The effect of Cephalotaxus group alkaloids on elongation of the polypeptide chain in human ribosomes

Effects of Cephalotaxus alkaloids (homoharringtonine and cephalotaxine) on the translation of endogenous mRNA in a cell-free system of rabbit reticulocyte lysate and on poly(U)-directed poly(Phe) synthesis on human placenta ribosomes was studied. The effect of the alkaloids on the activity of human placenta ribosomes in a template-dependent aminoacyl-tRNA binding, N-acetyl-phenylalanyl-puromycin and diphenylalanine formation was also studied. Homoharringtonine was shown to have little effect of codon-dependent Phe-tRNA(Phe) binding but the alkaloid strongly inhibited (Phe)2 formation as well as N-Ac-Phe-puromycin synthesis from the complex N-Ac-Phe-tRNA(Phe).poly(U).80S ribosomes. It was concluded that the site of homoharringtonine binding overlaps or coincides with the acceptor site of the ribosomal peptidyltransferase center. The association constant of homoharringtonine to the ribosomes was estimated to be (4.8 +/- 1.0) x 10(7) M-1. Cephalotaxine had no effect on the elongation steps.     

Kinetics of inhibition of peptide bond formation on bacterial ribosomes.

A cell-free system derived from Escherichia coli has been used in order to study the kinetics of inhibition of peptide bond formation with the aid of the puromycin reaction in solution. A similar study has been carried out earlier on a solid support matrix with the same inhibitors. We find that the overall pattern of the kinetics of inhibition is the same in the two systems. At low concentrations of inhibitor there is a competitive phase of inhibition, whereas at higher concentrations of inhibitor the type of inhibition becomes mixed noncompetitive. The values of Ki of the competitive phase in the system in solution are: 5.8 microM (amicetin), 0.2 microM (blasticidin S), 0.5 microM (chloramphenicol), and 0.5 microM (tevenel). The inhibitors amicetin, blasticidin S, and tevenel interact with the ribosome in a reaction which is slower than that of the substrate puromycin, showing clear-cut characteristics of slow-onset inhibition in both systems. Chloramphenicol, on the other hand does not easily show such a delay in solution. It interacts with the ribosome relatively faster than the other three antibiotics. Despite this, chloramphenicol too shows characteristics of time-dependent inhibition.     

Effect of glycosaminoglycans on peptide bond formation in bacterial ribosomes.

1. A cell-free system derived from E. coli has been used in this study. The process of peptide bond formation was assessed with the aid of the puromycin reaction, which is catalyzed by peptidyltransferase. 2. This reaction is inhibited by heparin, in contrast, this reaction is activated by hyaluronic acid. 3. The presence of heparin decreases the percentage of formed initiation complex (complex C), but hyaluronic acid, chondroitin sulphate and keratan sulphate have no effect on the formation of complex C. 4. From other types of glycosaminoglycans, only hyaluronic acid increases the stability of active complex C.     

Effect of alcohols on polypeptide chain elongation and aminoacyl-tRNA formation.

The effect of alcohols (methanol, ethanol, and propanol) on polypeptide chain elongation was studied. In the E. coli and rat liver cell-free systems, the optimal concentration of Mg2+ decreased with increase of ethanol concentration, although the maximum polyphenylalanine synthesis decreased. Methanol had almost the same effect as ethanol. Propanol decreased the optimal magnesium concentration, but polyphenylalanine synthetic activity was markedly decreased. The shift of optimal Mg2+ concentration by ethanol was also observed in polylysine and polysome-dependent polypeptide syntheses. Even in the presence of spermidine, ethanol caused the shift of optimal Mg2+ concentration. Ribosome-bound Mg2+ was decreased by the addition of ethanol. A study of the effect of alcohols on aminoacyl-tRNA formation with ten amino acids in the absence of added Mg2+ showed that the formation of arginyl-, leucyl-, and valyl-tRNA was stimulated by the alcohols. Valyl-tRNA formation in the presence of alcohols was completely inhibited by EDTA, while that in the presence of Mg2+ was inhibited slightly by EDTA. No PP1-ATP exchange was observed when alcohol was used as the only stimulant of valyl-tRNA formation.     

Movement of tRNA but not the nascent peptide during peptide bond formation on ribosomes.

The results from experiments involving nonradiative energy transfer indicate that a fluorescent probe on the 5'-end of tRNA(Phe) moves more than 20 A towards probes on ribosomal protein L1 as a peptide bond is formed during the peptidyl transferase reaction on Escherichia coli ribosomes. The peptide itself moves no more than a few angstroms during peptide bond formation, as judged by the movement of fluorescent probes attached to the phenylalanine amino group of phenylalanyl-tRNA. Other results demonstrate that an analogue of peptidyl-tRNA, deacylated tRNA, and puromycin can be bound simultaneously to the same ribosome, indicating that there are three physically distinct sites to which tRNA is bound during the reaction steps by which peptides are elongated. The results appear to be consistent with the displacement model of peptide elongation.     

Mammalian mitochondrial ribosomes. Studies on the exchangeability of polypeptide chain elongation factors from bacterial and mitochondrial systems

Mammalian mitochondrial ribosomes from rat liver synthesised poly(phenylalanine) from [14C]-Phe-tRNA in the presence of a homologous 10(5) X gav supernatent fraction. The activity depended on the addition of synthetic template and was resistant to cycloheximide. The polyanion spermidine had a stimulatory effect on peptide synthesis in vitro. In contrast to Escherichia coli ribosomes, which also functioned with heterologous supernatant fractions, 55-S mitochondrial ribosomes were inactive when supplemented with heterologous supernatant fractions from E. coli or with purified bacterial elongation factors. EF-T slightly stimulated polyphenylalanine synthesis when added in combination with mitochondrial supernatant fractions. Two-dimensional electrophoretic analysis of the protein content of both supernatant fractions revealed considerable differences in the distribution of the species-specific proteins according to their isoelectric points. The mitochondrial supernatant proteins were in general more basic, and the few acidic proteins did not co-migrate with EF-Tu or EF-G from E. coli.     

Age-related changes in the rates of polypeptide chain elongation

The time of an average polypeptide chain synthesis, ts, in the liver and brain cortex of rats of various age--from the 17th day of prenatal life up to the 24th month of the postnatal period--was estimated. At the end of the prenatal period the value of t is much higher than in postnatal life. In newborns, the t value is minimal, showing a gradual increase during the postnatal development. Determination of an average molecular mass of newly synthesized polypeptides demonstrated that the increase of t in postnatal life is due to the decrease of the rate of polypeptide chain elongation.     

Some properties and the possible role of intrinsic ATPase of rat liver 80S ribosomes in peptide bond elongation

The properties and role in peptide elongation of ATPase intrinsic to rat liver ribosomes were investigated. (i) Rat liver 80S ribosomes showed high ATPase and GTPase activities, whereas the GTPase activity of EF-1alpha and EF-2 was very low. mRNA, aminoacyl-tRNA, and elongation factors alone enhanced ribosomal ATPase activity and in combination stimulated it additively or synergistically. The results suggest that these translational components induce positive conformational changes of 80S ribosomes by binding to different regions of ribosomes. Translation inhibitors, tetracyclin and fusidic acid, inhibited ribosomal ATPase with or without elongational components. (ii) Two ATPase inhibitors, AMP-P(NH)P and vanadate, did not inhibit GTPase activities of EF-1alpha and EF-2 assayed as uncoupled GTPase, but they did inhibit poly(U)-dependent polyphe synthesis of 80S ribosomes. (iii) Effects of AMP-P(NH)P and ATP on poly(U)-dependent polyphe synthesis at various concentrations of GTP were examined. ATP enhanced the activity of polyphe synthesis even at high concentrations of GTP, suggesting a specific role of ATP. At low concentrations of GTP, the extent of inhibition by AMP-P(NH)P was very low, probably owing to the prevention of the reduction of the GTP concentration. (iv) Vanadate inhibited the translocation reaction by high KCl-washed polysomes. These findings together indicate that ribosomal ATPase participates in peptide translation by inducing positive conformational changes of mammalian ribosomes, in addition to its role of chasing tRNA from the E site.     

Enzymatic binding of aminoacyl-tRNA and peptide chain elongation by ribosomes and ribosome subunits in pea

In vitro aminoacyl transfer from aminoacyl-tRNA to elongating peptide chains and binding of aminoacyl-tRNA to ribosomes were studied with n     

Mechanism of peptide bond formation on the ribosome--controversions

During past five years there have been published many experimental data concerning structure and function of the ribosome. With the presentation of atomic structures we obtained a new data about composition of peptidyl transferase center. It is now obvious that PTC is composed entirely of rRNA. It is also known that the proper substrate alignment is the major factor for ribosome's catalytic activity. However, more detailed mechanism of peptide bond formation on the ribosome still remains unclear. Several issues remain unsolved. For example, are there any chemical components coming from ribosome itself, that enhance the rate of the reaction? Do intact ribosomes perform peptidyltransfer in the same way as the isolated ribosomal subunits that have been the source of most of the data? In this article we present different opinions and controversions around peptide bond formation on the ribosome.     

Mechanism of peptide bond formation on the ribosome

Peptide bond formation is the fundamental reaction of ribosomal protein synthesis. The ribosome's active site--the peptidyl transferase center--is composed of rRNA, and thus the ribosome is the largest known RNA catalyst. The ribosome accelerates peptide bond formation by 10(7)-fold relative to the uncatalyzed reaction. Recent progress of structural, biochemical and computational approaches has provided a fairly detailed picture of the catalytic mechanisms employed by the ribosome. Energetically, catalysis is entirely entropic, indicating an important role of solvent reorganization, substrate positioning, and/or orientation of the reacting groups within the active site. The ribosome provides a pre-organized network of electrostatic interactions that stabilize the transition state and facilitate proton shuttling involving ribose hydroxyl groups of tRNA. The catalytic mechanism employed by the ribosome suggests how ancient RNA-world enzymes may have functioned.     

Glycopeptides from brain inhibit rates of polypeptide chain elongation

In previous reports, we have identified cell-surface glycopeptides from mouse cerebrum (BCSG) that inhibited protein synthesis and mitosis in several cell types. When baby hamster kidney (BHK)-21 cells were infected with vesicular stomatitis virus (a negative strand RNA virus), BCSG extensively inhibited viral protein synthesis. This inhibition was effective against both protein and glycoprotein synthesis and was independent of amino acid uptake by infected cells, synthesis of viral RNA, and degradation of viral proteins. Analysis of polyribosome profiles in uninfected BHK-21 cells indicated that the degree of cellular protein synthesis inhibition could not be attributed to activation of RNase or solely to a disruption of chain initiation. When added directly to a cell-free protein-synthesizing system derived from BHK-21 cells, BCSG was ineffective, but if the inhibitory material was first allowed to react with cells, cell-free protein synthesis was substantially reduced. When BCSG were reacted with cells for 5 min at 0 degrees C, the cells tested, BHK-21 (a BCSG-sensitive line) and murine fibrosarcoma 2237 (a BCSG-insensitive line), both effectively adsorbed the inhibitor from the medium.     

Conformational changes of aminoacyl-tRNA and uncharged tRNA upon complex formation with polypeptide chain elongation factor Tu

The conformation change of Thermus thermophilus tRNA(1Ile) upon complex formation with T. thermophilus elongation factor Tu (EF-Tu) was studied by analysis of the circular dichroism (CD) bands at 315 nm (due to the 2-thioribothymidine residue in the T-loop) and at 295 nm (due to the core structure of tRNA). Formation of the ternary complex of isoleucyl-tRNA(1Ile) and EF-Tu.GTP increased the intensities of these CD bands, indicating stabilization of the association between the T-loop and the D-loop and also a significant conformation change of the core region. Upon complex formation of EF-Tu.GTP and uncharged tRNA, however, the conformation of the core region is not changed, while the association of the two loops is still stabilized. On the other hand, the binding with EF-Tu.GDP does not appreciably affect the conformation of isoleucyl-tRNA or uncharged tRNA. These indicate the importance of the gamma-phosphate group of GTP and the aminoacyl group in the formation of the active complex of aminoacyl-tRNA and EF-Tu.GTP.     

Optimization of enzyme-mediated peptide bond formation

Enzyme-catalyzed peptide bond formation requires thorough examination and optimization of each coupling step. In order to identify factors influencing the selectivity between aminolysis and hydrolysis, a systematic study was carried out for the kinetically controlled peptide synthesis. The reaction temperature, the type of C-terminal protecting group, and different organic cosolvents showed little influence on the selectivity. The enzyme, excess nucleophile, pH, N-terminal protecting group, and ionic strength of the solution were identified as major factors controlling the selectivity and, therefore, the yield of the dipeptide synthesis. Under optimized conditions, the selectivity of the chymotrypsin-catalyzed synthesis of PheSer could be increased from 35 to 100%.