Protein synthesis in rabbit reticulocytes. A study of the roles of Co-eIF-2, Co-eIF-2A80, and GDP in peptide chain initiation

The roles of Co-eIF-2, Co-eIF-2A80, and GDP in ternary complex and Met-tRNAf X 40 S initiation complex formation were studied. 1) Partially purified eukaryotic initiation factor 2 (eIF-2) (50% pure) preparations contained 0.4-0.6 pmol of bound GDP/pmol of eIF-2. eIF-2 purity was calculated from ternary complex formation in the absence of Mg2+ and in the presence of excess Co-eIF-2. 2) In the absence of Mg2+, approximately 30% of the potentially active eIF-2 molecules formed ternary complexes, and both Co-eIF-2 and Co-eIF-2A80 were equally effective in full activation of the eIF-2 molecules for ternary complex formation. 3) In the presence of Mg2+, approximately 10% of the potentially active eIF-2 molecules formed ternary complexes in the absence of ancillary factors, and the ancillary factors Co-eIF-2A80 and Co-eIF-2 raised the incorporation to 20 and 50% of the eIF-2 molecules, respectively. 4) In the absence of Mg2+, [3H]GDP in preformed eIF-2 X [3H]GDP was readily displaced by GTP during ternary complex formation. 5) In the presence of Mg2+, [3H]GDP remained tightly bound to eIF-2 and ternary complex formation was inhibited. Co-eIF-2, but not Co-eIF-2A80, was effective in promoting [3H]GDP displacement and the former was more effective in promoting ternary complex formation than the latter. 6) eIF-2 X [3H]GDP was converted to eIF-2 X [3H] GTP by incubation in the presence of nucleoside-5'-diphosphate kinase and ATP, but the eIF-2 X [3H]GTP thus formed did not bind Met-tRNAf in the presence of Mg2+ and required exogeneous addition of Co-eIF-2 and GTP for ternary complex formation and GTP displacement. 7) In the absence of Mg2+, the increased ternary complex formed in the presence of eIF-2 X [3H] GDP and Co-eIF-2A80 (with accompanying loss of [3H] GDP) was inactive in a subsequent reaction, which involves Met-tRNAf transfer to 40 S ribosomes (in the presence of Mg2+), and required trace amounts of Co-eIF-2 for such activity. Based on the above observations, we have suggested a two-step activation of eIF-2 molecules by the Co-eIF-2 protein complex for functional ternary complex formation. One of these steps involves the Co-eIF-2A component of Co-eIF-2. This activation results in stimulated Met-tRNAf binding to eIF-2 and is most apparent in the absence of Mg2+ and with aged eIF-2 molecules.(ABSTRACT TRUNCATED AT 400 WORDS)     

A mechanistic study of the formation of hydroxyl radicals induced by horseradish peroxidase with NADH

During the oxidation of NADH by horseradish peroxidase (HRP-Fe(3+)), superoxide (O(-)(2)) is produced, and HRP-Fe(3+) is converted to compound III. Superoxide dismutase inhibited both the generation of O(-)(2) and the formation of compound III. In contrast, catalase inhibited only the generation of O(-)(2). Under anaerobic conditions, the formation of compound III did not occur in the presence of NADH, thus indicating that compound III is produced via formation of a ternary complex consisting of HRP-Fe(3+), NADH and oxygen. The generation of hydroxyl radicals was dependent upon O(-)(2) and H(2)O(2) produced by HRP-Fe(3+)-NADH. The reaction of compound III with H(2)O(2) caused the formation of compound II without generation of hydroxyl radicals. Only HRP-Fe(3+)-NADH (but not K(+)O(-)(2) and xanthine oxidase-hypoxanthine) was able to induce the conversion of metmyoglobin to oxymyoglobin, thus suggesting the participation of a ternary complex made up of HRP-Fe(2+…)O(2)(…)NAD(.) (but not free O(-)(2) or H(2)O(2)) in the conversion of metmyoglobin to oxymyoglobin. It appears that a cyclic pathway is formed between HRP-Fe(3+), compound III and compound II in the presence of NADH under aerobic conditions, and a ternary complex plays the central roles in the generation of O(-)(2) and hydroxyl radicals.     

Spectroscopic studies of ternary complexes of thymidylate synthetase, deoxyribonucleotides, and folate analogs

Conformational changes accompanying the formation of binary and tightly bound ternary complexes of thymidylate synthetase and all possible combinations of three folate analogs (N-10-ethyl-quinazoline, folic acid triglutamate, and folic acid) and three deoxyribonucleotides (5-fluoro-2'-deoxyuridylic acid (FdUMP), 2'-deoxyuridylic acid (dUMP), and thymidylic acid (dTMP] were studied by means of ultraviolet difference spectroscopy. The amplitudes of the spectral changes upon ternary complex formation were 2-3-fold greater than those generated by formation of binary enzyme-nucleotide and enzyme-folate analog complexes. Difference spectra of the ternary complexes all showed a major increase in absorbance in the region of 320-340 nm, presumably due to perturbations of the folate analog chromophores, whereas decreases in absorbance occurred over a range of 260-310 nm. N-10-ethyl-quinazoline tended to form the complex with the greatest filtration efficiency on nitrocellulose filters, followed by folic acid triglutamate and folic acid, whereas among the nucleotides, the most stable complexes were formed with FdUMP, followed by dUMP and dTMP. A correlation was observed between the apparent stability of the ternary complex and the magnitude of the absorbance change in its difference spectrum. The formation of the various ternary complexes showed three different categories of rate behavior: 1) very rapid formation of the complex; 2) biphasic formation with a rapid phase and a slow phase requiring up to 90 min for completion; and 3) in the case of the ternary complex formed with enzyme, FdUMP, and folic acid, only a slow phase of binding. The slow formation of the latter complex was accompanied by concomitantly slow changes in the difference spectrum. However, in those cases of biphasic formation of the complexes, almost all of the spectral change occurred rapidly, and very little of it corresponded to the slow phase of complex formation. To accommodate these observations, a model is proposed involving a sequential interaction of the two subunits of thymidylate synthetase.     

Nucleotide regulation of a eukaryotic protein synthesis initiation complex;.

Formation of a ternary initiation complex containing Met-tRNAf, GTP and eukaryotic initiation factor 2, is the first step in sequential assembly of the initiation complex. The concentration of GTP required for half maximal formation of the ternary complex is 2.5 with 10(-6) M. GDP is a potent competitive inhibitor of ternary complex formation with Ki = 3.4 with 10(-7) M. The nucleotide binding site on eukaryotic initiation factor 2 demonstrates relative specificity for GDP with KD(GDP) = 3.0 with 10(-8) M; 100-fold higher concentrations of GTP than GDP are required for displacement of either [(3)H]GDP or [(3)h]gtp from the necleotide binding site. An ATP-dependent stimulation of ternary complex formation observed in partially purified initiation factor preparations is due to nucleoside diphosphate kinase (EC 2.7.4.6) which serves to remove inhibitory levels of GDP by phosphorylation with ATP. Since GTP is hydrolyzed to GDP during protein synthesis, this provides a mechanism by which the ATP:ADP ratio may regulate the rate of initiation of protein synthesis.     

Inhibition of the initiation of hepatic protein synthesis during ethionine mediated ATP depletion in vivo: modification to ribosomal subunits, evidence of impaired ternary complex formation and a subcellular redistribution of eIF-2 alpha

Acute ethionine intoxication is known to induce a reversible hepatic injury in female rats by reducing the level of hepatic ATP. The injury indirectly impairs the initiation of hepatic protein synthesis, with resultant polysome disaggregation. Administration of adenine rapidly restores the ATP levels and protein synthesis. Analysis of liver polysome and ribosomal subunits reveals that polysome disaggregation occurs following 3 h of the intoxication, and reaggregation occurs following the administration of adenine. Inactive hepatic ribosomes accumulate as monomers and disomes when analysed by sucrose gradient sedimentation in low-salt buffers. High-salt buffers dissociate the inactive ribosomes into the component 40 S and 60 S subunits. The level of higher density, 1.48 g/cc, 40 S subunit increases during the inhibition of protein synthesis, while the lower density, 1.41 g/cc, 40 S subunit species does not change significantly. Hepatic microsomal and cytosolic extracts examined for their ability to support the formation of the ternary complex of eIF-2-GTP and [35S]Met-tRNAi demonstrate that during acute ethionine intoxication, ternary complex formation in the two extracts decrease 65% and 85%, respectively. These changes are coincident with polysome disaggregation. Administration of adenine to reverse the intoxication restores the ternary complex forming ability of the cytosolic extract, but does not affect the activity of the microsomal salt wash extracts. Mixing experiments indicate the accumulation of an inhibitor of ternary complex formation in the microsomal salt wash fraction. The application of quantitative western blotting demonstrates that the level of antigenic eIF-2 alpha in the microsomal salt wash extract increases 31% during the inhibition. These observations are consistent with the idea that the inhibition of the initiation of hepatic protein synthesis induced by ethionine is mediated by eIF-2 alpha phosphorylation. The latter results in an inhibition of ternary complex formation, redistribution of eIF-2 to the microsome fraction, polysomal disaggregation, and accumulation of inactive ribosomal subunits.     

Kinetics of ternary complex formation with fusion proteins composed of the A(1)-adenosine receptor and G protein alpha-subunits.

High affinity agonist binding to G protein-coupled receptors depends on the formation of a ternary complex between agonist, receptor, and G protein. This process is too slow to be accounted for by a simple diffusion-controlled mechanism. We have tested if the interaction between activated receptor and G protein is rate-limiting by fusing the coding sequence of the human A(1)-adenosine receptor to that of Galpha(i-1) (A(1)/Galpha(i-1)) and of Galpha(o) (A(1)/Galpha(o)). Fusion proteins of the expected molecular mass were detected following transfection of HEK293 cells. Ternary complex formation was monitored by determining the kinetics for binding of the high affinity agonist (-)-N(6)-3[(125)I](iodo-4-hydroxyphenylisopropyl)adenosine; these were similar in the wild-type receptor and the fusion proteins over the temperature range of 10 to 30 degrees C. Agonist dissociation may be limited by the stability of the ternary complex. This assumption was tested by creating fusion proteins in which the Cys(351) of Galpha(i-1) was replaced with glycine (A(1)/Galpha(i-1)C351G) or isoleucine (A(1)/Galpha(i-1)C351I) to lower the affinity of the receptor for the G protein. In these mutated fusion proteins, the dissociation rate of the ternary complex was accelerated; in contrast, the rate of the forward reaction was not affected. We therefore conclude that (i) receptor activation per se rather than its interaction with the G protein is rate-limiting in ternary complex formation; (ii) the stability of the ternary complex is determined by the dissociation rate of the G protein. These features provide for a kinetic proofreading mechanism that sustains the fidelity of receptor-G protein coupling.     

Transfer-RNA, magnesium and the formation of ternary complexes by eukaryotic initiation factor eIF-2

The likely concentrations of free magnesium ions in assay systems measuring ternary complex formation with the eukaryotic initiation factor eIF-2 and the exchange of bound GDP have been calculated. Contrary to the suggestion of Roy et al. (Biochem. Biophys. Res. Commun. 146, 114-120) amounts of added tRNA are unlikely to sequester sufficient magnesium ions to affect significantly their role in the assays. There seems little correlation between methionyl-tRNA added and the extent of ternary complex formation in published data other than that expected from mass action. In vivo the concentration of methionyl-tRNA is probably greater than or equal to that of eIF-2 which is shown to be necessary for efficient functioning of the initiation factor.     

Regulation of protein synthesis in eukaryotes. Mode of action of eRF, an eIF-2-recycling factor from rabbit reticulocytes involved in GDP/GTP exchange

The rate of initiation of protein synthesis appears to be controlled at the level of recycling of eIF-2. In this process a new factor, designated eRF, plays an important role. The factor has been purified from the post-ribosomal supernatant and has been called formerly anti-HRI and anti-inhibitor [Amesz, H., Goumans, H., Haubrich-Morree, Th., Voorma, H.O., and Benne, R. (1979) Eur. J. Biochem. 98, 513-520]. Its effect on the initiation of protein synthesis has been studied in several assays: a small but distinct effect is found in the assay for the formation of a ternary complex between eIF-2, GTP and Met-tRNA; a 4-5-fold stimulation is obtained in assays for 40S preinitiation complex formation and in the methionyl-puromycin reaction. In the latter assay a catalytic use of eIF-2 occurs provided that eRF is present. eRF forms a complex with eIF-2 which results in a decrease of the affinity of eIF-2 for GDP, giving it the properties of a GDP/GTP exchange factor. The model stresses the catalytic use of eIF-2 in initiation provided that conditions are met for GDP/GTP exchange by a transient complex formation between eIF-2 and eRF. On the other hand, it is shown that phosphorylation of eIF-2 by the hemin-regulated inhibitor (HRI) abolishes the recycling of eIF-2, by the formation of another stable complex comprising eIF-2 alpha P, GDP and eRF.     

Evaluation and significance of kinetic parameters governing function of protein synthesis initiation factors eIF-2 and eIF-2B

Published data dealing with the formation of the ternary complex eIF-2 X GTP X met-tRNAi involved in eukaryotic initiation have been evaluated to calculate the expected inhibition by GDP and the role of eIF-2B in limiting this inhibition. It is concluded that cellular levels of GDP are unlikely seriously to inhibit ternary complex formation if the reaction can proceed to equilibrium. However, derivation of 'on' and 'off' rates for the interaction of GTP and GDP with eIF-2 demonstrates that these are too slow in the absence of eIF-2B to support active protein synthesis, particularly if eIF-2 is released from ribosomes as eIF-2 X GDP. Whilst eIF-2 X GDP and eIF-2 X GTP appear to dissociate equally slowly, it is concluded that GDP binds to eIF-2 100-times faster than GTP. Addition of eIF-2B has the effect of raising k-1 for both GDP and GTP several hundred-fold and k+1 50- and 7000-fold, respectively. Thus, a kinetic block can be relieved even if there is no change in the thermodynamic state. Phosphorylation of the alpha-subunit of eIF-2 appears to affect only those parameters influenced by eIF-2B. The reported rescue of inhibited lysates by addition of 1 mM GTP is not by mass action but by some other mechanism. Consideration of the kinetic parameters favours the formation of a ternary complex of eIF-2 X eIF-2B X GDP en route to eIF-2 X GTP as opposed to displacement of GDP from eIF-2 X GDP by eIF-2B.     

Self-assembled ternary complex of cationic dendrimer,cucurbituril, and DNA: noncovalent strategy in developing a gene delivery carrier

A ternary complex of PPI-DAB dendrimer [(1,4-diaminobutane); Gen = N; dendri-poly(propyleneimine); -[NHC(=O)CH(2)NH(2)(+)(CH(2))(4)NH(3)(+)](z)()], DNA, and cucurbituril (CB) was evaluated as an example of a totally self-assembled gene delivery carrier. The complex was formed in a noncovalent way in which DNA interacts with PPI-DAB electrostatistically and CB with PPI-DAB through multiple noncovalent interactions. Dynamic light scattering data indicated that the diameter and size distributions of the complexes were dependent upon the sequence of mixing of each component with unimodal distribution ranging from 150.8 to 210.2 nm under favorable conditions. Fluorescence studies showed the quantitative binding of CB to PPI-DAB after ternary complex formation. The complex was able to transfect mammalian cells with high efficiency and the cytotoxicity of the PPI-DAB/CB complex was relatively low.     

Kinetics of ternary complex formation between dihydrofolate reductase, coenzyme, and inhibitors

The kinetics of ligand binding to dihydrofolate reductase from Lactobacillus casei (MTX/R) to form the ternary enzyme-inhibitor-coenzyme complex have been investigated by the stopped-flow fluorescence technique. The fluorescence changes observed when coenzymes or inhibitors bind to the binary complex of the enzyme with the complementary ligand occur in a single fast phase. Under pseudo-first-order conditions the reaction traces could be fitted with precision to a single-exponential decay, and apparent bimolecular rate constants in the range 2 x 10(6) to 3 x 10(7) M-1s-1 have been measured assuming a bimolecular-unimolecular model. The kinetic constants obtained suggest that prior binding of an inhibitor to the enzyme may, to a minor extent, interfere with coenzyme binding but the rates of inhibitor binding seem to be unaffected by the presence of a bound coenzyme. Dissociation rate constants appear to be less than 1 s-1 which suggests that both coenzymes and inhibitors are tightly bound in the ternary complex. An investigation of the effects of pH on the kinetics of ternary complex formation indicated the involvement of ionizable groups in ligand binding, but this shows some ligand dependence. The rates of ligand bindings to form the ternary complex are fairly high, but it is unlikely that these associations are diffusion controlled because their measured activation energies of 7.8-14.5 kcal mol-1 are higher than expected from reactions whose rates are limited by diffusion in aqeous solution.     

An inhibitor of eIF2 activity in the sRNA pool of eukaryotic cells

Eukaryotic protein synthesis is a multi-step and highly controlled process that includes an early initiation complex containing eukaryotic initiation factor 2 (eIF2), GTP, and methionine-charged initiator methionyl-tRNA (met-tRNAi). During studies to reconstruct formation of the ternary complex containing these molecules, we detected a potent inhibitor in low molecular mass RNA (sRNA) preparations of eukaryotic tRNA. The ternary complex inhibitor (TCI) was retained in the total sRNA pool after met-tRNAi was charged by aminoacyl tRNA synthetase, co-eluted with sRNA by size exclusion chromatography, but resolved from met-tRNAi by ion exchange chromatography. The adverse effect of TCI was not overcome by high GTP or magnesium omission and was independent of GTP regeneration. Rather, TCI suppressed the rate of ternary complex formation, and disrupted protein synthesis and the accumulation of heavy polymeric ribosomes in reticulocyte lysates in vitro. Lastly, a component or components in ribosome depleted cell lysate significantly reversed TCI activity. Since assembly of the met-tRNAi/eIF2/GTP ternary complex is integral to protein synthesis, awareness of TCI is important to avoid confusion in studies of translation initiation. A clear definition of TCI may also allow a better appreciation of physiologic or pathologic situations, factors, and events that control protein synthesis in vivo.     

Inhibition of cofactor activity of protein S by a complex of protein S and C4b-binding protein. Evidence for inactive ternary complex formation between protein S, C4b-binding protein, and activated protein C

To elucidate the mechanism by which C4b-binding protein inhibits the cofactor activity of protein S for anticoagulant-activated protein C, the interactions between protein S, activated protein C, and C4b-binding protein were studied using solid-phase enzyme immunoassays. Both activated protein C and C4b-binding protein bound to protein S fixed to microplate wells. C4b-binding protein did not inhibit the binding of activated protein C to protein S, nor did activated protein C inhibit the binding of C4b-binding protein to protein S. Activated protein C bound to a protein S-C4b-binding protein complex which was cross-linked with a chemical reagent as well as it bound to free protein S. Protein S-C4b-binding protein complex competitively inhibited activated protein C-binding to free protein S and also the cofactor activity of free protein S. Immunoblotting analysis showed ternary complex formation with protein S, C4b-binding protein, and activated protein C in the liquid phase by treatment with the cross-linking reagent. These findings suggest that the protein S-C4b-binding protein complex inhibits the cofactor activity of free protein S probably by inhibition of functionally active protein S-activated protein C complex formation by the apparent competitive formation of an inactive ternary complex with protein S, C4b-binding protein, and activated protein C.     

1H NMR study of effects of synergistic anion and metal ion binding on pH titration of the histidinyl side-chain residues of the half-molecules of ovotransferrin

Separation of ovotransferrin into C-terminal (OTf/2C) and N-terminal (OTf/2N) half-molecules has made possible the resolution of all expected histidinyl C(2)H resonances by proton nuclear magnetic resonance at 250 MHz. The chemical shift of many of the resonances decreases with increasing pH, allowing construction of titration curves, whereas a few resonances fail to titrate. On formation of the GaIIIOTf/2(C2O4) ternary complexes, two of the low-field C(2)H resonances in each half-molecule fail to titrate. This behavior implicates the imidazole groups giving rise to these resonances as ligands to the bound metal ion. A third C(2)H resonance in each half-molecule undergoes a marked reduction in pK'a on formation of the ternary complex. The imidazole group displaying this resonance is implicated in a proton-relay scheme involved in binding the synergistic anion, oxalate, and a water of hydration on the bound metal ion. The titration curves for the various imidazole resonances have been fit to a four-parameter equation involving estimation of the pK'a, the limiting chemical shift values, and a Hill constant n. Hill constants of less than 1 can be rationalized by correcting the titration curve for the charge Z on the protein as a function of pH and the work function w. The titration curve for the imidazole group in OTf/2C involved in the proton-relay scheme shows a value for n greater than 1, which suggests positive cooperativity in the titration of this residue. The basis for this behavior cannot be rationalized at this time.(ABSTRACT TRUNCATED AT 250 WORDS)     

Analysis of the ternary interaction of the red cell membrane skeletal proteins spectrin, actin, and 4.1

Spectrin dimers interact weakly with F-actin under physiological solvent conditions (with an association constant of about 5 X 10(3) M-1 at 20 degrees C). In the presence of the membrane skeletal constituent, protein 4.1, strong binding is observed; an analysis of the profiles for formation of a ternary complex leads to an association constant of about 1 X 10(12) M-2. This association becomes weaker at low ionic strength, whereas the opposite applies to the spectrin-actin interaction. The stability of the ternary complex is maximal at physiological ionic strength and somewhat above. The effect of temperature in the range 0-20 degrees C on the formation of the ternary complex is small, whereas the spectrin-actin interaction almost vanishes at low temperature. There is no detectable calcium sensitivity in either the binary or the ternary system within the limits of precision of our assay. The ternary complex resembles the natural system in the membrane in that the actin is resistant to dissociation and unavailable in the deoxyribonuclease assay; after selective proteolytic destruction of spectrin and 4.1, all the actin becomes available. In the absence of 4.1, spectrin dimers do not measurably protect the actin against dissociation.     

DNA binding induces conformational transition within human DNA topoisomerase I in solution

We employed Raman and circular dichroism (CD) spectroscopy to probe the molecular structure of 68-kDa recombinant human DNA topoisomerase I (TopoI) in solution, in a complex with a 16-bp DNA fragment containing a camptothecin-enhanced TopoI cleavage site, and in a ternary complex with this oligonucleotide and topotecan. Raman spectroscopy reveals a TopoI secondary structure transition and significant changes in the hydrogen bonding of the tyrosine residues induced by the DNA binding. CD spectroscopy confirms the Raman data and identifies a DNA-induced (>7%) decrease of the TopoI alpha helix accompanied by at least a 6% increase of the beta structure. The Raman DNA molecular signatures demonstrated a bandshift that is expected for a net change in the environment of guanine C6 [double bond] O groups from pairing to solvent exposure. The formation of a ternary cleavage complex with TopoI, DNA, and topotecan as probed by CD spectroscopy reveals neither additional modifications of the TopoI secondary structure nor of the oligonucleotide structure, compared to the TopoI-oligonucleotide complex.     

pH-dependent conformational states of horse liver alcohol dehydrogenase.

The quenching of liver alcohol dehydrogenase protein fluorescence at alkaline pH indicates two conformational states of the enzyme with a pKa of 9.8+/-0.2, shifted to 10.6+/-0.2 in D2O. NAD+ and 2-p-toluidinonaphthalene-6-sulfonate, a fluorescent probe competitive with coenzyme, bind to the acid conformation of the enzyme. The pKa of the protein-fluorescence quenching curve is shifted toward 7.6 in the presence of NAD+, and the ternary complex formation with NAD+ and trifluoroethanol results in a pH-independent maximal quench. At pH (pD) 10.5, the rate constant for NAD+ binding was 2.6 times faster in D2O2 than in H2O due to the shift of the pKa. Based on these results, a scheme has been proposed in which the state of protonation of an enzyme functional group with a pKa of 9.8 controls the conformational state of the enzyme. NAD+ binds to the acid conformation and subsequently causes another conformational change resulting in the perturbation of the pKa to 7.6. Alcohol then binds to the unprotonated form of the functional group with a pKa of 7.6 in the binary enzyme-NAD+ complex and converts the enzyme to the alkaline conformation. Thus, at neutral pH liver alcohol dehydrogenase undergoes two conformational changes en route to the ternary complex in which hydride transfer occurs.     

Proton nuclear magnetic resonance spectroscopy of human transferrin N-terminal half-molecule: titration and hydrogen-deuterium exchange

The binding of Ga(III) to the proteolytically derived N-terminal half-molecule of human transferrin (HTF/2N) was studied by proton nuclear magnetic resonance spectroscopy. The pH-dependent titration curves of the histidinyl C(2) proton chemical shifts were altered upon formation of the GaIIIHTF/2N(C2O4) ternary complex. Two high-pK'a histidines failed to titrate when the metal and synergistic anion formed a complex with the protein. These results implicated two histidinyl residues as direct ligands to the metal. The rates of hydrogen-deuterium exchange for the C(2) protons of certain histidinyl residues were substantially decreased by metal ion binding. The two ligand histidines were protected from exchange, and a third, low-pK'a, histidinyl residue was protected. We propose that this third histidinyl residue is involved in anion binding and may serve as the base in the putative proton-relay scheme proposed for complex formation.     

Protein synthesis in rabbit reticulocytes. A study of the mechanism of Co-eIF-2 action

The characteristics of component activities in Co-eIF-2 (where eIF is eukaryotic initiation factor) protein complex have been studied. (i) At limiting concentrations, Co-eIF-2 promoted rapid GDP binding to eIF-2 and also GDP displacement from eIF-2 X GDP during ternary complex formation in the presence of GTP and Mg2+ (Co-eIF-2C activity) but did not significantly stimulate ternary complex formation by eIF-2. (ii) At higher concentrations, Co-eIF-2 significantly enhanced ternary complex formation by eIF-2 and also rendered the complex stable to aurintricarboxylic acid presumably as Co-eIF-2 became physically bound to the ternary complex (Co-eIF-2A activity). (iii) Ternary complex preformed in the presence of Co-eIF-2 and without Mg2+ dissociated upon subsequent addition of Mg2+ (Co-eIF-2B activity). This dissociation reaction was presumably due to loss of interaction of the Co-eIF-2A component in Co-eIF-2 with the ternary complex (reversal of Co-eIF-2A activity) as the complex became increasingly sensitive to aurintricarboxylic acid with increasing Mg2+ concentration. In another study, purified eIF-2 was freed of bound GDP by treatment with alkaline phosphatase and the characteristics of native and GDP-free eIF-2 were compared. (i) One mM Mg2+ inhibited (60%) ternary complex formation by native eIF-2 but not by GDP-free eIF-2. Addition of exogenous GDP rendered GDP-free eIF-2 sensitive to Mg2+ indicating that Mg2+ inhibition is due to eIF-2-bound GDP. (ii) In the presence of Mg2+, Co-eIF-2 stimulated similarly ternary and Met-tRNAf X 40 S X AUG complex formation by both native and GDP-free eIF-2. Such stimulatory activity in each case was strongly inhibited by prior phosphorylation of eIF-2 alpha subunit by heme-regulated translational inhibitor. (iii) Ternary complexes preformed using either native and GDP-free eIF-2 and excess Co-eIF-2A80 in the absence of Mg2+ did not form Met-tRNAf X 40 S X AUG complex. They required trace amounts of Co-eIF-2 for such activity.     

Low-affinity interaction of ethanol with the fluorescent complex between horse liver alcohol dehydrogenase and auramine O.

Quenching of the fluorescence of the complex between horse liver alcohol dehydrogenase (alcohol:NAD+ oxidoreductase (EC 1.1.1.1) and auramine O complex is inconsistent with a simple competitive displacement of auramine O by ethanol. Instead, the action of ethanol requires an explanation in terms of a solvent effect, or the formation of an enzyme-auramine O-ethanol ternary complex. The latter complex would have to be the low-affinity variety similar to the enzyme-NADH-ethanol ternary complex encountered in the kinetic system.