Affinity labeling of eukaryotic initiation factor 2 and elongation factor 1 alpha beta gamma with GTP analogs

As part of an attempt to understand the specific function and role of each subunit in multisubunit protein synthesis factors, we have attempted to identify the nucleotide binding peptides of eukaryotic initiation factor 2 (eIF-2). To ensure that the interactions were of a specific nature, two general controls were used: first, other protein factors with characterized GTP binding activity were tested; second, all affinity labeling was checked for nucleotide specificity by protection with the authentic nucleotide at a 10-fold molar excess over the affinity reagent. Results with a number of GTP modifying reagents ([alpha-32P]GTP, [alpha-32P]GDP, oxidized [alpha-32P]GTP, 3'-p-azidobenzoyl-[alpha-32P]GTP, 3'-p-azidobenzoyl-[alpha-32P]GDP, and 5'-p-[8-3H]fluorosulfonylbenzoyl guanosine) indicate that appropriate conditions for both nucleotide and subunit specific labeling have been achieved. Under these conditions all reagents modified the beta subunit of eIF-2. Complementary studies with subunit-deficient forms of eIF-2 also suggest that the beta subunit of eIF-2 is involved with GTP binding. Coupled with other data suggesting that the gamma subunit of eIF-2 might be involved in GTP binding and amino acid sequence data of eIF-2 gamma from which a part of a GTP binding consensus sequence can be localized, support is provided for the concept of alternate GTP binding domains or a GTP binding domain shared between different subunits of eIF-2.     

The 60 S ribosomal subunit as a carrier of eukaryotic initiation factor 2 and the site of reversing factor activity during protein synthesis

Studies on the recycling of eukaryotic initiation factor 2 (eIF-2) during protein synthesis in normal and heme-deficient reticulocyte lysates indicate that eIF-2 binds physiologically to the 60 S ribosomal subunit. Several findings suggest that the 60 S subunit serves as a carrier for eIF-2 during protein synthesis. The addition of purified eIF-2 (beta-32P) to normal hemin-supplemented lysates results in its binding to polyribosomal 60 S subunits; the binding is temperature-dependent. In lysates inhibited by heme deficiency, phosphorylated eIF-2 alpha can be detected on polyribosomal 60 S subunits early in the initial linear phase of protein synthesis; after polyribosomal disaggregation and shut-off of protein synthesis, phosphorylated eIF-2 alpha accumulates on free 60 S ribosome subunits and on the 60 S subunits of 80 S ribosome couples. The phosphorylated eIF-2 alpha associated with the 60 S subunits in heme-deficient lysates appears to be present as the binary complex [eIF-2 (alpha P) X GDP]; the binding of this complex to the 60 S subunit is tight and is not affected by treatment with 25 mM EDTA or by sedimentation in sucrose gradients. Reversal of the inhibition of protein synthesis in heme-deficient lysates by the addition of reversing factor results in a rapid binding of reversing factor to the 60 S subunits and a concomitant dissociation of [eIF-2(alpha P) X GDP]. These findings suggest that the [eIF-2 X GDP] binary complex formed during the assembly of the 80 S initiation complex binds to the 60 S subunit of polyribosomes and is subsequently released by the action of reversing factor.     

Initiation of mammalian protein synthesis. II. The assembly of the initiation complex with purified initiation factors

The assembly of initiation complexes is studied in a protein synthesis initiation assay containing ribosomal subunits, globin [¹²⁵I]mRNA, [³H]Met-tRNA_f, seven purified initiation factors, ATP and GTP. By omitting single components from the initiation assay, specific roles of the initiation factors, ATP and GTP are demonstrated. The initiation factor eIF-2 is required for the binding of Met-tRNA_f to the 40 S ribosomal subunit. The initial Met-tRNA_f binding to the small ribosomal subunit is a stringent prerequisite for the subsequent mRNA binding. The initiation factors eIF-3, eIF-4A, eIF-4B and eIF-4C together with ATP promote the binding of mRNA to the 40 S initiation complex. The association of the 40 S initiation complex with the 60 S ribosome subunit to form an 80 S initiation complex is mediated by the initiation factor eIF-5 and requires the hydrolysis of GTP. The factor eIF-1 gives a twofold overall stimulation of initiation complex formation. A model of the sequential steps in the assembly of the 80 S initiation complex in mammalian protein synthesis is presented.     

Erratum

RNA polynucleotide kinase has been shown to transfer [γ³²P] from ATP to 5-OH termini of endogenous nuclear RNA. The products of this reaction have been isolated in RNA larger than 125 after in vitro incubation of mouse L cell nuclei. About 20%–30% of these 5′-OH kinase products are polyadenylated. A sizeable fraction of the [γ³²P] label from ATP is also found in internal phosphodiester bonds after 30-minute nuclear incubation in vitro. The possibility of substantial [³²P] recycling via the α position of nucleoside triphosphate was ruled out because: (1) 2mM nucleoside triphosphates in the incubation medium, (2) limited nearestneighbor distribution 3′ and 5′ to the phosphodiester bond compared with that from [α³²P] UTP, (3) different nearest-neighbor distribution for RNA molecules > 12S and 12-3S, (4) relative insensitivity of the [γ³²P] incorporation to α-amanitin as compared with total RNA synthesis, (5) internal [³²P] appearance in RNA > 12S in less than five minutes of incubation, and (6) < 0.03% to 0.6% of the total [³²P] in the α position of nucleoside triphosphates after 30 minutes of incubation. The [γ³²P] incorporation was dependent on high ATP concentration and was insensitive to competition by inorganic phosphate. These results are consistent with the levels of 5′ RNA polynucleotide kinase activity in L cell nuclei and suggest the presence of an RNA ligase that can utilize the termini generated by the 5′-OH RNA kinase in a ligation reaction.     

Soybean β-Conglycinin α Subunit is Phosphorylated on Two Distinct Serines by Protein Kinase CK2 In Vitro

Protein kinase CK2 purified from the yeast Yarrowia lipolytica was used to phosphorylate soybean β-conglycinin α subunit. CK2 is known to phosphorylate serines and threonines in the consensus sequence Ser/Thr-X-X-Glu/Asp/SerP/TyrP. β-Conglycinin α subunit (68 kDa) presents seven consensus sequences, but only 0.5–1 mol P/mol α subunit was incorporated by CK2. [³²P]Phosphorylated β-conglycinin α subunit was cleaved either by cyanogen bromide or by trypsin. ³²P was incorporated into the largest cyanogen bromide fragment only (50 kDa, N-terminal) and only two radiolabeled zones were detected after HPLC of the trypsic digest. The corresponding phosphorylated zones were collected and further analyzed by RP-HPLC coupled to electrospray ionization mass spectrometry (LC-ESMS). Two phosphorylated sites, Ser 75 and Ser 117, were determined after MS-MS analysis of three phosphopeptides identified as 70–89, 116–126, and 116–127 sequences. Over the seven consensus sequences of β-conglycinin α subunit, Ser 75 is the only one which was phosphorylated. Ser 117 was phosphorylated although it is not an expected phosphorylation site according to the canonical consensus sequence criteria as there is no acidic determinant at the +3 position. Both Ser 75 and Ser 117 are located inside very acidic sequences, by contrast with the other unphosphorylated potential sites.     

Autophosphorylation of brain microtubule protein: evidence for endogenous protein kinase/phosphoprotein phosphatase cycling and multiple phosphorylation of a microtubule associated protein

Brain microtubule protein, prepared by two types of recycling methods, undergoes “flash” phosphorylation in the presence of [γ-³²p]ATP through sequential action of protein kinase and phosphoprotein phosphatase present in microtubule protein. SDS electrophoretic analysis indicates that MAP₁, tau protein, and tubulin are poorly phosphorylated, and MAP₂ is the major site of phosphorylation. To improve [³²P]phosphoprotein stability in the presence of the kinase/phosphatase cycle, 3′,5′-cyclicAMP, orthophosphate, or fluoride ion may be added. After separation from tubulin by phosphocellulose chromatography, the MAP fraction exhibits autophosphorylation. Finally, the maximal extent of autophosphorylation is observed with an ATP regenerating system using ADP, [³²P]acetyl-P, and bacterial acetate kinase; this results in the incorporation of 3–4 phosphoryl groups per MAP₂ subunit.     

Purification and properties of eIF-2 phosphatase

Eukaryotic initiation factor 2 (eIF-2) phosphatase has been purified 840-fold to apparent homogeneity from rabbit reticulocyte lysate. Native eIF-2 phosphatase has a Mr = 98,000, pI = 6.1, s20,w = 5.1, and a Stokes radius = 38 A. A subunit composition of one 60,000-dalton polypeptide and one 38,000-dalton polypeptide is indicated. The Km for [32P]eIF-2 is 30 microM and the Vmax = 1.1 nmol of phosphate released/min/microgram. The 38,000-dalton subunit of eIF-2 phosphatase does not co-electrophorese with the catalytic subunit of liver phosphorylase phosphatase, a type 1 protein phosphatase. The specificity of eIF-2 phosphatase for phosphorylation sites on th alpha- and beta-subunits of eIF-2 appears to be determined by the environment of the phosphatase and substrate. Both the alpha- and beta-subunits of [32P]eIF-2 are rapidly dephosphorylated by the purified phosphatase. In unfractionated lysate and in unfractionated lysate supplemented with an equivalent activity of the purified phosphatase, only the alpha-subunit of eIF-2 is dephosphorylated. This indicates other factors are present in the lysate which govern the dephosphorylation of eIF-2.     

Regulation of protein synthesis in rabbit reticulocyte lysates. Thiophosphorylation of initiation factor eIF-2 by heme-regulated protein kinase

The heme-regulated protein kinase, which specifically phosphorylates the 38-kDa subunit of initiation factor eIF-2, can utilize adenosine 5'-O-(3-thiotriphosphate) (ATP[gamma S]) as a substrate. The rate of thiophosphorylation is 5-6-times slower than that observed with ATP. It is of special interest that thiophosphorylated derivatives of eIF-2 are resistant to dephosphorylation catalyzed by eIF-2 phosphoprotein phosphatase. The thiophosphorylated eIF-2 is less effective in promoting protein synthesis in hemin-deficient lysates under physiological conditions. In addition, ATP[gamma S] could also be utilized by the self-phosphorylation activity intrinsically associated with HRI.     

Mechanism of interferon action. Purification and substrate specificities of the double-stranded RNA-dependent protein kinase from untreated and interferon-treated mouse fibroblasts

The double-stranded RNA (dsRNA)-dependent protein kinase which catalyzes the phosphorylation of ribosome-associated protein P1 and the alpha subunit of eukaryotic protein synthesis initiation factor 2 (eIF-2) was purified and characterized from mouse fibroblast L929 cells treated with either natural or recombinant interferon and from untreated cells. The dsRNA-dependent P1/eIF-2 alpha kinase was purified at least 1,500-fold from interferon-treated cells; the kinase activity that catalyzed the phosphorylation of eIF-2 alpha copurified with protein P1. The yield of P1/eIF-2 alpha protein kinase activity obtained following purification from cells treated with interferon was about 5-10 times greater than the yield from an equivalent number of untreated cells. The purified protein kinase remained dsRNA dependent. When P1 kinase was activated by dsRNA, a major phosphopeptide designated Xds was phosphorylated; Xds was not phosphorylated from P1 which had not been activated by dsRNA. The apparent native molecular weight of the purified mouse L929 dsRNA-dependent kinase as determined by sedimentation analysis was about 62,000, comparable to the molecular weight of 67,000 determined for denatured L929 phosphoprotein P1 by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The purified protein kinase was highly selective for the alpha subunit of protein synthesis initiation factor eIF-2 and endogenous protein P1. Kinase activity was dependent upon Mg2+, and the Km for ATP was determined to be 5 X 10(-6) M. Histones (H1, H2A-B, H3, and H4) and protein synthesis initiation factors other than eIF-2 (eIF-3, eIF-4A, eIF-4B, and eIF-5) were not substrates or were very poor substrates for the purified dsRNA-dependent protein kinase. N-Ethylmaleimide, ethylenediaminetetraacetic acid, AMP, pyrophosphate, spermine, spermidine, and high concentrations of potassium inhibited both P1 and eIF-2 alpha phosphorylation by the purified kinase, whereas ethylene glycol bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid and phenanthroline did not significantly affect the phosphorylation of either protein P1 or eIF-2 alpha.     

Neuropeptide y inhibits pertussis toxin-catalyzed ADP-ribosylation in bovine adrenal chromaffin cell membranes

Evidence is presented that the neuropeptide Y receptor is directly coupled to an inhibitory G protein existing in cultured bovine adrenal chromaffin cell membranes. Pertussis toxin catalyzes the [³²P]ADP-ribosylation of a 41 kDa plasma membrane protein. 5′-Guanylylimidodiphosphate inhibited the [³²P]ADP labelling of this protein in a dose-dependent manner whereas GTP had no effect. Preincubation of the plasma membranes with high concentrations of neuropeptide Y followed by a brief exposure to a low concentration of 5′-guanylylimidodiphosphate significant;y inhibited ADP-ribosylation beyond that observed with 5′-guanylimidodiphosphate alone. These result suggest that the neuropeptide Y receptor in bovine adrenal chromaffin cells is directly coupled to a 41 kDa PTX substrate (presumably the α subunit of an inhibitory G protein).     

Phosphorothioated binary complex of eukaryotic initiation factor eIF-2 and GDP inhibits protein synthesis in hemin-supplemented reticulocyte lysates

The rabbit reticulocyte heme-regulated eIF-2 alpha kinase (HRI) utilizes adenosine-5'-0-(3-thiotriphosphate) (ATP-gamma-S) as a substrate for its autophosphorylation and activation, and for the phosphorylation of eIF-2. The phosphorothioated binary complex [eIF-2(alpha-[35S]P) . GDP], interacted with the reticulocyte reversing factor (RF) in in vitro assays, and inhibited the ability of RF to catalyze GDP exchange from (eIF-2 . [3H]GDP) complexes. The phosphorothioate residue in the binary complex was resistant to phosphatase action under protein synthesis conditions. eIF-2(alpha-[35S]P) . GDP inhibited protein synthesis in hemin-supplemented lysates with biphasic kinetics, but had no effect on protein synthesis in heme-deficient lysates. The data reported here indicate that phosphorylation of eIF-2 . GDP alone, through the ability of eIF-2(alpha-P) . GDP to bind and sequester RF, is sufficient to inhibit protein chain initiation in the reticulocyte lysate.     

Studies on the metabolism of ATP by isolated bacterial membranes: solubilization and phosphorylation of a protein component of the diglyceride kinase system

A soluble fraction, obtained by extracting E. coli cytoplasmic membrane vesicles with water, transfers radioactivity from [γ-³²P]ATP to a protein present in this soluble fraction. The formation of the [³²P]phosphoprotein appears to be reversible. Thus the protein can transfer its ³²P to ADP to form [³²P]ATP, and the phosphate on the protein can exchange with the phosphate of ATP. Preliminary evidence indicates that the phosphate moiety is linked to a histidine residue of the protein. The Mn²⁺ and ATP dependencies of [³²P]phosphoprotein formation are almost identical to the diglyceride kinase reaction previously reported in intact membrane vesicles. Although indirect evidence supports the involvement of the phosphoprotein in the diglyceride kinase reaction, the soluble fraction catalyzes only a slow formation of [³²P]phosphatidie acid from [γ-³²P]ATP and α,β-diglyceride.     

Isolation of a translational inhibitor from wheat germ with protein kinase activity that phosphorylates initiation factor eIF-2

A translational inhibitor (WGI) has been partially purified from wheat germ extracts. WGI inhibits protein synthesis in rabbit reticulocyte lysates with inhibition kinetics that are similar to those observed in heme-deficiency or by the addition of purified heme-regulated translational inhibitor (HRI). Initiation factor eIF-2 from rabbit reticulocytes overcomes this inhibition. This finding suggests that WGI inhibits protein chain initiation. WGI induced inhibition is enhanced by ATP (2 mM), and overcome by GTP (2 mM) and cyclic-AMP (10 mM). WGI preparations contain a cyclic-AMP independent protein kinase activity that phosphorylates the 38,000-dalton subunit of rabbit reticulocyte eIF-2. The phosphopeptide analyses of eIF-2 phosphorylated by WGI or HRI show that they phosphorylate the same site(s) of eIF-2. HRI phosphorylates the corresponding 38,000-dalton subunit of wheat germ eIF-2. These results obtained with WGI are similar to that of HRI. HRI has been identified as a cyclic-AMP independent protein kinase that phosphorylates the 38,000-dalton subunit of eIF-2 [for review see Ochoa, S. and de Haro, C. (1979) Ann. Rev. Biochem. $\text{48}$, 549]. Hence, these findings with wheat germ-a phylogenetically distant eukaryote, raise further the possibility that phosphorylation-dephosphorylation of eIF-2 may be an important general mechanism in the regulation of eukaryotic protein biosynthesis.     

Effect of Met-tRNAf deacylase on polypeptide chain initiation in rabbit reticulocyte lysate

The possible role of Met-tRNAf deacylase in the regulation of protein synthesis in rabbit reticulocyte lysate by the hemin-controlled translational repressor (HCR) or the double-stranded RNA-activated inhibitor (dsI) has been examined. Inhibition of protein synthesis by either HCR or dsI is associated with a marked increase in the steady state level of 48 S initiation complexes, containing a 40 S ribosomal subunit, globin mRNA, and a reduced level of Met-tRNAf, suggesting that the rate of 60 S subunit addition may be inhibited and that subunit-bound Met-tRNAf may become deacylated by Met-tRNAf deacylase. The addition of highly purified Met-tRNAf deacylase to lysate samples incubated with HCR or dsI reduces the [35S]Met-tRNAf labeling of 48 S complexes to even a lower level but has no effect on the high level of [35S]Met-tRNAf associated with 43 S complexes in the plus hemin control. The effect of added deacylase on the labeling of 48 S complexes with [35S]Met-tRNAf can be overcome by adding eIF-5 or a soluble reticulocyte protein that has been termed the reversing factor, but not by the addition of eIF-2. Added deacylase has no effect on the level of mRNA in 48 S complexes or the labeling of these complexes with [35S]fMet-tRNAf. When lysate samples were labeled with Met-tRNAf, purified from wheat germ or yeast, and doubly labeled with 32P at the 5' end and [35S]methionine aminoacylation, HCR reduced the level of 32P and 35S-labeled tRNAMetf in 48 S complexes to a similar degree, suggesting that once it has become deacylated, tRNAMetf dissociates from the 40 S subunit.     

Maturation hormone induced an increase in the translational activity of starfish oocytes coincident with the phosphorylation of the mRNA cap binding protein,eIF-4E,and the activation of several kinases

The stimulation of translation in starfish oocytes by the maturation hormone, 1-methyladenine (1-MA), requires the activation or mobilization of both initiation factors and mRNAs [Xu and Hille, Cell Regul. 1:1057, 1990]. We identify here the translational initiation complex, eIF-4F, and the guanine nucleotide exchange factor for eIF-2, eIF-2B, as the rate controlling components of protein synthesis in immature oocytes of the starfish, Pisaster orchraceus. Increased phosphorylation of eIF-4E, the cap binding subunit of the eIF-4F complex, is coincident with the initial increase in translational activity during maturation of these oocytes. Significantly, protein kinase C activity increased during oocyte maturation in parallel with the increase in eIF-4E phosphorylation and protein synthesis. An increase in the activities of cdc2 kinase and mitogen-activated myelin basic protein kinase (MBP kinase) similarly coincide with the increase in eIF-4E phosphorylation. However, neither cdc2 kinase nor MBP kinase phosphorylates eIF-4E in vitro. Casein kinase II activity does not change during oocyte maturation, and therefore, cannot be responsible for the activation of translation. Treatment of oocytes with phorbol 12-myristate 13-acetate, an activator of protein kinase C, for 30 min prior to the addition of 1-MA resulted in the inhibition of 1-MA-induced phosphorylation of eIF-4E, translational activation, and germinal vesicle breakdown. Therefore, protein kinase C may phosphorylate eIF-4E, after very early events of maturation. Another possibility is that eIF-4E is phosphorylated by an unknown kinase that is activated by the cascade of reactions stimulated by 1-MA. In conclusion, our results suggest a role for the phosphorylation of eIF-4E in the activation of translation during maturation, similar to translational regulation during the stimulation of growth in mammalian cells. © 1993 Wiley-Liss, Inc.     

Phenyl azide substituted and benzophenone-substituted phosphonamides of 7-methylguanosine 5'-triphosphate as photoaffinity probes for protein synthesis initiation factor eIF-4E and a proteolytic fragment containing the cap-binding site

Three photoactive derivatives of the 7-methylguanosine-containing cap of eukaryotic mRNA were used to investigate protein synthesis initiation factor eIF-4E from human erythrocytes and rabbit reticulocytes. Sensitive and specific labeling of eIF-4E was observed with the previously described probe, [gamma-32P]-gamma-[[(4-benzoylphenyl)methyl]amido]-7-methyl-GTP [Blaas et al. (1982) Virology 116, 339; abbreviated [32P]BPM]. A second probe was synthesized that was an azidophenyltyrosine derivative of m7GTP [( 125I]APTM), the monoanhydride of m7GDP with [125I]-N-(4-azidophenyl)-2-(phosphoramido)-3-(4-hydroxy-3-iodop hen yl) propionamide. This probe allowed rapid and quantitative introduction of radioactivity in the last rather than the first step of synthesis and placed the radioactive label on the protein-proximal side of the weak P-N bond. A dissociation constant of 6.9 microM was determined for [125I]APTM, which is comparable to the published values for m7GTP. m7GTP and APTM were equally effective as competitive inhibitors of eIF-4E labeling with [125I]APTM. Like [32P]BPM, [125I]APTM labeled both the full-length (25 kDa) polypeptide and a 16-kDa degradation product, designated eIF-4E*, with labeling occurring in proportion to the amounts of each polypeptide present. A third probe, an azidophenylglycine derivative of m7GTP [( 32P]APGM), the monoanhydride of m7GDP with [32P]-N-(4-azidophenyl)-2-(phosphoramido)acetamide, was also synthesized and shown to label eIF-4E specifically. Unlike [32P]BPM and [125I]APTM, however, [32P]APGM labeled eIF-4E* approximately 4-fold more readily than intact eIF-4E. Tryptic and CNBr cleavage suggested that eIF-4E* consists of a protease-resistant core of eIF-4E that retains the cap-binding site and consists of approximately residues 47-182.     

Assay of adenosine 3', 5' cyclic monophosphate by stimulation of protein kinase: a method not involving radioactivity

In order to meet a need for a cAMP assay which is not subject to interference by compounds in plant extracts, and which is suitable for use on occasions separated by many ³²P half-lives, an assay based on cAMP-dependent protein kinase has been developed which does not require the use of [γ-³²P]ATP. Instead of measuring the cAMP-stimulated increase in the rate of transfer of [γ-³²P] phosphate from [γ-³²P]ATP to protein, the rate of loss of ATP from the reaction mixture is determined. The ATP remaining after the protein kinase reaction is assayed by ATP-dependent chemiluminescence of the firefly luciferin-luciferase system. Under conditions of the protein kinase reaction in which a readily measurable decrease in ATP concentration occurs, the logarithm of the concentration of ATP decreases in proportion to the cAMP concentration, i.e., the reaction can be described by the equation: [ATP] = [ATP]₀ e^?[cAMP]kt. The assay based on this relationship can detect less than 1 pmol of cAMP. The levels of cAMP found with this assay after partial purification of the cAMP from rat tissue, algal cells, and the media in which the cells were grown agreed with measurements made by the cAMP binding-competition assay of Gilman, and the protein kinase stimulation assay based on transfer of [³²P] phosphate from [γ-³²P]ATP to protein. All of the enzymes and chemicals required for the assay of cAMP by protein kinase catalyzed loss of ATP can be stored frozen for months, making the assay suitable for occasional use.     

The role of protein kinases in ACTH-stimulated steroidogenesis.

The effect of highly purified bovine cytosolic adrenal cortical protein kinase isozyme II catalytic subunit (ATP: Protein Phosphotransferase EC 2.7.1.37) on the formation of pregnenolone from cholesterol in rat and bovine adrenal mitochondrial extracts has been investigated. No stimulation was observed although a low level incorporation of [³²P] from [³²P]-ATP into a component or components of the extract was detected. The mitochondrial extracts contained alkaline phosphatase activity that was inhibited by L-cysteine and dithiothreitol. It is concluded that the acute stimulation by ACTH of corticoid production in the rat adrenal does not involve protein kinase mediated phosphorylation of a component or components of the cholesterol sidechain cleavage mixed-function oxygenase system.     

The association of eIF-2 with Met-tRNAi or eIF-2B alters the specificity of eIF-2 phosphatase

In unfractioned reticulocyte lysate, interaction of eukaryotic initiation factor 2 (eIF-2) with other components regulates the accessibility of phosphatases and kinases to phosphorylation sites on its alpha and beta subunits. Upon addition of eIF-2 phosphorylated on both alpha and beta subunits (eIF-2(alpha 32P, beta 32P) to lysate, the alpha subunit is rapidly dephosphorylated, but the beta subunit is not. In contrast, both sites are rapidly dephosphorylated by the purified phosphatase. The basis of this altered specificity appears to be the association of eIF-2 with other translational components rather than an alteration of the phosphatase. Formation of an eIF-2(alpha 32P,beta 32P) Met-tRNAi X GTP ternary complex prevents dephosphorylation of the beta subunit, but has no effect on the rate of alpha dephosphorylation. eIF-2B, a 280,000-dalton polypeptide complex required for GTP:GDP exchange, also protects the beta subunit phosphorylation site from the purified phosphatase. However, the dephosphorylation of eIF-2(alpha 32P) is inhibited by 75% while complexed with eIF-2B. The altered phosphatase specificity upon association of eIF-2 with eIF-2B also affects the access of protein kinases to these phosphorylation sites. In the eIF-2B X eIF-2 complex, the alpha subunit is phosphorylated at 30% the rate of free eIF-2. Under identical conditions, phosphorylation of eIF-2 beta can not be detected. These results illustrate the importance of substrate conformation and/or functional association with other components in determining the overall phosphorylation state allowed by alterations of kinase and phosphatase activities.     

Phosphorylation site of eukaryotic initiation factor 4E

Eukaryotic protein synthesis initiation factor 4E (eIF-4E) was labeled in situ with [32P]orthophosphate in cultured HeLa cells and rabbit reticulocytes and purified by affinity chromatography. Tryptic digestion yielded one labeled peptide which contained predominantly serine and lysine. After treatment of the protein with citraconic anhydride to block epsilon-amino groups of lysyl residues, tryptic digestion yielded a labeled peptide whose composition was consistent with the structure Trp-Ala-Leu-Trp-Phe-Phe-Lys-Asn-Asp-Lys-Ser(P)-Lys-Thr-Trp-Gln-Ala-Asn-L eu-Arg, one of the arginyl peptides predicted from the human eIF-4E cDNA sequence. The only serine in this peptide is located at position 53 of eIF-4E. Thus, it is concluded that eIF-4E contains a single site of phosphorylation for an endogenous protein kinase, which is Ser-53 in the human eIF-4E sequence.