Alkaloid homoharringtonine inhibits polypeptide chain elongation on human ribosomes on the step of peptide bond formation

The aim of the present study was to investigate homoharringtonine alkaloid effect on: (i) the nonenzymatic and eEF-1-dependent Phe-tRNAPhe binding to poly(U)-programmed human placenta 80 S ribosomes; (ii) diphenylalanine synthesis accompanying nonenzymatic Phe-tRNAPhe binding; and (iii) acetylphenylalanyl-puromycin formation. Neither nonenzymatic nor eEF-1-dependent Phe-tRNAPhe binding were noticeably affected by the alkaloid, whereas diphenylalanine synthesis and puromycin reaction were strongly inhibited by homoharringtonine. It has been proposed that the site of homoharringtonine binding on 80 S ribosomes should overlap or coincide with the acceptor site of the ribosome.     

Isolation of ribosomal subparticles from human placenta containing intact rRNA and determination of the functional activity of the 80S ribosome

The method for isolation of human placenta ribosomal subunits containing intact rRNA has been determined. The method uses fresh unfrozen placenta. Activity of 80S ribosomes obtained via reassociation of 40S and 60S subunits in non-enzymatic poly(U)-mediated Phe-tRNAPhe binding, was near 75% (maximal [14C]Phe-tRNA(Phe) binding was 1.5 mol Phe-tRNA(Phe) per mol of 80S ribosomes). Activity of 80S ribosomes with damaged rRNA isolated from frozen placenta was 2 times lower (the maximum level of poly(U)-dependent Phe-tRNA(Phe) binding was 0.7 mol per mol of ribosomes). The activity 80S ribosomes in poly(U)-mediated synthesis of polyphenylalanine was determined by using fractionated ("ribosomeless") protein synthesising system from rabbit reticulocytes. In this system up to the 50 mol of Phe residues per mol of 80S ribosomes are incorporated in acid insoluble fraction in 1 hour, at 37 degrees C. The obtained level of [14C]phenylalanine incorporation is three times as much as the amount of Phe residues observed for the ribosomal subunits, isolated from frozen placenta.     

Interaction of human and Escherichia coli tRNA(Phe) with human 80S ribosomes in the presence of oligo- and polyuridylate templates.

Human placenta and Escherichia coli Phe-tRNA(Phe) and N-AcPhe-tRNA(Phe) binding to human placenta 80S ribosomes was studied at 13 mM Mg2+ and 20 degrees C in the presence of poly(U), (pU)6 or without a template. Binding properties of both tRNA species were studied. Poly(U)-programmed 80S ribosomes were able to bind charged tRNA at A and P sites simultaneously under saturating conditions resulting in effective dipeptide formation in the case of Phe-tRNA(Phe). Affinities of both forms of tRNA(Phe) to the P site were similar (about 1 x 10(7) M-1) and exceeded those to the A site. Affinity of the deacylated tRNA(Phe) to the P site was much higher (association constant > 10(10) M-1). Binding at the E site (introduced into the 80S ribosome by its 60S subunit) was specific for deacylated tRNA(Phe). The association constant of this tRNA to the E site when A and P sites were preoccupied with N-AcPhe-tRNA(Phe) was estimated as (1.7 +/- 0.1) x 10(6) M-1. In the presence of (pU)6, charged tRNA(Phe) bound loosely at the A and P sites, and the transpeptidation level exceeded the binding level due to the exchange with free tRNA from solution. Affinities of aminoacyl-tRNA to the A and P sites in the presence of (pU)6 seem to be the same and much lower than those in the case of poly(U). Without a messenger, binding of the charged tRNA(Phe) to 80S ribosomes was undetectable, although an effective transpeptidation was observed suggesting a very labile binding of the tRNA simultaneously at the A and P sites.     

Inhibition of translation in eukaryotic systems by harringtonine.

The Cephalotaxus alkaloids harringtonine, homoharringtonine and isoharringtonine inhibit protein synthesis in eukaryotic cells. The alkaloids do not inhibit, in model systems, any of the steps of the initiation process but block poly(U)-directed polyphenylalanine synthesis as well as peptide bond formation in the fragment reaction assay, the sparsomycin-induced binding of (C)U-A-C-C-A-[3H]Leu-Ac, and the enzymic and the non-enzymic binding of Phe-tRNA to ribosomes. These results suggest that the Cephalotaxus alkaloids inhibit the elongation phase of translation by preventing substrate binding to the acceptor site on the 60-S ribosome subunit and therefore block aminoacyl-tRNA binding and peptide bond formation. However, the Cephalotaxus alkaloids do not inhibit polypeptide synthesis and peptidyl[3H]puromycin formation in polysomes. Furthermore, these alkaloids strongly inhibit [14C]trichlodermin binding to free ribosomes but hardly affect the interaction of the antibiotic with yeast polysomot interact with polysomes and therefore only inhibit cycles of elongation. This explains the polysome run off that has been observed by some workers in the presence of harringtonine.     

Isolation of ribosomal subunits containing intact rRNA from human placenta: estimation of functional activity of 80S ribosomes.

We have elaborated a method for the isolation of ribosomal subunits from fresh unfrozen human placenta containing intact rRNA and a complete set of ribosomal proteins. Activity of 80S ribosomes obtained by reassociation of 40S and 60S subunits in nonenzymatic poly(U)-dependent binding of Phe-tRNA(Phe) was equal to 80% (above 1.5 mol [14C]Phe-tRNA(Phe) is coupled to 1 mol of ribosomes). The activity of 80S ribosomes in poly(U)-directed synthesis of polyphenylalanine was tested in a polysome-free protein-synthesizing system from rabbit reticulocytes. About 100 mol of phenylalanine residue was polymerized by a mole of ribosomes at a rate of 0.83 residues per minute in this system (2 h, 37 degrees C).     

Interaction of N-acetyl-phenylalanyl-tRNAPhe with 70S ribosomes of Escherichia coli.

The interaction of N--Acetyl--Phe--tRNA Phe with 70 S ribosomes is a reversible process in the absence as well as in the presence of messenger. The equilibrium binding constants of these interactions were measured at different magnesium concentrations and temperatures and thermodynamical quantities computed. The enthalpy of the formation of complexes with the P site of ribosomes is larger by 6,000 cal/mol in the presence of poly (U) than in the presence of poly (C) or in total absence of messenger. Free energy differences are rather small, the association constants differ less than one order of magnitude. The association constant of N--Acetyl--Phe--tRNA Phe with the A site of ribosomes is 30--50 times lower than with the P site even in the presence of poly (U).     

Partial release of AcPhe-Phe-tRNA from ribosomes during poly(U)-dependent poly(Phe) synthesis and the effects of chloramphenicol

Poly(U)-programmed 70S ribosomes can be shown to be 80% to 100% active in binding the peptidyl-tRNA analogue AcPhe-tRNA to their A or P sites, respectively. Despite this fact, only a fraction of such ribosomes primed with AcPhe-tRNA participate in poly(U)-directed poly(Phe) synthesis (up to 65%) at 14 mM Mg2+ and 160 mM NH4+. Here it is demonstrated that the apparently 'inactive' ribosomes (greater than or equal to 35%) are able to participate in peptide-bond formation, but lose their nascent peptidyl-tRNA at the stage of Ac(Phe)n-tRNA, with n greater than or equal to 2. The relative loss of early peptidyl-tRNAs is largely independent of the degree of initial saturation with AcPhe-tRNA and is observed in a poly(A) system as well. This observation resolves a current controversy concerning the active fraction of ribosomes. The loss of Ac(Phe)n-tRNA is reduced but still significant if more physiological conditions for Ac(Phe)n synthesis are applied (3 mM Mg2+, 150 mM NH4+, 2 mM spermidine, 0.05 mM spermine). Chloramphenicol (0.1 mM) blocks the puromycin reaction with AcPhe-tRNA as expected but, surprisingly, does not affect the puromycin reaction with Ac(Phe)2-tRNA nor peptide bond formation between AcPhe-tRNA and Phe-tRNA. The drug facilitates the release of Ac(Phe)2-4-tRNA from ribosomes at 14 mM Mg2+ while it hardly affects the overall synthesis of poly(Phe) or poly(Lys).     

The effect of mutations in ribosomal proteins S4, S12 and L7/L12 on EF-Tu-dependent expenditure of GTP in the process of codon-specific elongation and misreading of poly(U)

The effect of mutations in ribosomal proteins S4 (rpsD12), S12 (rpsL282) and L7/L12 (rplL265) of Escherichia coli K12 on the EF-Tu-dependent expenditure of GTP during codon-specific elongation (poly(Phe) synthesis on poly(U] and misreading (poly(Leu) synthesis on poly(U], was studied. Under the conditions used the mutations in proteins S4 and L7/L12 did not practically affect the EF-Tu-dependent expenditure of GTR during the poly(Phe) synthesis on poly(U): the GTP/Phe ratio was about 1, as in the case of the wild strain. Under the same conditions, the ribosomes with a mutant S12 protein tended to discard some amount of Phe-tRNA, as a result of which the GTP/Phe ratio increased to about 3. The marked inhibition of misreading by ribosomes with a mutant S12 protein was accompanied by a significant increase of GTP expenditure at the stage of EF-Tu-dependent non-cognate aminoacyl-tRNA binding. In mutant S 12 proteins the GTP/Leu ratio was about 30-40, whereas in the wild type it was about 12. In contrast, stimulation of misreading by ribosomes with mutant S4 and L7/L12 proteins was accompanied by a decrease of the EF-Tu-dependent expenditure of GTP by 2-3 GTP molecules per one Leu residue included into the peptide.     

Apparent association constants of tRNAs for the ribosomal A, P, and E sites.

Association constants for tRNA binding to poly(U) programmed ribosomes were assessed under standardized conditions with a single preparation of ribosomes, tRNAs, and elongation factors, respectively, at 15 and 10 mM Mg2+. Association constants were determined by Scatchard plot analysis (the constants are given in units of [10(7)/M] measured at 15 mM Mg2+): the ternary complex Phe-tRNA.elongation factor EF-Tu.GTP (12 +/- 3), Phe-tRNA (1 +/- 0.4), AcPhe-tRNA (0.7 +/- 0.3), and deacylated tRNA(Phe) (0.4 +/- 0.15) bind with decreasing affinity to the A site of poly(U)-programmed ribosomes. tRNA(Phe) (7.2 +/- 0.8) binds to the P site with higher affinity than AcPhe-tRNA (3.7 +/- 1.3). The affinity of the E site for deacylated tRNA(Phe) (1 +/- 0.2) is about the same as that of the A site for AcPhe-tRNA (0.7 +/- 0.3). At lower Mg2+ concentrations the affinity of the E site ligand becomes stronger relative to the affinities of the A site ligands. Phe-tRNA and ternary complexes can occupy the A site at 0 degrees C in the presence of poly(U) even if the P site is free, whereas, as already known, deacylated tRNA or AcPhe-tRNA bind first to the P site of programmed ribosomes. Hill plot analyses of the binding data confirm an allosteric linkage between A and E sites in the sense of a negative cooperativity.     

Mechanism of codon-anticodon interaction in ribosomes. Direct functional evidence that isolated 30S subunits contain two codon-specific binding sites for transfer RNA.

30S subunits were isolated capable to bind simultaneously two molecules of Phe-tRNAPhe (or N-Acetyl-Phe-tRNAPhe), both poly(U) dependent. The site with higher affinity to tRNA was identified as P site. tRNA binding to this site was not inhibited by low concentrations of tetracycline (2 x 10(-5)M) and, on the other hand, N-Acetyl-Phe-tRNAPhe, initially prebound to the 30S.poly(U) complex in the presence of tetracycline, reacted with puromycin quantitatively after addition of 50S subunits. The site with lower affinity to tRNA revealed features of the A site: tetracycline fully inhibited the binding of both Phe-tRNAPhe and N-Acetyl-Phe-tRNAPhe. Binding of two molecules of Phe-tRNAPhe to the 30S.poly(U) complex followed by the addition of 50S subunits resulted in the formation of (Phe)2-tRNAPhe in 75-90% of the reassociated 70S ribosomes. These results prove that isolated 30S subunits contain two physically distinct centers for the binding of specific aminoacyl- (or peptidyl-) tRNA. Addition of 50S subunits results in the formation of whole 70S ribosomes with usual donor and acceptor sites.     

Interaction of puromycin with acceptor site of human placenta 80 S ribosomes

The complex N-AcPhe-tRNA(Phe).poly(U).80 S ribosome from human placenta was treated with puromycin taken in various concentrations. Based on the kinetic data of N-acetylphenylalanyl-puromycin formation, the association constant of puromycin with the acceptor site of the ribosome was estimated to be (3.96 +/- 0.84) x 10(4) M-1 at 37 degrees C.     

Segments of 18S rRNA, located in the area of the mRNA-binding center of ribosomes from human placenta

The affinity labelling of human placenta 80S ribosomes by 4-(N-2-chloroethyl-N-methylamino)benzyl-5'-phosphoramide of hexauridylate has been studied. This mRNA analogue has normal coding properties because its binding to placenta ribosomes significantly increases in the presence of the cognate tRNA(Phe). Incubation of the mRNA analogue in the complex with ribosomes and Phe-tRNAPhe) leads to its covalent attachment exclusively to the small subunit (mainly to 18S rRNA). The reaction site has been shown by hybridisation experiments to be located within positions 975-1055 of 18S rRNA. The identified fragment is located in a highly conserved part of the small subunit rRNA domain II.     

Effect of spermine on the efficiency and fidelity of the codon-specific binding of tRNA to the ribosomes

Binding of the yeast Tyr-tRNA and Phe-tRNA to the A site, and the binding of their acetyl derivatives to the P site of poly(U11,A)-programmed Escherichia coli ribosomes was studied. Spermine stimulated the rate of binding of both tRNAs at least threefold, enabling more than 90% final saturation of both ribosomal binding sites. The effect is observed when the tRNAs, but not ribosomes or poly(U11,A), are preincubated with polyamine. Regardless of the binding site, optimal saturation was reached at spermine/tRNA molar ratios of 3 for tRNA(Phe) and 5 for tRNA(Tyr). The same low spermine/tRNA ratios were previously reported to stabilize the conformation of these tRNAs in solution. On the other hand, the messenger-free, EF-Tu- and EF-G-dependent polymerization of lysine from E. coli Lys-tRNA is drastically reduced, while the poly(A)-directed polymerization is stimulated by spermine through a wide range of Mg2+ concentrations. Misreading of UUU codons as isoleucine, assayed by the A-site binding of E. coli Ile-tRNA, is also inhibited by spermine. All these results demonstrate that spermine increases the efficiency and accuracy of a series of macromolecular interactions leading to the correct incorporation of an amino acid into protein, at the same time preventing some unspecific or erroneous interactions. From the analogy with its known structural effects, it can be inferred that spermine does so by conferring on the tRNA a specific biologically functional conformation.     

Preparation of spin-labeled poly(U) and its activity in assays with eukaryotic ribosomes

ESR studies on the interaction of spin-labeled polynucleotides with ribosomes require a sufficient label-to-nucleotide ratio. Using three different spin labels (SL) we have elaborated a technique to label poly(U) up to a ratio of 1 SL per 30 uridine residues. This ratio is much higher than maximal values obtained by other authors. The SL-poly(U) was shown to have the same activity as unlabeled poly(U) to direct synthesis of poly(Phe). SL-poly(U) binds to rat liver ribosomes in the presence of Mg2+ as shown by ESR. Titration with EDTA leads to a release of SL-poly(U) from ribosomes.     

Characteristics of nonenzymatic binding of oligoribonucleotides-- analogs of mRNA and Phe-tRNA Phe with 80S ribosomes from human placenta

Binding of labelled oligouridylates--mRNA analogs--to human placenta 80S ribosomes in the presence of Phe-tRNAPhe has been studied. The single site for (pU)n (n = 6, 9, 13) binding on the ribosome was found; association constants for their tRNA-dependent binding were evaluated. In the presence of oligouridylates as templates [14C]Phe-tRNAPhe was found to be able to bind simultaneously at acceptor and donor ribosomal sites which resulted in diphenylalanine formation. The observed maximum Phe-tRNAPhe binding level was considerably lower than for the corresponding oligouridylate binding; the longer oligouridylate the higher Phe-tRNAPhe maximum binding level. To explain the results obtained we have proposed that (i) (Phe)2-tRNA produced from transpeptidation dissociates from the ribosomal A site to a significant extent and (ii) when oligouridylate length increases its interaction with 3'-side of mRNA binding center results in allosteric stabilization of the complex of peptidyl-tRNA with the ribosome at A site.     

On the accessibility and selection of the initiator site of mRNA in protein synthesis.

The specificity of the cell-free system of Escherichia coli for mRNA was examined, and the "accessibility" of some natural and synthetic RNAs to the ribosomes was determined by measurement of AcPhe-tRNA and fMet-tRNA binding, AcPhe-puromycin and fMet-puromycin formation, and polypeptide synthesis. The E. coli system effectively initiates the translation of various synthetic RNAs with AcPhe-tRNA or fMet-tRNA under conditions optimal for the translation of viral RNA. Poly(A,G,U) is accessible to the ribosomes according to all of the above criteria. Poly(A,C,G,U), 23 S rRNA, R17 RNA, and MS2 RNA, on the other hand, show limited accessibility when tested for initiator tRNA binding, or for AcPhe-puromycin and fMet-puromycin formation. MS2 and R17 RNA, but not poly(A,C,G,U) and 23 S rRNA, show accessibility when measured by polypeptide synthesis. The results suggest that, except at initiator sites of natural mRNA, an RNA containing about equal amounts of all four bases is inaccessible to E. coli ribosomes for polypeptide synthesis. Rate constants obtained for fMet-tRNA binding with MS2 RNA, poly(A,G,U), and poly(C,G,U) indicate that the ribosomes do not have any special affinity for the viral RNA. Thus, the selection of the initiator site in protein synthesis may be critically determined more by the accessibility of the initiator codon than by ribosomal recognition of the site.     

Two tRNA-binding sites in addition to A and P sites on eukaryotic ribosomes.

The interaction of tRNA with 80 S ribosomes from rabbit liver was studied using biochemical as well as fluorescence techniques. Besides the canonical A and P sites, two additional sites were found which specifically bind deacylated tRNA. One of the sites is analogous to the E site of prokaryotic ribosomes, in that binding of tRNA is labile, does not depend on codon-anticodon interaction, does not protect the anticodon loop from solvent access, and requires the presence of the 3'-terminal adenosine of the tRNA. In contrast, the stability of the tRNA complex with the second site (S site) is high. tRNA binding to the S site is also codon-independent; nevertheless, the anticodon loop is shielded from solvent access. Removal of the 3'-terminal adenosine decreases the affinity of tRNA(Phe) for the S site approximately 50-fold. tRNA(Phe) is retained at the S site during translocation and through poly(Phe) synthesis. Thus, the S site does not seem to be an intermediate site for the tRNA during the elongation cycle. Rather, the tRNA bound to the S site may allosterically modulate the function of the ribosome.     

Physical and coding properties of poly(5-methoxyuridylic) acid.

The synthesis of poly(mo5U) requires a high concentration (2.7 mg/ml) of polynucleotide phosphorylase as well as a long reaction time (48 h). The resulting polynucleotide has a chain length of approximately 100 nucleotides. It shows no indication of a stable secondary structure. When poly(mo5U) is mixed with poly(A), a triple-stranded complex poly(A) . 2poly(mo5U) is formed. This complex has a melting temperature of 68.5 +/- 0.5 degrees C at 150 mMNa+ and exhibits a hysteresis loop between melting and reformation of the complex having a delta Tm of 11.5 degrees C. Poly-5-methoxyuridylic acid stimulates the binding of Phe-tRNA to 70-S ribosomes but is inactive in directing poly(Phe) synthesis.     

Transit of tRNA through the Escherichia coli ribosome: cross-linking of the 3' end of tRNA to ribosomal proteins at the P and E sites

Photoreactive derivatives of yeast tRNA(Phe) containing 2-azidoadenosine at their 3' termini were used to trace the movement of tRNA across the 50S subunit during its transit from the P site to the E site of the 70S ribosome. When bound to the P site of poly(U)-programmed ribosomes, deacylated tRNA(Phe), Phe-tRNA(Phe) and N-acetyl-Phe-tRNA(Phe) probes labeled protein L27 and two main sites within domain V of the 23S RNA. In contrast, deacylated tRNA(Phe) bound to the E site in the presence of poly(U) labeled protein L33 and a single site within domain V of the 23S rRNA. In the absence of poly(U), the deacylated tRNA(Phe) probe also labeled protein L1. Cross-linking experiments with vacant 70S ribosomes revealed that deacylated tRNA enters the P site through the E site, progressively labeling proteins L1, L33 and, finally, L27. In the course of this process, tRNA passes through the intermediate P/E binding state. These findings suggest that the transit of tRNA from the P site to the E site involves the same interactions, but in reverse order. Moreover, our results indicate that the final release of deacylated tRNA from the ribosome is mediated by the F site, for which protein L1 serves as a marker. The results also show that the precise placement of the acceptor end of tRNA on the 50S subunit at the P and E sites is influenced in subtle ways both by the presence of aminoacyl or peptidyl moieties and, more surprisingly, by the environment of the anticodon on the 30S subunit.     

In vitro protein synthesis by the moderate halophile Vibrio costicola: site of action of Cl- ions.

In vitro protein synthesis in Vibrio costicola [poly(U)-directed incorporation of phenylalanine] was studied. The extent of protein synthesis was limited by the number of ribosomes present. Density gradient centrifugation experiments suggested that, after runoff of ribosomes from the artificial messenger, the 50S subunit was unable to attach to the 30S-messenger complex. As shown previously (M. Kamekura and D. J. Kushner, J. Bacteriol. 160:385-390, 1984), Cl- ions inhibited protein synthesis; indeed, the highest rate of synthesis took place in the lowest attainable Cl- concentration (37 mM). The inhibitory effects were partly reversed by glutamate and betaine, both of which are concentrated within cells of V. costicola. The strongest reversal was seen when both glutamate and betaine were present. Cl- ions can prevent binding of ribosomes to poly(U) and displace ribosomes already bound to this artificial messenger. The effects of Cl- ions on binding were also reversed by glutamate and betaine. Cl- ions did not affect accuracy of translation; they were shown previously (Kamekura and Kushner, J. Bacteriol. 160:385-390, 1984) not to affect phenylalanyl-tRNA synthetase. It was also found that washing ribosomes with inhibitory NaCl concentrations did not interfere with their ability to carry out protein synthesis later in optimal (low) salt concentrations. On the contrary, these ribosomes were more active than before they were washed. We conclude that the main site of action of Cl- in the system studied is on the binding of ribosomes to the mRNA.