adequate supply of low copy number aminoacyl-tRNAs under conditions of limitation in elongation factor Tu-GTP, e.g. during stringent response, and is consistent with the idea of elongation factor Tu-GTP modulating translational efficiencies of aminoacyl-tRNAs.     

DNA-binding properties of an adenovirus 289R E1A protein.

An adenovirus 2 289 amino acid (289R) E1A protein purified from Escherichia coli has been shown to interact with DNA by two independent methods. UV-crosslinking of complexes containing unmodified, uniformly 32P-labelled DNA and purified E1A protein induced efficient labelling of the protein with covalently attached oligonucleotides, indicating that the E1A protein itself contacts DNA. Discrete nucleoprotein species were also observed when E1A protein--DNA complexes were analysed by gel electrophoresis. Although the 289R E1A protein exhibited no significant binding to single-stranded DNA or to RNA, no evidence for its sequence-specific binding to double-stranded DNA was obtained with either assay. Identification of the sites of covalent attachment of 32P-labelled oligonucleotides by partial proteolysis of the crosslinked E1A protein indicated that the interaction of this protein with DNA is mediated via domain(s) in the C-terminal half of the protein. Such previously unrecognized DNA-binding activity is likely to contribute to the regulatory activities of this important adenoviral protein.     

Affinity labeling at the A-site of Escherichia coli ribosomes by a non-hydrolyzable gamma-amide analog of GTP

gamma-Amides of GTP and affinity and photoaffinity derivatives of gamma-amides of GTP: gamma-anilide of GTP, gamma-(4-azido)anilide of GTP, gamma-[N-(4-azidobenzyl)-N-methyl]amide of GTP, gamma[4-N-(2-chloroethyl)-N-methylaminobenzyl]amide of GTP and gamma-[4-N-(2-oxoethyl)-N-methylaminobenzyl]amide of GTP substituted efficiently for GTP in the EF-Tu-dependent transfer of aminoacyl-tRNA to the ribosome but, in contrast to GTP, they were not hydrolyzed in this process. They represent a new class of non-hydrolyzable GTP analogs with preserved gamma-phosphodiester bond. The radioactive analog of GTP: gamma-[4-N-(2-chloroethyl)-N-methylamino[14C]benzyl]amide of GTP was used as an affinity labeling probe for the identification of components of the GTPase center formed in the EF-Tu-dependent transfer reaction of aminoacyl-tRNA to the ribosomal A-site. Within a six-component complex of poly(U)-programmed E. coli ribosomes with elongation factor Tu, Phe-tRNA(Phe) (at the A-site), tRNA(Phe) (at the P-site) and the [14C]GTP analog, mainly the ribosomal 23S RNA and to a lesser extent the ribosomal proteins L17, L21, S16, S21 and the ribosomal 16S RNA were labeled by the reagent. No significant modification of EF-Tu was detected.