Sordarin inhibits fungal protein synthesis by blocking translocation differently to fusidic acid.

Sordarin derivatives are selective inhibitors of fungal protein synthesis, which specifically impair elongation factor 2 (EF-2) function. We have studied the effect of sordarin on the ribosome-dependent GTPase activity of EF-2 from Candida albicans in the absence of any other component of the translation system. The effect of sordarin turned out to be dependent both on the ratio of ribosomes to EF-2 and on the nature of the ribosomes. When the amount of EF-2 exceeded that of ribosomes sordarin inhibited the GTPase activity following an inverted bell-shaped dose-response curve, whereas when EF-2 and ribosomes were in equimolar concentrations sordarin yielded a typical sigmoidal dose-dependent inhibition. However, when ricin-treated ribosomes were used, sordarin stimulated the hydrolysis of GTP. These results were compared with those obtained with fusidic acid, showing that both drugs act in a different manner. All these data are consistent with sordarin blocking the elongation cycle at the initial steps of translocation, prior to GTP hydrolysis. In agreement with this conclusion, sordarin prevented the formation of peptidyl-[(3)H]puromycin on polysomes from Candida albicans.     

Modification of the accessibility of ribosomal proteins after elongation factor 2 binding to rat liver ribosomes and during translocation

Free- and EF-2-bound 80 S ribosomes, within the high-affinity complex with the non-hydrolysable GTP analog: guanylylmethylenediphosphonate (GuoPP(CH2)P), and the low-affinity complex with GDP, were treated with trypsin under conditions that modified neither their protein synthesis ability nor their sedimentation constant nor the bound EF-2 itself. Proteins extracted from trypsin-digested ribosomes were unambiguously identified using three different two-dimensional gel electrophoresis systems and 5 S RNA release was checked by submitting directly free- and EF-2-bound 80 S ribosomes, incubated with trypsin, to two-dimensional gel electrophoresis. Our results indicate that the binding of (EF-2)-GuoPP[CH2]P to 80 S ribosomes modified the behavior of a cluster of five proteins which were trypsin-resistant within free 80 S ribosomes and trypsin-sensitive within the high-affinity complex (proteins: L3, L10, L13a, L26, L27a). As for the binding of (EF-2)-GDP to 80 S ribosomes, it induced an intermediate conformational change of ribosomes, unshielding only protein L13a and L27a. Quantitative release of free intact 5 S RNA which occurred in the first case but not in the second one, should be related to the trypsinolysis of protein(s) L3 and/or L10 and/or L26. Results were discussed in relation to structural and functional data available on the ribosomal proteins we found to be modified by EF-2 binding.     

Elongation factor 3 (EF-3) from Candida albicans shows both structural and functional similarity to EF-3 from Saccharomyces cerevisiae

As with many other fungi, including the budding yeast Saccharomyces cerevisiae, the dimorphic fungus Candida albicans encodes the novel translation factor, elongation factor 3 (EF-3). Using a rapid affinity chromatography protocol, EF-3 was purified to homogeneity from C. albicans and shown to have an apparent molecular mass of 128 kDa. A polyclonal antibody raised against C. albicans EF-3 also showed cross-reactivity with EF-3 from S. cerevisiae. Similarly, the S. cerevisiae TEF3 gene (encoding EF-3) showed cross-hybridization with genomic DNA from C. albicans in Southern hybridization analysis, demonstrating the existence of a single gene closely related to TEF3 in the C. albicans genome. This gene was cloned by using a 0.7 kb polymerase chain reaction-amplified DNA fragment to screen to C. albicans gene library. DNA sequence analysis of 200 bp of the cloned fragment demonstrated an open reading frame showing 51% predicted amino acid identity between the putative C. albicans EF-3 gene and its S. cerevisiae counterpart over the encoded 65-amino-acid stretch. That the cloned C. albicans sequence did indeed encode EF-3 was confirmed by demonstrating its ability to rescue an otherwise non-viable S. cerevisiae tef3:HIS3 null mutant. Thus EF-3 from C. albicans shows both structural and functional similarity to EF-3 from S. cerevisiae.     

Limited proteolysis of yeast elongation factor 3. Sequence and location of the subdomains

Elongation factor 3 (EF-3) is an ATPase essential for polypeptide chain synthesis in a variety of yeasts and fungi. We used limited proteolysis to study the organization of the subdomains of EF-3. Trypsinolysis of EF-3 at 30 degrees C resulted in the formation of three fragments with estimated molecular masses of 90, 70, and 50 kDa. Yeast ribosomes protected EF-3 and the large fragments from further degradation. ATP exposed a new tryptic cleavage site and stabilized the 70- and 50-kDa fragments. The conformation of EF-3 as measured by fluorescence spectroscopy did not change upon ATP binding. Poly(G) stimulated proteolysis and quenched the intrinsic fluorescence of EF-3. Using gel mobility shift, we demonstrated a direct interaction between EF-3 and tRNA. Neither tRNA nor rRNA altered the tryptic cleavage pattern. The proteolytic products were sequenced by mass spectrometric analysis. EF-3 is blocked NH(2)-terminally by an acetylated serine. The 90-, 70-, and 50-kDa fragments are also blocked NH(2)-terminally, confirming their origin. The 50-kDa fragment (Ser(2)-Lys(443)) is the most stable domain in EF-3 with no known function. The 70-kDa fragment (Ser(2)-Lys(668)) containing the first nucleotide-binding sequence motif forms the core ATP binding subdomain within the 90-kDa domain. The primary ribosome binding site is located near the loosely structured carboxyl-terminal end.     

Functional interaction of yeast elongation factor 3 with yeast ribosomes

Elongation factor 3 (EF-3) is a unique and essential requirement of the fungal translational apparatus. EF-3 is a monomeric protein with a molecular mass of 116,000. EF-3 is required by yeast ribosomes for in vitro translation and for in vivo growth. The protein stimulates the binding of EF-1 alpha :GTP:aa-tRNA ternary complex to the ribosomal A-site by facilitating release of deacylated-tRNA from the E-site. The reaction requires ATP hydrolysis. EF-3 contains two ATP-binding sequence motifs (NBS). NBSI is sufficient for the intrinsic ATPase function. NBSII is essential for ribosome-stimulated activity. By limited proteolysis, EF-3 was divided into two distinct functional domains. The N-terminal domain lacking the highly charged lysine blocks failed to bind ribosomes and was inactive in the ribosome-stimulated ATPase activity. The C-terminally derived lysine-rich fragment showed strong binding to yeast ribosomes. The purported S5 homology region of EF-3 at the N-terminal end has been reported to interact with 18S ribosomal RNA. We postulate that EF-3 contacts rRNA and/or protein(s) through the C-terminal end. Removal of these residues severely weakens its interaction mediated possibly through the N-terminal domain of the protein.     

Candida albicans and three other Candida species contain an elongation factor structurally and functionally analogous to elongation factor 3.

A cell-free poly(U)-dependent translation elongation system from Candida albicans is ATP-dependent due to the presence of an elongation factor 3 (EF3)-like activity. Saccharomyces cerevisiae ribosomes added to a C. albicans postribosomal supernatant (PRS) supported poly(U)-dependent elongation, suggesting that the C. albicans lysate contained a soluble translation factor functionally analogous to the S. cerevisiae translation factor EF-3. The presence of EF-3 in C. albicans was confirmed by Western blotting using an antibody raised against S. cerevisiae EF-3. This antibody was also used to screen a selection of Candida species, all of which possessed EF-3 with molecular mass in the range of 110-130 kDa.     

Purification and properties of a new polypeptide chain elongation factor, EF-1beta, from pig liver.

Eukaryotic polypeptide elongation factor 1 (EF-1) from pig liver has been resolved into two complementary factors, EF-1alpha and EF-1beta (Iwasaki, K., Mizumoto, K., Tanka, M., and Kaziro, Y. (1973) J. Biochem. (Tokyo) 74, 849). This paper describes the procedures for purification of EF-1beta and some properties of the purified factor. The purification method includes an aqueous two-phase separation technique, a treatment of the crude factor with sodium cholate and two successive column chromatographies on diethyl-aminoethyl-Sephadex A-50. By this method, EF-1beta was purified about 50-fold starting from the material obtained after two-phase separation followed by ammonium sulfate fractionation with a recovery of 20%. The purified EF-1beta appeared homogeneous, having a molecular weight of about 90,000. It consisted of two unequal subunits of the molecular weights of 55,000 and 30,000. It stimulates polymerization of phenylalanine dependent on poly(U) in the presence of both EF-1alpha and EF-2, as well as the EF-1alpha-dependent binding of phenylalanyl-tRNA to ribosomes in the presence of GTP. However, it had no effect on the stoichiometric binding of phenylalanyl-tRNA to ribosomes dependent on EF-1alpha in the presence of guanyl-5'-yl methylenediphosphonate. These results indicate that the function of EF-1beta is to stimulate the recycling of EF-1alpha.     

Structural and functional studies of the interaction of the eukaryotic elongation factor EF-2 with GTP and ribosomes

The structure of the guanosine nucleotide binding site of EF-2 was studied by affinity labelling with the GTP analogue, oxidized GTP (oGTP), and by amino acid sequencing of polypeptides generated after partial degradation with trypsin and N-chlorosuccinimide. Native EF-2 contains two exposed trypsin-sensitive cleavage sites. One site is at Arg66 with a second site at Lys571/Lys572. oGTP was covalently bound to the factor between Arg66 and Lys571. After further cleavage of this fragment with the tryptophan-specific cleavage reagent N-chlorosuccinimide, oGTP was found associated with a polypeptide fragment originating from a cleavage at Trp261 and Trp343. The covalent oGTP . EF-2 complex was capable of forming a high-affinity complex with ribosomes, indicating that oGTP, in this respect, induced a conformation in EF-2 indistinguishable from that produced by GTP. Although GTP could be substituted by non-covalently linked oGTP in the factor and ribosome-dependent GTPase reaction, the factor was unable to utilize the covalently bound oGTP as a substrate. This indicates that the conformational flexibility in EF-2 required for the ribosomal activation of the GTPase was inhibited by the covalent attachment of the nucleotide to the factor. EF-2 cleaved at Arg66 were unable to form the high-affinity complex with ribosomes while retaining the ability to form the low-affinity complex and to hydrolyse GTP. The second cleavage at Lys571/Lys572 was accompanied by a total loss of both the low-affinity binding and the GTPase activity.     

Binding of reticulocyte elongation factor 1 to ribosomes and nucleic acids.

The present study has examined the requirements for the binding of rabbit reticulocyte elongation factor 1 (EF-1) to ribosomes under different assay conditions. When a centrifugation procedure was used to separate the ribosome EF-1 complex, the binding of EF-1 to ribosomes required GTP and Phe-tRNA, but not poly(U). The results suggested that undr these conditions a ternary complex, EF-1 . GTP . aminoacyl-tRNA, is necessary for the formation of a ribosome . EF-1 complex. However, when gel filtration was used to isolate the ribosome . EF-1 complex, only template and tRNA were required. These studie emphasize the fact that the procedure used to isolate the ribosome . EF-1 complex determines the requirements for stable complex formation. EF-1 can also interact with nucleic acids such as 28 S and 18 S rRNA, messenger RNA and DNA. In contrast to the binding to ribosomes, EF-1 binding to nucleic acids requires only Mg2+.     

Characterization of the ribosomal properties required for formation of a GTPase active complex with the eukaryotic elongation factor 2

The binding stability of the different nucleotide-dependent and -independent interactions between elongation factor 2 (EF-2) and 80S ribosomes, as well as 60S subunits, was studied and correlated to the kinetics of the EF-2- and ribosome-dependent hydrolysis of GTP. Empty reconstituted 80S ribosomes were found to contain two subpopulations of ribosomes, with approximately 80% capable of binding EF-2.GuoPP[CH2]P with high affinity (Kd less than 10(-9) M) and the rest only capable of binding the factor-nucleotide complex with low affinity (Kd = 3.7 x 10(-7) M). The activity of the EF-2- and 80S-ribosome dependent GTPase did not respond linearly to increasing factor concentrations. At low EF-2/ribosome ratios the number of GTP molecules hydrolyzed/factor molecule was considerably lower than at higher ratios. The low response coincided with the formation of the high-affinity complex. At increasing EF-2/ribosome ratios, the ribosomes capable of forming the high-affinity complex was saturated with EF-2, thus allowing formation of the low-affinity ribosome.EF-2 complex. Simultaneously, the GTPase activity/factor molecule increased, indicating that the low-affinity complex was responsible for activating the GTP hydrolysis. The large ribosomal subunits constituted a homogeneous population that interacted with EF-2 in a low-affinity (Kd = 1.3 x 10(-6) M) GTPase active complex, suggesting that the ribosomal domain responsible for activating the GTPase was located on the 60S subunit. Ricin treatment converted the 80S particles to the type of conformation only capable of interacting with EF-2 in a low-affinity complex. The structural alteration was accompanied by a dramatic increase in the EF-2-dependent GTPase activity. Surprisingly, ricin had no effect on the factor-catalyzed GTP hydrolysis in the presence of 60S subunits alone.     

Modification of the reactivity of three amino-acid residues in elongation factor 2 during its binding to ribosomes and translocation

The accessibility of three amino acids of EF-2, located within highly conserved regions near the N- and C-terminal extremities of the molecule (the E region and the ADPR region, respectively) to modifying enzymes has been compared within nucleotide-complexed EF-2 and ribosomal complexes that mimic the pre- and posttranslocational ones: the high-affinity complex (EF-2)-nonhydrolysable GTP analog GuoPP[CH2]P ribosome and the low-affinity (EF-2)-GDP-ribosome complex, EF-2 and ribosomes being from rat liver. We studied the reactivity of two highly conserved residues diphthamide-715 and Arg-66, to diphtheria-toxin-dependent ADP-ribosylation and trypsin attack, and of a threonine that probably lies between residues 51 and 60, to phosphorylation by a Ca2+/calmodulin-dependent protein kinase. Diphthamide 715 and this threonine residue were unreactive within the high-affinity complex but seemed fully reactive in the low-affinity complex. Arg-66 was resistant to trypsin in both complexes. The possible involvement of the E and ADPR regions of EF-2 in the interaction with ribosome in the two complexes is discussed.     

Purification and characterization of three elongation factors, EF-1 alpha, EF-1 beta gamma, and EF-2, from wheat germ

Three elongation factors, EF-1 alpha, EF-1 beta gamma and EF-2, have been isolated from wheat germ. EF-1 alpha and EF-2 are single polypeptides with molecular weights of approximately 52,000 and 102,000, respectively. The most highly purified preparations of EF-1 beta gamma contain four polypeptides with molecular weights of approximately 48,000, 46,000 and 36,000, 34,000. EF-1 alpha supports poly(U)-directed binding of Phe-tRNA to wheat germ ribosomes and catalyzes the hydrolysis of GTP in the presence of ribosomes, poly(U), and Phe-tRNA. EF-2 catalyzes the hydrolysis of GTP in the presence of ribosomes alone and is ADP-ribosylated by diphtheria toxin to the extent of 0.95 mol of ADP-ribose/mol of EF-2. EF-1 beta gamma decreases the amount of EF-1 alpha required for polyphenylalanine synthesis about 20-fold. EF-1 beta gamma enhances the ability to EF-1 alpha to support the binding of Phe-tRNA to the ribosomes and enhances the GTPase activity of EF-1 alpha. Wheat germ EF-1 alpha, EF-1 beta gamma, and EF-2 support polyphenylalanine synthesis on rabbit reticulocyte ribosomes as well as on yeast ribosomes.     

Structural analysis of Mg2+ and Ca2+ binding to CaBP1, a neuron-specific regulator of calcium channels

CaBP1 (calcium-binding protein 1) is a 19.4-kDa protein of the EF-hand superfamily that modulates the activity of Ca(2+) channels in the brain and retina. Here we present data from NMR, microcalorimetry, and other biophysical studies that characterize Ca(2+) binding, Mg(2+) binding, and structural properties of recombinant CaBP1 purified from Escherichia coli. Mg(2+) binds constitutively to CaBP1 at EF-1 with an apparent dissociation constant (K(d)) of 300 microm. Mg(2+) binding to CaBP1 is enthalpic (DeltaH = -3.725 kcal/mol) and promotes NMR spectral changes, indicative of a concerted Mg(2+)-induced conformational change. Ca(2+) binding to CaBP1 induces NMR spectral changes assigned to residues in EF-3 and EF-4, indicating localized Ca(2+)-induced conformational changes at these sites. Ca(2+) binds cooperatively to CaBP1 at EF-3 and EF-4 with an apparent K(d) of 2.5 microM and a Hill coefficient of 1.3. Ca(2+) binds to EF-1 with low affinity (K(d) >100 microM), and no Ca(2+) binding was detected at EF-2. In the absence of Mg(2+) and Ca(2+), CaBP1 forms a flexible molten globule-like structure. Mg(2+) and Ca(2+) induce distinct conformational changes resulting in protein dimerization and markedly increased folding stability. The unfolding temperatures are 53, 74, and 76 degrees C for apo-, Mg(2+)-bound, and Ca(2+)-bound CaBP1, respectively. Together, our results suggest that CaBP1 switches between structurally distinct Mg(2+)-bound and Ca(2+)-bound states in response to Ca(2+) signaling. Both conformational states may serve to modulate the activity of Ca(2+) channel targets.     

Binding synergy and cooperativity in dihydrodipicolinate reductase: implications for mechanism and the design of biligand inhibitors

Dihydrodipicolinate reductase (DHPR) is a homotetramer that catalyzes reduction of dihydrodipicolinate (DHP). We recently reported a biligand inhibitor ( K i = 100 nM) of DHPR, comprised of fragments that bind in the NADH (CRAA = catechol rhodanine acetic acid) and DHP (PDC = pyridine dicarboxylate) binding sites. Herein, we characterize binding synergy and cooperativity for ligand binding to Escherichia coli DHPR: NADH or CRAA and PDC (stable analog of DHP). While K d values indicate little synergy between NADH and PDC, (1)H- (15)N HSQC chemical shift perturbation and saturation transfer difference (STD) titrations indicate that PDC induces a more dramatic conformational change than NADH, consistent with a role in domain closure. PDC binds cooperatively (Hill coefficient = 2), while NADH does not, based on STD titrations that monitor only fast exchange processes. However, HSQC titrations monitoring Trp253 (located between monomers) indicate that NADH binds in two steps, with high affinity binding to only one of the monomers. Therefore, DHPR binds cofactor via a sequential model, with negative cooperativity. These results, interpreted in light of steady-state data, suggest that DHPR activity requires NADH binding at only one of the four monomers. Implications of our results for fragment assembly are discussed, using CRAA tethering to PDC as a model biligand: (a) if one fragment (ex. PDC) must induce a large structural change before the other fragment is brought proximal, this must be screened for upfront, and (b) cooperative or synergistic interactions between binding sites can lead to unexpected and misleading effects in NMR-based screening.     

Calcium-induced folding of a fragment of calmodulin composed of EF-hands 2 and 3

Calmodulin (CaM) is an EF-hand protein composed of two calcium (Ca(2+))-binding EF-hand motifs in its N-domain (EF-1 and EF-2) and two in its C-domain (EF-3 and EF-4). In this study, we examined the structure, dynamics, and Ca(2+)-binding properties of a fragment of CaM containing only EF-2 and EF-3 and the intervening linker sequence (CaM2/3). Based on NMR spectroscopic analyses, Ca(2+)-free CaM2/3 is predominantly unfolded, but upon binding Ca(2+), adopts a monomeric structure composed of two EF-hand motifs bridged by a short antiparallel beta-sheet. Despite having an "even-odd" pairing of EF-hands, the tertiary structure of CaM2/3 is similar to both the "odd-even" paired N- and C-domains of Ca(2+)-ligated CaM, with the conformationally flexible linker sequence adopting the role of an inter-EF-hand loop. However, unlike either CaM domain, CaM2/3 exhibits stepwise Ca(2+) binding with a K (d1) = 30 +/- 5 microM to EF-3, and a K (d2) > 1000 microM to EF-2. Binding of the first equivalent of Ca(2+) induces the cooperative folding of CaM2/3. In the case of native CaM, stacking interactions between four conserved aromatic residues help to hold the first and fourth helices of each EF-hand domain together, while the loop between EF-hands covalently tethers the second and third helices. In contrast, these aromatic residues lie along the second and third helices of CaM2/3, and thus are positioned adjacent to the loop between its "even-odd" paired EF-hands. This nonnative hydrophobic core packing may contribute to the weak Ca(2+) affinity exhibited by EF-2 in the context of CaM2/3.     

Reduced turnover of the elongation factor EF-1 X ribosome complex after treatment with the protein synthesis inhibitor II from barley seeds

The effect of the protein synthesis inhibitor II from barley seeds (Hordeum sp.) on protein synthesis was studied in rabbit reticulocyte lysates. Inhibitor treatment of the lysates resulted in a rapid decrease in amino acid incorporation and an accumulation of heavy polysomes, indicating an effect of the inhibitor on polypeptide chain elongation. The protein synthesis inhibition was due to a catalytic inactivation of the large ribosomal subunit with no effect on the small subparticle. The inhibitor-treated ribosomes were fully active in participating in the EF-1-dependent binding of [14C]phenylalanyl-tRNA to poly(U)-programmed ribosomes in the presence of GTP and the binding of radioactively labelled EF-2 in the presence of GuoPP[CH2]P. Furthermore, the ribosomes were still able to catalyse peptide-bond formation. However, the EF-1- and ribosome-dependent hydrolysis of GTP was reduced by more than 40% in the presence of inhibitor-treated ribosomes, while the EF-2- and ribosome-dependent GTPase remained unaffected. This suggests that the active domains involved in the two different GTPases are non-identical. Treatment of reticulocyte lysates with the barley inhibitor resulted in a marked shift of the steady-state distribution of the ribosomal phases during the elongation cycle as determined by the ribosomal content of elongation factors. Thus, the content of EF-1 increased from 0.38 mol/mol ribosome to 0.71 mol/mol ribosome, whereas the EF-2 content dropped from 0.20 mol/mol ribosome at steady state to 0.09 mol/mol ribosome after inhibitor treatment. The data suggest that the inhibitor reduces the turnover of ribosome-bound ternary EF-1 X GTP X aminoacyl-tRNA complexes during proof-reading and binding of the cognate aminoacyl-tRNA by inhibiting the EF-1-dependent GTPase.     

Studies on the high molecular weight form of polypeptide chain elongation factor-1 from pig liver. III. Temperature-dependent dissociation into subunits in the presence of GTP

Dissociation of highly purified EF-1 alpha beta gamma (a high molecular weight form of polypeptide chain elongation factor-1) from pig liver into EF-1 alpha and EF-1 beta gamma at various temperatures was examined and the following results were obtained. (i) When dissociation of EF-1 alpha beta gamma was analyzed by gel filtration with Sephacryl S-200, it was found that in the absence of GTP, it did not dissociate at any temperature between 4 and 37 degrees C, whereas in the presence of GTP, it tended to dissociate with elevation of the temperature, and almost complete dissociation was observed at 32 degrees C. This indicated that the dissociation constant of EF-1 alpha beta gamma into EF-1 alpha and EF-1 beta gamma in the presence of GTP increased with increase in the temperature. (ii) When gel filtration was performed in the presence of both GTP and [14C]Phe-tRNA, the formation of a ternary complex of EF-1 alpha . GTP . [14C]Phe-tRNA from EF-1 alpha beta gamma was noted, and its amount was found to increase with elevation of the temperature. (iii) The amount of [14C]Phe-tRNA bound to ribosomes dependent on added EF-1 alpha beta gamma similarly increased with increase in the temperature, as in the case of ternary complex formation, whereas the binding of [14C]Phe-tRNA to ribosomes dependent on free EF-1 alpha proceeded fairly well even at 0 degrees C. From these results we concluded that among the reaction steps in the binding of [14C]Phe-tRNA to ribosomes dependent on EF-1 alpha beta gamma, dissociation of EF-1 alpha beta gamma to form EF-1 alpha . GTP and EF-1 beta gamma in the presence of GTP is the step which is strongly influenced by temperature.     

A human autoantibody specific for a unique conserved region of 28 S ribosomal RNA inhibits the interaction of elongation factors 1 alpha and 2 with ribosomes

An autoantibody reactive with a conserved sequence of 28 S rRNA (anti-28 S) was identified in serum from a patient with systemic lupus erythematosus. Anti-28 S protected a unique 59-nucleotide fragment synthesized in vitro against RNase T1 digestion. RNA sequence analysis revealed that it corresponded to residues 1944-2002 in human 28 S rRNA and 1767-1825 in mouse 28 S rRNA. These sequences are identical and highly conserved throughout all known eukaryotic 28 S rRNAs. In addition, this fragment is homologous to residues 1052-1110 of Escherichia coli 23 S rRNA that lies within the GTP hydrolysis center of the 50 S ribosomal subunit. Anti-28 S and its Fab fragments strongly inhibited poly(U)-directed polyphenylalanine synthesis, but had no effect on ribosomal peptidyltransferase activity. This effect resulted from inhibition of the binding of elongation factors EF-1 alpha and EF-2 to ribosomes and of the associated GTP hydrolysis. The inhibitory effect was almost completely suppressed by preincubation of anti-28 S with 28 S rRNA or in vitro synthesized RNA fragments containing the immunoreactive region. These results show that the immunoreactive conserved region of 28 S rRNA participates in the interaction of ribosomes with the two elongation factors in protein synthesis.     

Characterization of elongation factor 1 from yeast

Two species of elongation factor 1 (EF-1) differing in molecular weight have been obtained from the postribosomal supernatant fraction of yeast by chromatography on Sephadex G-200. These two forms are present in approximately equal amounts and both appear to be of cytoplasmic origin. Preparations of the higher and lower molecular weight forms of EF-1 catalyze the poly(U)-directed binding of N-acetylphenylalanylt-RNA (AcPhe-tRNA) to yeast ribosomes. The AcPhe-tRNA binding activity of these preparations is consistently lower than the phenylalanyl-tRNA (Phe-tRNA) binding activity and is more sensitive to N-ethylmaleimide. However, the AcPhe-tRNA binding activity co-purifies with EF-1 on phosphocellulose and has the same heat inactivation profile. Several lines of evidence indicate that the AcPhe-tRNA is bound to the acceptor site of the ribosomes. These and other data strongly suggest that yeast EF-1 is capable of catalyzing the binding of both Phe-tRNA and AcPhe-tRNA to ribosomes.     

Identification of the sites in the eukaryotic elongation factor 1 alpha involved in the binding of elongation factor 1 beta and aminoacyl-tRNA.

In this article we report the identification of the sites which are involved in the binding of the GDP-exchange factor EF-1 beta and aminoacyl tRNA to the alpha-subunit of the eukaryotic elongation factor 1 (EF-1) from Artemia. For this purpose the polypeptide chain of EF-1 alpha, having 461 amino acid residues, was proteolytically cleaved into large fragments by distinct proteases. Under well defined conditions, a mixture of two large fragments, free from intact EF-1 alpha and with molecular masses of 37 kDa and 43 kDa, was obtained. The 37-kDa and 43-kDa fragments comprise the residues 129-461 and 69-461, respectively. However, in aqueous solution and under non-denaturing conditions, the mixture still contained a short amino-terminal peptide, encompassing the residues 1-36, that remained tightly bound. The ability of the mixture of the 37+43-kDa fragments, including this amino-terminal peptide 1-36, to bind GDP or to facilitate aminoacyl tRNA binding to salt-washed ribosomes was severely reduced, compared to intact EF-1 alpha. However, both of these complexes were able to bind to the GDP-exchange-stimulating subunit EF-1 beta. A 30-kDa fragment, comprising the residues 1-287, was generated after treatment of the protein with endoproteinase Glu-C. This fragment contained the complete guanine nucleotide binding pocket. Although it was able to bind GDP and to transport aminoacyl tRNA to the ribosome, no affinity towards EF-1 beta was observed. We propose that the guanine-nucleotide-exchange stimulation by EF-1 beta is induced through binding of this factor to the carboxy-terminal part of EF-1 alpha. As a result, a decreased susceptibility towards trypsin of the guanine-nucleotide-binding pocket of EF-1 alpha, especially in the region of its presumed effector loop is induced.