Characterization of the two eIF4A-binding sites on human eIF4G-1.

Eukaryotic translation initiation factor 4G-1 (eIF4G) plays a critical role in the recruitment of mRNA to the 43 S preinitiation complex. eIF4G has two binding sites for the RNA helicase eIF4A, one in the central domain and one in the COOH-terminal domain. Recombinant eIF4G fragments that contained each of these sites separately bound eIF4A with a 1:1 stoichiometry, but fragments containing both sites bound eIF4A with a 1:2 stoichiometry. eIF3 did not interfere with eIF4A binding to the central site. Interestingly, at the same concentration of free eIF4A, more eIF4A was bound to an eIF4G fragment containing both eIF4A sites than the sum of binding to fragments containing the single sites, indicating cooperative binding. Binding of eIF4A to an immobilized fragment of eIF4G containing the COOH-terminal site was competed by a soluble eIF4G fragment containing the central site, indicating that a single eIF4A molecule cannot bind simultaneously to both sites. The association rate constant, dissociation rate constant, and dissociation equilibrium constant for each site were determined by surface plasmon resonance and found to be, respectively, 1.2 x 10(5) m(-1) s(-1), 2.1 x 10(-3) s(-1), and 17 nm for the central site and 5.1 x 10(3) m(-1) s(-1), 1.7 x 10(-3) s(-1), and 330 nm for the COOH-terminal site.

Mutually cooperative binding of eukaryotic translation initiation factor (eIF) 3 and eIF4A to human eIF4G-1.

Eukaryotic translation initiation factor 4G-1 (eIF4G) plays a critical role in the recruitment of mRNA to the 43 S preinitiation complex. The central region of eIF4G binds the ATP-dependent RNA helicase eIF4A, the 40 S binding factor eIF3, and RNA. In the present work, we have further characterized the binding properties of the central region of human eIF4G. Both titration and competition experiments were consistent with a 1:1 stoichiometry for eIF3 binding. Surface plasmon resonance studies showed that three recombinant eIF4G fragments corresponding to amino acids 642-1560, 613-1078, and 975-1078 bound eIF3 with similar kinetics. A dissociation equilibrium constant of approximately 42 nm was derived from an association rate constant of 3.9 x 10(4) m(-1) s(-1) and dissociation rate constant of 1.5 x 10(-3) s(-1). Thus, the eIF3-binding region is included within amino acid residues 975-1078. This region does not overlap with the RNA-binding site, which suggests that eIF3 binds eIF4G directly and not through an RNA bridge, or the central eIF4A-binding site. Surprisingly, the binding of eIF3 and eIF4A to the central region was mutually cooperative; eIF3 binding to eIF4G increased 4-fold in the presence of eIF4A, and conversely, eIF4A binding to the central (but not COOH-terminal) region of eIF4G increased 2.4-fold in the presence of eIF3.

Functional characterization of five eIF4E isoforms in Caenorhabditis elegans.

Recognition of the 5'-cap structure of mRNA by eIF4E is a critical step in the recruitment of most mRNAs to the ribosome. In Caenorhabditis elegans, approximately 70% of mRNAs contain an unusual 2,2,7-trimethylguanosine cap structure as a result of trans-splicing onto the 5' end of the pre-mRNA. The characterization of three eIF4E isoforms in C. elegans (IFE-1, IFE-2, and IFE-3) was reported previously. The present study describes two more eIF4E isoforms expressed in C. elegans, IFE-4 and IFE-5. We analyzed the requirement of each isoform for viability by RNA interference. IFE-3, the most closely related to mammalian eIF4E-1, binds only 7-methylguanosine caps and is essential for viability. In contrast, three closely related isoforms (IFE-1, IFE-2, and IFE-5) bind 2,2, 7-trimethylguanosine caps and are partially redundant, but at least one functional isoform is required for viability. IFE-4, which binds only 7-methylguanosine caps, is most closely related to an unusual eIF4E isoform found in plants (nCBP) and mammals (4E-HP) and is not essential for viability in any combination of IFE knockout. ife-2, ife-3, ife-4, and ife-5 mRNAs are themselves trans-spliced to SL1 spliced leaders. ife-1 mRNA is trans-spliced to an SL2 leader, indicating that its gene resides in a downstream position of an operon.

Enteroviral protease 2A cleaves dystrophin: evidence of cytoskeletal disruption in an acquired cardiomyopathy.

Enteroviruses such as Coxsackievirus B3 can cause dilated cardiomyopathy, but the mechanism of this pathology is unknown. Mutations in cytoskeletal proteins such as dystrophin cause hereditary dilated cardiomyopathy, but it is unclear if similar mechanisms underlie acquired forms of heart failure. We demonstrate here that purified Coxsackievirus protease 2A cleaves dystrophin in vitro as predicted by computer analysis. Dystrophin is also cleaved during Coxsackievirus infection of cultured myocytes and in infected mouse hearts, leading to impaired dystrophin function. In vivo, dystrophin and the dystrophin-associated glycoproteins alpha-sarcoglycan and beta-dystroglycan are morphologically disrupted in infected myocytes. We suggest a molecular mechanism through which enteroviral infection contributes to the pathogenesis of acquired forms of dilated cardiomyopathy.

Direct cleavage of elF4G by poliovirus 2A protease is inefficient in vitro.

Previously, the purified recombinant 2A proteases (2Apro) of coxsackievirus B4 (CVB4) and human rhinovirus type 2 (HRV2) were shown to cleave synthetic peptides derived from human or rabbit elF4G as well as elF4G protein purified from rabbit reticulocytes. These results were in contrast to previous evidence which supported the view that elF4G cleavage activity in poliovirus-infected HeLa cells required a cellular factor(s) activated by poliovirus (PV) 2Apro. In the present study, recombinant PV 2Apro was shown to cleave either rabbit or human elF4G or their derived peptides in direct cleavage reactions, but cleaved the 4G-derived peptides with 100-fold lower efficiency than with a peptide derived from the poliovirus polyprotein. In these experiments, up to 25-fold molar excess of 2Apro over elF4G protein was required to cause greater than 50% cleavage. CVB4 2Apro was also tested in peptide cleavage assays under the same conditions as PV 2Apro and was found to cleave all elF4G substrates with efficiencies similar to PV 2Apro. Finally, cleavage reactions utilizing recombinant elF4G containing a G486E substitution at the cleavage site for CVB4 and HRV2 proteases resulted in drastically reduced cleavage by PV 2Apro, similar to the reduction previously seen with HRV2 and CVB4 2Apro, confirming that all three viral 2A proteases recognize the same cleavage site on elF4G. These data show that PV 2Apro can directly cleave elF4G in vitro with efficiencies similar to those of CVB 2Apro, but cleavage efficiency of elF4G is approximately 1000-fold lower than cleavage of a peptide derived from the authentic 2A cleavage site on the poliovirus polyprotein.

Multiple isoforms of eukaryotic protein synthesis initiation factor 4E in Caenorhabditis elegans can distinguish between mono- and trimethylated mRNA cap structures.

The rate-limiting step for cap-dependent translation initiation in eukaryotes is recruitment of mRNA to the ribosome. An early event in this process is recognition of the m7GTP-containing cap structure at the 5'-end of the mRNA by initiation factor eIF4E. In the nematode Caenorhabditis elegans, mRNAs from 70% of the genes contain a different cap structure, m32,2,7GTP. This cap structure is poorly recognized by mammalian elF4E, suggesting that C. elegans may possess a specialized form of elF4E that can recognize m32,2,7GTP. Analysis of the C. elegans genomic sequence data base revealed the presence of three elF4E-like genes, here named ife-1, ife-2, and ife-3. cDNAs for these three eIF4E isoforms were cloned and sequenced. Isoform-specific antibodies were prepared from synthetic peptides based on nonhomologous regions of the three proteins. All three eIF4E isoforms were detected in extracts of C. elegans and were retained on m7GTP-Sepharose. One eIF4E isoform, IFE-1, was also retained on m32,2,7GTP-Sepharose. Furthermore, binding of IFE-1 and IFE-2 to m7GTP-Sepharose was inhibited by m32,2,7GTP. These results suggest that IFE-1 and IFE-2 bind both m7GTP- and m32,2, 7GTP-containing mRNA cap structures, although with different affinities. In conjunction with IFE-3, these eIF4E isoforms would permit cap-dependent recruitment of all C. elegans mRNAs to the ribosome.

A single amino acid change in protein synthesis initiation factor 4G renders cap-dependent translation resistant to picornaviral 2A proteases.

Infection of cells with picornaviruses of the rhino-, aphtho-, and enterovirus groups causes a shut-off in cap-dependent translation of cellular mRNAs but permits cap-independent viral RNA translation to proceed. This shut-off is thought to be mediated in part by the proteolytic cleavage of eukaryotic initiation factor 4G (eIF4G), although there is evidence to the contrary. Cleavage of eIF4G results in the separation of the eIF4E-binding domain from the ribosome- and helicase-binding domains of the factor, thereby limiting the ability of eIF4G to function in cap-dependent recruitment of mRNAs. Previously we determined the cleavage site within eIF4G targeted by the 2A proteases from human coxsackievirus serotype B4 and human rhinovirus serotype 2 using highly purified eIF4F and recombinant proteases. To examine further the role proteolysis of eIF4G plays in shut-off of translation, we altered the 2A cleavage site in human eIF4G by site-directed mutagenesis. Strikingly, the replacement of one amino acid at the 2A cleavage site resulted in a protein that is approximately 100-fold resistant to cleavage by coxsackievirus 2A protease and 10-50-fold for rhinovirus 2A. Alteration of the cleavage site had no effect on factor activity since the variant was just as active as wild-type eIF4G in restoring cap-dependent translation to an in vitro translation system depleted of endogenous eIF4G. Furthermore, the presence of the variant form of eIF4G rendered in vitro translation reactions resistant to the 2A protease-mediated inhibition of cap-dependent translation initiation. These results support the model that 2A proteases inhibit cap-dependent translation through direct proteolysis of eIF4G.

Mapping of functional domains in eukaryotic protein synthesis initiation factor 4G (eIF4G) with picornaviral proteases. Implications for cap-dependent and cap-independent translational initiation.

Cap-dependent binding of mRNA to the 40 S ribosomal subunit during translational initiation requires the association of eukaryotic initiation factor 4G (eIF4G; formerly eIF-4 gamma and p220) with other initiation factors, notably eIF4E, eIF4A, and eIF3. Infection of cells by picornaviruses results in proteolytic cleavage of eIF4G and generation of a cap-independent translational state. Rhinovirus 2A protease and foot-and-mouth-disease virus L protease were used to analyze the association of eIF4G with eIF4A, eIF4E, and eIF3. Both proteases bisect eIF4G into N- and C-terminal fragments termed cpN and cpC. cpN was shown to contain the eIF4E-binding site, as judged by retention on m7GTP-Sepharose, whereas cpC was bound to eIF3 and eIF4A, based on ultracentrifugal co-sedimentation. Further proteolysis of cpN by L protease produced an 18-kDa polypeptide termed cpN2 which retained eIF4E binding activity and corresponded to amino acid residues 319-479 of rabbit eIF4G. Further proteolysis of cpC yielded several smaller fragments. cpC2 (approximately 887-1402) contained the eIF4A binding site, whereas cpC3 (approximately 480-886) contained the eIF3 binding site. These results suggest that cleavage by picornaviral proteases at residues 479-486 separates eIF4G into two domains, one required for recruiting capped mRNAs and one for attaching mRNA to the ribosome and directing helicase activity. Only the latter would appear to be necessary for internal initiation of picornaviral RNAs.

Foot-and-mouth disease virus leader proteinase: purification of the Lb form and determination of its cleavage site on eIF-4 gamma.

Many picornaviruses cause a dramatic decrease in the translation of cellular mRNAs in the infected cell, without affecting the translation of their own RNA. Specific proteolysis of protein synthesis initiation factor eIF-4 gamma occurs during infection with rhinoviruses, enteroviruses, and aphthoviruses, apparently leading to an inability of the ribosomes to bind capped mRNAs. Cleavage of eIF-4 gamma in human rhinoviruses and enteroviruses is carried out by the viral 2A proteinase; in aphthoviruses (i.e., foot-and-mouth disease viruses), the leader proteinase is responsible for this reaction. We describe here the purification to homogeneity of the Lb form of the leader proteinase expressed in Escherichia coli. The primary cleavage products of eIF-4 gamma obtained in vitro with purified leader or 2A proteinase are electrophoretically indistinguishable from those found during infection in vivo. However, additional proteolysis products of eIF-4 gamma are observed with the leader proteinase and the human rhinovirus type 2 2A proteinase in vitro. The cleavage site of the leader proteinase in eIF-4 gamma from rabbit reticulocyte was determined by sequencing the purified C-terminal cleavage product by automated Edman degradation. The cleavage site is between Gly-479 and Arg-480 and thus differs from that of rhinovirus and enterovirus 2A proteinases, which cleave between Arg-486 and Gly-487.

Factor IXa protects factor VIIIa from activated protein C. Factor IXa inhibits activated protein C-catalyzed cleavage of factor VIIIa at Arg562.

Factor VIIIa is inactivated by both factor IXa and activated protein C. The latter protease rapidly attacked a site at Arg562 (A2 subunit), whereas both proteases slowly cleaved factor VIIIa at Arg336 (A1 subunit). Cofactor inactivation catalyzed by activated protein C was 8-fold faster than that catalyzed by factor IXa. Simultaneous reaction of factor VIIIa with the two enzymes resulted in a rate of inactivation intermediate to that observed for the individual proteases. Under these conditions, the activated protein C-catalyzed cleavage at Arg562 was inhibited such that cofactor inactivation resulted primarily from cleavage at Arg336. Substitution of factor IXa modified in its active site with 6-(dimethylamino)-2-naphthalenesulfonyl-glutamylglycylarginyl++ + chloromethyl ketone (DEGR-IXa) for the native enzyme yielded a similar rate of activated protein C-catalyzed cleavage at the A1 site, whereas cleavage at the A2 site was virtually eliminated. However, the inclusion of protein S resulted in a marked increase in cleavage at the A2 site that correlated with an increased rate of cofactor inactivation. Active site-modified activated protein C inhibited the factor IXa-dependent enhancement of factor VIIIa reconstitution from isolated subunits. In addition, the factor VIIIa-dependent fluorescence enhancement of DEGR-activated protein C was inhibited by EGR-IXa. These results indicate that factor IXa can reduce the rate of activated protein C-catalyzed cofactor inactivation by selectively blocking cleavage at the A2 domainal site, an effect reversed by protein S. One mechanism consistent with the reciprocal inhibitory effects of the proteases is that activated protein C and factor IXa occupy overlapping sites on the cofactor. Thus, factor IXa may protect factor VIIIa by preventing activated protein C binding.

Mapping the cleavage site in protein synthesis initiation factor eIF-4 gamma of the 2A proteases from human Coxsackievirus and rhinovirus.

The rate-limiting step of eukaryotic protein synthesis is the binding of mRNA to the 40 S ribosomal subunit, a step which is catalyzed by initiation factors of the eIF-4 (eukaryotic initiation factor 4) group: eIF-4A, eIF-4B, eIF-4E, and eIF-4 gamma. Infection of cells with picornaviruses of the rhino- and enterovirus groups causes a shut-off in translation of cellular mRNAs but permits viral RNA translation to proceed. This change in translational specificity is thought to be mediated by proteolytic cleavage of eIF-4 gamma, which is catalyzed, directly or indirectly, by the picornaviral 2A protease. In this report we have used highly purified recombinant 2A protease from either human Coxsackievirus serotype B4 or rhinovirus serotype 2 to cleave eIF-4 gamma in vitro in the eIF-4 complex purified from rabbit reticulocytes. Neither the rate of cleavage nor fragment sizes were affected by addition of eIF-3. The NH2- and COOH-terminal fragments of eIF-4 gamma were separated by reverse phase HPLC and identified with specific antibodies, and the NH2-terminal sequence of the COOH-terminal fragment was determined by automated Edman degradation. The cleavage site for both proteases is 479GRPALSSR decreases GPPRGGPG494 in rabbit eIF-4 gamma, corresponding to 478GRTTLSTR decreases GPPRGGPG493 in human eIF-4 gamma.

Proteolytic interactions of factor IXa with human factor VIII and factor VIIIa.

Factor IXa was shown to inactivate both factor VIII and factor VIIIa in a phospholipid-dependent reaction that could be blocked by an antifactor IX antibody. Factor IXa-catalyzed inactivation correlated with proteolytic cleavages within the A1 subunit of factor VIIIa and within the heavy chain (contiguous A1-A2-B domains) of factor VIII. Furthermore, a relatively slow conversion of factor VIII light chain to a 68-Kd fragment was observed after prolonged incubation. Sites of cleavage were identified within the A1 domain at Arg336-Met337 and within the factor VIII light chain at Arg1719-Asn1720. Factor IXa failed to cleave isolated factor VIII heavy chains, yet cleaved isolated factor VIII light chain. In addition, the purified A1/A3-C1-C2 dimer derived from factor VIIIa was a substrate for factor IXa; however, cleavage of the A1 subunit occurred at less than 30% the rate of cleavage of A1 in trimeric factor VIIIa. These data suggest that factor VIII light chain contributes to the binding site for factor IXa and also support a role for a heavy chain determinant located within the A2 subunit in the association of factor VIIIa with factor IXa. Furthermore, the capacity of factor IXa to proteolytically inactivate its cofactor, factor VIIIa, suggests a mode of regulation within the intrinsic tenase complex.

Factor IXa enhances reconstitution of factor VIIIa from isolated A2 subunit and A1/A3-C1-C2 dimer.

Heterotrimeric factor VIIIa was reconstituted from isolated A2 subunit and A1/A3-C1-C2 dimer of thrombin-activated human factor VIII in a reaction that was sensitive to pH. Maximal levels of reconstituted factor VIIIa at pH 6.0 were as much as 20-fold greater than were values observed at pH 7.5. The presence of factor IXa and phospholipid resulted in a marked increase in factor VIIIa reconstituted at physiologic pH. However, the resultant factor VIIIa was unstable due to slow proteolysis of the A1 subunit. Factor IXa modified by the active site-specific reagent dansyl-glutamyl-glycyl-arginyl-chloromethyl ketone (DEGR-IXa) increased the level of factor VIIIa reconstituted from subunits to a similar extent as was observed for unmodified factor IXa and yielded stable factor VIIIa. This enhancement was saturated above a 1:1 molar ratio of DEGR-IXa to factor VIIIa subunits and could be blocked by an anti-factor IX antibody, suggesting that the DEGR-IXa-dependent increase in factor VIIIa reconstitution correlated with assembly of the factor X-ase complex. At a saturating amount of DEGR-IXa, the level of factor VIIIa reconstitution at pH 7.5 approached values obtained at pH 6.0. Fluorescence polarization measurements indicated that factor VIIIa altered binding of DEGR-IXa to phospholipid. However, neither the A2 subunit nor the A1/A3-C1-C2 dimer alone produced this effect. This result suggested that both A2 and A1/A3-C1-C2 were necessary for association of the cofactor with factor IXa. These results suggest a model in which assembly of the intrinsic factor X-ase complex stabilizes factor VIIIa through inhibition of subunit dissociation.

Heat shock impairs the interaction of cap-binding protein complex with 5' mRNA cap.

Cell-free protein synthesizing systems prepared from heat-shocked Ehrlich cells retain the inhibition of translation that is seen at the cellular level. Recently, we showed that a highly purified cap-binding protein complex composed of the p220 and p28 subunits of eukaryotic initiation factor 4F, in a 1:1 molar ratio, restores protein synthesis in these cell-free translation systems (Lamphear, B.J., and Panniers, R. (1990) J. Biol. Chem. 265, 5333-5336). Here we have estimated the amount of cap-binding complex in cell extracts that can restore protein synthesis in heat-shocked cells. We find reduced restoring activity in heat-shocked cell extracts. Further, less cap-binding complex can be purified by 7-methyl-guanosine triphosphate Sepharose affinity chromatography from heat-shocked cell extracts, and we conclude that heat shock impairs the binding of complex to 5' mRNA cap. We have ruled out proteolysis and competitive inhibitors as mediators of this impairment. However we cannot distinguish between two possible explanations: (i) reduced association of p220 with p28 or (ii) a non-competitive inhibitor blocks complex binding to cap. We have also examined the affect of heat shock on the phosphorylation state of two forms of p28, p220.p28 complex and p28 free of p220. Both forms have reduced levels of phosphorylation during heat shock. The significance of these changes is discussed.

Cap binding protein complex that restores protein synthesis in heat-shocked Ehrlich cell lysates contains highly phosphorylated eIF-4E.

Cell-free protein-synthesizing systems derived from Ehrlich ascites tumor cells that have been exposed to elevated temperatures retain the inhibition of translation that is seen at the cellular level. A multisubunit cap binding protein complex able to restore protein synthesis in these cell free systems was purified from Ehrlich ascites tumor cells via affinity chromatography using m7GTP-Sepharose and fast protein liquid chromatography on Mono Q. The purified complex contains an Mr 220,000 polypeptide (p220) and an Mr 28,000 polypeptide (p28), both of which are components of eukaryotic initiation factor 4F (eIF-4F). p28 is identical to eIF-4E. Restoring activity was relatively free of the Mr 46,000 polypeptide (p46) that is the third component of eIF-4F and does not appear to be dependent on its presence. p28 associated in a complex with p220 is 85% phosphorylated; however, the majority of p28 is not associated with p220, and this free form is only about 50% phosphorylated. The correlation between association of p28 with p220 and high levels of p28 phosphorylation suggests a possible role for phosphorylation in association of p220 with p28.