A mutant of eukaryotic protein synthesis initiation factor eIF4E(K119A) has an increased binding affinity for both m7G cap analogues and eIF4G peptides.

The eukaryotic multisubunit initiation factor eIF4F is an essential component of the translational machinery. Recognition of the cap structure of mRNA, m(7)GpppN, where N is any nucleotide, by eIF4E is required for initiation of translation. Here we compare the equilibrium and thermodynamic binding characteristics of wild-type eIF4E and a high-affinity mutant, eIF4E(K119A), with those of cap analogues and eIF4G peptides. The temperature-dependent K(d) values for cap analogues were markedly lower, indicating tighter binding, with the eIF4E(K119A) mutant compared with wild-type eIF4E. Although interactions with cap analogues were found to be enthalpically driven, entropic contributions were also significant. Moreover, the binding affinities of eIF4G peptides were 2-4-fold tighter for eIF4E(K119A) than for eIF4E(wt). These results demonstrate that the binding affinity for both the mRNA cap and eIF4G peptides can be simultaneously altered by point mutations distant from either binding site. Entropic contributions to binding suggesting hydrophobic interactions are larger in the mutant protein and are most likely due to a conformational change.

Homeostasis in mRNA initiation: wheat germ poly(A)-binding protein lowers the activation energy barrier to initiation complex formation.

Previous kinetic binding studies of wheat germ protein synthesis eukaryotic initiation factor iso4F (eIFiso4F) and its subunit, eIF4E, with m(7)GTP and mRNA analogues indicated that binding occurred by a two-step process with the first step being too fast to measure by stopped-flow techniques (). Further equilibrium studies showed that poly(A)-binding protein (PABP) enhanced the cap binding of eIFiso4F about 40-fold. The kinetic effects of PABP on cap binding and the temperature dependence of this reaction were measured and compared. Fluorescence stopped-flow studies of the PABP.eIFiso4F protein complex with cap show a concentration-independent conformational change. PABP did not significantly increase the rate of the conformational change, and because the initial second-order binding is essentially diffusion-controlled, the enhancement of cap affinity must reside in the dissociation rate. The dissociation rate was more than 5-fold slower in the presence of PABP. The temperature dependence of the cap binding reaction was markedly reduced in the presence of PABP. The reduced energy barrier for formation of a cap.eIFiso4F complex suggests a more stable platform for further initiation complex formation and a possible means of adapting to varying temperature conditions.

Kinetic proofreading scanning models for eukaryotic translational initiation: the cap and poly(A) tail dependency of translation.

Two simplified kinetic proofreading scanning (KPS) models were proposed to describe the 5' cap and 3' poly(A) tail dependency of eukaryotic translation initiation. In Model I, the initiation factor complex starts scanning and unwinding the secondary structure of the 5' untranslated region (UTR) from the 5' terminus of mRNA. In Model II, the initiation factor complex starts scanning from any binding site in the 5' UTR. In both models, following ATP hydrolysis, the initiation factor complex either dissociates from mRNA or continues to scan and unwind RNA secondary structure in the 5' UTR. This step repeats n times until the AUG codon is reached. These two models show very different cap and/or poly(A) tail dependency of translation initiation. The models predict that both cap and poly(A) tail dependencies of translation, and translatability of mRNAs are coupled with the structure of 5' UTR: the translation of mRNA with structured 5' UTR is strongly cap- and poly(A) tail-dependent; while translation of mRNA with unstructured 5' UTR is less cap- and poly(A) tail-dependent. We use these two models to explain: (1) the cap and poly(A) tail dependence of translation; (2) the effect of exogenous poly(A) on translation; (3) repression of host mRNA and translation of late adenovirus mRNA in the late phase of adenovirus infection; (4) repression of host mRNA and translation of Vaccinia virus mRNA in virus-infected cell; (5) heat shock repression of translation of normal mRNA and stimulation of translation of hsp mRNA; and (6) the synergistic effect of cap and poly(A) tail on stimulating translation. The kinetic proofreading scanning models provide a coherent interpretation of those phenomena.

Wheat germ translation initiation factor eIF4B affects eIF4A and eIFiso4F helicase activity by increasing the ATP binding affinity of eIF4A.

It has been proposed that, during translational initiation, structures in the 5' untranslated region of mRNA are unwound. eIF4A, a member of the DEAD box family of proteins (those that contain a DEAD amino acid sequence), separately or in conjunction with other eukaryotic initiation factors, utilizes the energy from ATP hydrolysis to unwind these structures. As a step in defining the mechanism of helicase activity in the wheat germ protein synthesis system, we have utilized direct fluorescence measurements, ATPase assays, and helicase assays. The RNA duplex unwinding activity of wheat germ eIF4A is similar to other mammalian systems; however, eIF4F or eIFiso4F is required, probably because of the low binding affinity of wheat germ eIF4A for mRNA. Direct ATP binding measurements showed that eIF4A had a higher binding affinity for ADP than ATP, resulting in a limited hydrolysis and procession along the RNA in the helicase assay. The addition of eIF4B resulted in a change in binding affinity for ATP, increasing it almost 10-fold while the ADP binding affinity was approximately the same. The data presented in this paper suggest that eIF4F or eIFiso4F acts to position the eIF4A and stabilize the interaction with mRNA. ATP produces a conformational change which allows a limited unwinding of the RNA duplex. The binding of eIF4B either prior to or after hydrolysis allows for increased affinity for ATP and for the cycle of conformational changes to proceed, resulting in further unwinding and processive movement along the mRNA.

Wheat germ poly(A)-binding protein increases the ATPase and the RNA helicase activity of translation initiation factors eIF4A, eIF4B, and eIF-iso4F.

Recent studies demonstrated that wheat germ poly(A)-binding protein (PABP) interacted with translation eukaryotic initiation factor (eIF)-iso4G and eIF4B, and these interactions increased the poly(A) binding activity of PABP (Le, H., Tanguay, R. L., Balasta, M. L., Wei, C. C., Browning, K. S., Metz, A. M., Goss, D. J., and Gallie, D. R. (1997) J. Biol. Chem. 272, 16247-16255) and the cap binding activity of eIF-iso4F (Wei, C. C., Balasta, M. L., Ren, J., and Goss, D. J. (1998) Biochemistry 37, 1910-1916). We report here that the interaction between PABP and eIF-iso4G has a substantial effect on the ATPase activity and RNA helicase activity of (eIF4A + eIF4B + eIF-iso4F) complex. ATPase kinetic assays show, in the presence of poly(U), PABP can increase the parameter (k(cat)/K(m)) by 3.5-fold with a 2-fold decrease of K(m) for the (eIF4A + eIF-iso4F) complex. In the presence of globin messenger RNA, the ATPase activity of the complex (eIF4A + eIF-iso4F) was increased 2-fold by the presence of PABP. RNA helicase assays demonstrated that the presence of PABP enhanced the RNA duplex unwinding activity of the initiation factor complex. These results suggest that, in terms of the scanning model of translation initiation, PABP may enhance the mRNA scanning rate of the complex formed by eIF4A, eIF4B, and eIF4F or eIF-(iso)4F and increase the rate of translation.

Identification and characterization of a novel cap-binding protein from Arabidopsis thaliana.

Cap-binding proteins specifically bind to the 7-methyl guanosine (m7G) functional group at the 5' end of eukaryotic mRNAs. A novel Arabidopsis thaliana protein has been identified that has sequence similarity to cap-binding proteins but is clearly a different form of the protein. The most obvious primary sequence difference is the substitution of two of the eight conserved tryptophan residues with other aromatic amino acids in the novel protein. Analogous forms of this novel protein appear to be present in other higher eukaryotes but not in yeast. Analysis of the native and recombinant forms of the novel protein by retention on m7GTP-Sepharose indicate that it is a functional cap-binding protein. Measurements of the dissociation constant for this protein indicate that it binds m7GTP 5-20-fold tighter than eukaryotic initiation factor (eIF)(iso)4E. The novel protein also supports the initiation of translation of capped mRNA in vitro. Biochemical analysis and yeast two-hybrid data indicate that it interacts with eIF(iso)4G to form a complex. Based on these observations, this protein appears to be able to function as a cap-binding protein and is given the designation of novel cap-binding protein (nCBP).

Wheat germ poly(A) binding protein enhances the binding affinity of eukaryotic initiation factor 4F and (iso)4F for cap analogues.

Most eukaryotic mRNAs contain a 5' cap (m7GppX) and a 3' poly(A) tail to increase synergistically the translational efficiency. Recently, the poly(A) binding protein (PABP) and cap-binding protein, eIF-4F, were found to interact [Le et al. (1997) J. Biol. Chem. 272, 16247-16255; Tarun and Sachs (1996) EMBO J. 15, 7168-7177]. These data suggest that PABP may exert its effect on translational efficiency either by increasing the formation of initiation factor-mRNA complex or by enhancing ribosome recycling. To investigate the functional consequences of these interactions, the fluorescent cap analogue, ant-m7GTP, which is an environmentally sensitive fluorescent probe [Ren and Goss (1996) Nucleic Acids Res. 24, 3629-3634] was used to investigate the cap-binding affinity. Our data show that the binding of eIF-(iso)4F or eIF-4F to cap analogue enhanced their binding affinity toward PABP approximately 40-fold. Similarly, the eIF-4F/PABP or eIF-(iso)4F/PABP complexes show a 40-fold enhancement of cap analogue binding as compared to eIF-4F or eIF-(iso)4F alone. At least part of the enhancement of the translational initiation by PABP can be accounted for by direct changes in cap-binding affinity. The interactions of these components also suggest a mechanism whereby the poly(A) tail is brought into close proximity with m7G cap. This effect was examined by fluorescence energy transfer, and it was determined that the PABP/eIF-4F complex could bind both poly(A) and 5' cap simultaneously.

Translation initiation factors eIF-iso4G and eIF-4B interact with the poly(A)-binding protein and increase its RNA binding activity.

The 5'-cap and the poly(A) tail act synergistically to increase the translational efficiency of eukaryotic mRNAs, which suggests that these two mRNA elements communicate during translation. We report here that the cap-associated eukaryotic initiation factors (eIFs), i. e. the two isoforms of the cap-binding complex (eIF-4F and eIF-iso4F) and eIF-4B, bind to the poly(A)-binding protein (PABP) both in the presence and absence of poly(A) RNA. The interactions between PABP and eIF-4F, eIF-iso4F, and eIF-4B were measured in the absence of poly(A) RNA using far Western analysis and confirmed by direct fluorescence titration studies. The functional consequence of the interaction between these initiation factors and PABP was examined using RNA binding assays and RNA mobility shift analysis. eIF-4F, eIF-iso4F, and eIF-4B promoted PABP activity through a shift in its equilibrium affinity for poly(A). eIF-iso4G, the large subunit of eIF-iso4F, was the subunit responsible for the interaction between eIF-iso4F and PABP and was the subunit that promoted PABP RNA binding activity. Truncation analysis of eIF-iso4G indicated that a domain close to its N-terminal end appeared to be involved in binding PABP. These results suggest that the interaction between PABP and eIF-4B and eIF-iso4G may be involved in mediating the functional co-dependence observed between the cap and the poly(A) tail during translation.

Expression of functional eIF-4Ehuman: purification, detailed characterization, and its use in isolating eIF-4E binding proteins.

Protein-mRNA cap interactions represent a critical point for regulating gene expression in vivo. For example, a rapid stimulation of gene expression at the mRNA level is mediated by insulin regulating the availability of functional cap-binding protein (eIF-4E). In addition, several viruses modify cap binding proteins to regulate host vs viral gene expression. However, little is known about the molecular details of eIF-4E interactions with m7GTP mRNA caps, with regulatory proteins (e.g., eIF-4E binding proteins), and with proteins within the eIF-4F complex. To study these protein-mRNA and protein-protein interactions in mammalian systems we have constructed a T7 polymerase-driven expression vector containing the coding sequence for human eIF-4E. Recombinant eIF-4Ehuman was purified in a functional state by m7GTP affinity chromatography and Mono Q FPLC. This recombinant protein has biological and physical characteristics that are similar or identical to native eIF-4E. Fluorescence titration studies determined the equilibrium constant for recombinant eIF-4E/m7GTP binding to be 10.1 +/- 0.3 x 10(5) M(-1). To isolate eIF-4E binding proteins, recombinant eIF-4E was linked to agarose beads and incubated with cell lysates. Several proteins were isolated, including a 220-kDa protein that was confirmed to be the p220 subunit of eIF-4F by its proteolysis during incubation with lysates of poliovirus-infected cells. We conclude that recombinant eIF-4E produced in Escherichia coli provides a useful tool for studying eIF-4E/protein and eIF-4E/mRNA cap interactions and their role in regulating mammalian gene expression.

Identification of the cap binding domain of human recombinant eukaryotic protein synthesis initiation factor 4E using a photoaffinity analogue.

Binding of eIF-4E to the 5' m7G cap structure of eukaryotic mRNA signals the initiation of protein synthesis. In order to investigate the molecular basis for this recognition, photoaffinity labeling with [gamma-32P]8-N3GTP was used in binding site studies of human recombinant cap binding protein eIF-4E. Competitive inhibition of this cap analogue by m7GTP and capped mRNA indicated probe specificity for interaction at the protein binding site. Saturation of the binding site with [gamma-32P]8-N3GTP further demonstrated the selectivity of photoinsertion. Aluminum (III)-chelate chromatography and reverse-phase HPLC were used to isolate the binding site peptide resulting from digestion of photolabeled eIF-4E with modified trypsin. Amino acid sequencing identified the binding domain as the region containing the sequence Trp 113-Arg 122.Lys 119 was not identified in sequencing analysis nor was it cleaved by trypsin. These results indicate that Lys 119 is the residue directly modified by photoinsertion of [gamma-32P]8-N3GTP. A detailed understanding of eIF-4E.m7G mRNA cap interactions may lead the way to regulating this essential protein-RNA interaction for specific mRNA in vivo.

pH-dependent and ligand induced conformational changes of eucaryotic protein synthesis initiation factor eIF-(iso)4F: a circular dichroism study.

The structural features of wheat germ protein synthesis initiation factor eIF-(iso)4F, which has a cap binding protein as one of its two subunits, are unknown. In this study, circular dichroism (CD) spectra and secondary structure prediction were obtained for eIF-(iso)4F and its two subunits, p28 and p86. The alpha-helix content of eIF-(iso)4F changed from 42% at pH 6.3 to 15% at pH 7.6, the optimum pH for cap binding. The beta-sheet content increased from 14% (pH 6.3) to 38% at pH 7.6. The CD spectra of the two subunits, p28 and p86 were also measured and analyzed. The separated subunits both had a higher alpha-helix content at pH 7.6 than the native protein, giving values of 60% and 34% alpha-helix for p28 and p86, respectively. Binding of the dinucleotide cap analog to p28 reduced the alpha-helix content to approximately 8% with an increase in the beta sheet content from 10% to 37%. The conformational changes in eIF-(iso)4F upon binding with mRNA are dependent on cap or oligonucleotide structure. A conformation consisting of approximately the same alpha-helix and beta-sheet content can be induced by ligands even at non-optimal pH values. This large conformational transition suggests eIF-(iso)4F binds nucleic acids by interaction of a beta-sheet motif and that this conformational transition may have a regulatory role.

Synthesis of a fluorescent 7-methylguanosine analog and a fluorescence spectroscopic study of its reaction with wheatgerm cap binding proteins.

In the initiation of protein synthesis, the mRNA 5'-terminal 7-methylguanosine cap structure and several recognition proteins play a pivotal role. For the study of this cap binding reaction, one approach is to use fluorescence spectroscopy. A ribose diol-modified fluorescent cap analog, anthraniloyl-m7GTP (Ant-m7GTP), was designed and synthesized for this purpose. This fluorescent cap analog was found to have a high quantum yield, resistance to photobleaching and avoided overlap of excitation and emission wavelengths with those of proteins. The binding of Ant-m7GTP with wheatgerm initiation factors elF-4F and elF-(iso)4F was determined. The fluorescent cap analog and m7GTP had similar interactions with both cap binding proteins. Fluorescence quenching experiments showed that the microenvironment of Ant-m7GTP when bound to protein was hydrophobic.

Mutations at two invariant nucleotides in the 3'-minor domain of Escherichia coli 16 S rRNA affecting translational initiation and initiation factor 3 function.

We have investigated the highly conserved GAUCA sequence of small subunit ribosomal RNA. Within this region, the invariant nucleotides G1530 and A1531 of Escherichia coli 16 S rRNA were mutagenized to A1530/G1531. These base changes caused a lethal phenotype when expressed from a high copy number plasmid. In low copy number plasmids, the mutant ribosomes had limited effects when expressed in vivo but caused significant deficiencies in translation in vitro, affecting enzymatic tRNA binding, non-enzymatic tRNA binding, subunit association, and initiation factor 3 (IF3) binding. Mutant 30 S ribosomal subunits showed a 10-fold decrease in affinity for IF3 as compared to wild-type subunits but showed an increased affinity for IF3 when in 70 S ribosomes. Additionally, IF3 did not promote dissociation of 70 S ribosomes, which had mutated subunits as monitored by light-scattering experiments. However, extension inhibition experiments (toeprinting) showed that IF3 retained its ability to discriminate between initiator and elongator tRNAs on mutated subunits. The results indicate that the two functions of IF3, tRNA discrimination and subunit dissociation, are separable and that the invariant nucleotides are important for correct subunit function during initiation.

Interaction of wheat germ protein synthesis initiation factor eIF-(iso)4F and its subunits p28 and p86 with m7GTP and mRNA analogues.

The binding of p28, p86, and native wheat germ eIF-(iso)4F with m7GTP and oligonucleotides was measured and compared. The purified subunits (p28, 28 kDa and p86, 86 kDa) of wheat germ protein synthesis initiation factor eIF-(iso)4F have been obtained from Escherichia coli expression of the cloned DNA (van Heerden, A., and Browning, K. S. (1994) J. Biol. Chem. 269, 17454-17457). The binding of the 5'-terminal cap analogue m7GTP to the small subunit (p28) of eIF-(iso)4F as a function of pH, temperature, and ionic strength is described. The mode of binding of p28 to cap analogues is very similar to the intact protein. Assuming that all tryptophan residues contribute to p28 and eIF-(iso)4F fluorescence, iodide quenching shows that all 9 tryptophan residues in p28 are solvent-accessible, while only 6 out of 16 tryptophan residues are solvent-accessible on the intact eIF-(iso)4F. The fluorescence stopped-flow studies of eIF-(iso)4F and p28 with cap show a concentration-independent conformational change. The rate of this conformational change was approximately 10-fold faster for the isolated p28 compared with the native eIF-(iso)4F. From these studies it appears that cap recognition resides in the p28 subunit. However, p86 enhances the interaction with capped oligonucleotides and probably is involved in protein-protein interactions as well. Both subunits are required for helicase activity.

Anti-cooperative biphasic equilibrium binding of transcription factor upstream stimulatory factor to its cognate DNA monitored by protein fluorescence changes.

Upstream stimulatory factor USF is a human transcriptional activation factor, which uses a basic/helix-loop-helix/ leucin zipper (b/HLH/Z) motif to homodimerize and recognize specific sequences in the promoter region of both nuclear and viral genes transcribed by RNA polymerase II. Steady state fluorescence spectroscopy demonstrated that the basic/helix-loop-helix/leucin zipper domain of USF binds its DNA targets with high affinity and specificity, whereas removal of the leucine zipper yielding the basic/helix-loop-helix minimal DNA binding region reduces both affinity and specificity. Stopped flow method provided kinetic evidence for a two-step binding process involving rapid formation of a protein-DNA intermediate followed by a slow isomerization step, which is consistent with the basic region undergoing a random coil to alpha-helix folding transition on specific DNA recognition. The leucine zipper is also necessary for USF to function as a bivalent homotetramer, capable of binding two distinct recognition sites simultaneously and mediating DNA looping under physiologic conditions. Titration studies revealed that the first binding event has a equilibrium constant Keq = (2.2 +/- 2.0) x 10(9) M-1 for major late promoter DNA, whereas the second binding event occurs with a remarkable reduced affinity, Keq = (1.2 +/- 0.8) x 10(8) M-1. This anticooperative feature of DNA binding by the homotetramer suggests that USF stimulates transcription by mediating DNA looping between nearby recognition sites located in class II nuclear and viral gene promoters.

Chromatographic resolution of in vivo phosphorylated and nonphosphorylated eukaryotic translation initiation factor eIF-4E: increased cap affinity of the phosphorylated form.

Eukaryotic translation initiation factor eIF-4E plays a central role in the recognition of the 7-methylguanosine-containing cap structure of mRNA and the formation of initiation complexes during protein synthesis. eIF-4E exists in both phosphorylated and nonphosphorylated forms, and the primary site of phosphorylation has been identified. Previous studies have suggested that eIF-4E phosphorylation facilitates its participation in protein synthesis. However, the biochemical basis for the functional difference between the two forms of eIF-4E is unknown. To address this directly, we have developed a method for the separation of phosphorylated and nonphosphorylated eIF-4E from rabbit reticulocytes by chromatography on rRNA-Sepharose. Using the resultant purified forms, we have studied the protein's interaction with the cap analogs m7GTP and m7GpppG and with the cap of globin mRNA by fluorescence quenching of tryptophan residues. It was found that phosphorylated eIF-4E had 3- to 4-fold greater affinity for cap analogs and mRNA than nonphosphorylated eIF-4E. The equilibrium binding constants (x 10(5), expressed as M-1) for the interaction of phosphorylated eIF-4E with m7GTP, m7GpppG, and globin mRNA were 20.0 +/- 0.1, 16.4 +/- 0.1, and 31.0 +/- 0.1, respectively, whereas those for the nonphosphorylated form were 5.5 +/- 0.4, 4.3 +/- 0.4, and 10.0 +/- 0.1, respectively. Treatment with potato acid phosphatase converted the phosphorylated form to the nonphosphorylated form and decreased the binding constant for m7GTP by a factor of 3. The increased affinity for mRNA caps may account for the in vivo and in vitro correlations between eIF-4E phosphorylation and accelerated protein synthesis and cell growth.

An interaction of wheat germ initiation factor 4B with oligoribonucleotides.

The binding of oligoribonucleotides to wheat germ protein synthesis initiation factor eIF-4B was measured by direct fluorescence techniques. An analysis of the equilibrium association constants (Keq) indicates that eIF-4B binding is not affected by the m7GTP cap structure or the AUG. eIF-4B is insensitive to hairpin structures within the oligoribonucleotide. The binding site size is approximately 18 bases. The binding of oligoribonucleotide to eIF-4B as a function of pH, temperature, and ionic strength is also described. The pH-dependent binding showed an increase in binding with increasing pH in contrast to the sharp pH optimum observed for cap binding protein eIF-4E (Carberry, S. E., Darzynkiewicz, E., and Goss, D.J. (1991) Biochemistry 30, 1624-1627). Assuming all tryptophan residues contribute to the observed fluorescence, iodide quenching showed that 8(+/- 1) out 9 of eIF-4B's tryptophan residues are on the surface of the eIF-4B protein. A specific anion effect of Cl- on eIF-4B binding to oligoribonucleotide was found when comparing the ionic strength effect of KC2H3O2 and KCl.

Characterization of the ATP-dependent binding of wheat germ protein synthesis initiation factors eIF-(iso)4F and eIF-4A to mRNA.

The ATP-dependent binding of wheat germ protein synthesis initiation factors eIF-(iso)4F and eIF-4A to an oligoribonucleotide has been investigated by direct fluorescence titration techniques. In addition, the effect of ATP on the interaction between another cap-binding initiation factor, eIF-4F, and eIF-4A was studied using the same methods. Comparison of the equilibrium association constants (K(eq)) indicate that 1) hydrolyzable ATP affects the affinity of eIF-(iso)4F for eIF-4A, regardless of whether or not mRNA was previously bound to the eIF-(iso)4F; in contrast, ATP had no effect on the eIF-(iso)4F/oligoribonucleotide interaction; 2) in the presence of ATP, the binding of the binary eIF-(iso)4F.eIF-4A complex to the oligoribonucleotide is of similar affinity as the binding of the oligoribonucleotide to the eIF-(iso)4F alone; the stoichiometry of this ternary eIF-(iso)4F.eIF-4A.mRNA complex was found to be 1:1:1; and 3) a similar ATP effect is observed for the eIF-4F/eIF-4A interaction as for the eIF-(iso)4F.eIF-4A complex.

Strategies for the computation of infrared CD and absorption spectra of biological molecules: ribonucleic acids.

We report observed and computed infrared (vibrational) circular dichroism spectra of a number of polyribonucleic acids in aqueous solutions in the 1600-1750 cm-1 spectral region, in which C = O and some nucleotide base ring stretching vibrations occur. The experimental data are compared with results calculated using different levels of sophistication within the exciton approach. We find that observed band shapes are generally well reproduced by these models, particularly if care is taken to determine the direction of the vibrational dipole transition moments accurately.

Binding of protein synthesis initiation factor 4E to oligoribonucleotides: effects of cap accessibility and secondary structure.

The binding of rabbit globin mRNA to the 25-kDa cap binding protein eIF-4E from human erythrocytes was found to be 5.3-fold stronger than the binding of the cap analogue m7GpppG to eIF-4E [Gross et al. (1990) Biochemistry 29, 5008-5012]. In order to investigate whether this effect is due to the longer sequence of nucleotides in globin mRNA or to other features such as cap accessibility or secondary structure, oligoribonucleotide analogues of rabbit alpha-globin mRNA were synthesized by T7 RNA polymerase from a synthetic oligodeoxynucleotide template in the presence of m7GpppG; these oligoribonucleotide analogues possess varying degrees of cap accessibility and secondary structure. Equilibrium association constants for the interaction of these oligoribonucleotides and purified human erythrocyte eIF-4E were obtained from direct fluorescence titration experiments. The data indicate that while the presence of the m7G cap is required for efficient recognition by eIF-4E, the cap need not be completely sterically accessible, since other structural features within the mRNA also influence binding.