Comparative analysis of the action of cytokinin and light on the formation of ribulosebisphosphate carboxylase and plastid biogenesis

The role of cytokinin in plastid biogenesis was investigated in etiolated rye leaves (Secale cereale L.) and compared with the effect of white light. Cytokinin deficiency of the leaves was induced by early excision of the seedling roots and reversed by the application of kinetin. The cytokinin supply had a much greater influence on plastid biogenesis than on leaf growth in general. The activities of several chloroplastic enzymes were increased 200%–400% after kinetin treatment of cytokinin-depleted leaves. The activity of ribulose-1,5-bisphosphate carboxylase (EC 4.1.1.39) and the amount of fraction-I protein even showed a sevenfold increase. In cytokinin-depleted leaves the development of ribulose-1,5-bisphosphate carboxylase and NADP-glyceraldehydephosphate dehydrogenase was specifically, and markedly inhibited by actinomycin D. The inhibition was partially or even completely overcome after treatment with kinetin. However, under all conditions, RNA synthesis of the leaves, was only partially inhibited by actinomycin D. According to immunologic studies, all dark-grown leaves, in addition to the complete enzyme, contained an excess of free small subunit of ribulose-1,5-bisphosphate carboxylase that was absent in mature light-grown leaves. The most striking accumulation of free small subunit, protein occurred in cytokinin-depleted dark-grown leaves, indicating a deficiency of the plastidic synthesis of the large subunit. The capacity as well as the activity of plastidic protein synthesis was preferentially increased by cytokinin and light. Cytokinin increased, the amount of plastidic ribosomes per leaf and relative to the amount of cytoplasmic ribosomes. While the percentage of cytoplasmic ribosomes bound as polyribosomes was little affected by the cytokinin supply, the proportion of plastidic polyribosomes was increased from 11% to 18% after kinetin treatment of cytokinin-depleted leaves. In the light, the proportion of plastidic polyribosomes reached 39% of the total plastidic ribosomes.Abbreviations RuBP carboxylase ribulose-1,5-bisphosphate carboxylase - NADP-GAP dehydrogenase NADP-dependent glyceraldehyde-3-phosphate dehydrogenase     

Binding and translation of turnip-yellow-mosaic-virus ribonucleic acid by skeletal-muscle ribosomes from normal and diabetic rats

Ribosomes from skeletal muscle of diabetic rats were less active than normal ribosomes in protein synthesis directed by turnip-yellow-mosaic-virus RNA. The proportion of ribosomes from muscle of diabetic rats capable of binding turnip-yellow-mosaic-virus RNA was greater than normal, but there was no difference in the equilibrium constants for the binding reaction. The turnip-yellow-mosaic-virus RNA was bound preferentially to the small (40S) ribosomal subunit, whereas the decrease due to diabetes in its translation was associated with the large (60S) subunit. Thus the diminished capacity of ribosomes from muscle of diabetic rats to translate turnip-yellow-mosaic-virus RNA was not the result of decreased binding of the template.     

Polyribosome formation and poly(A)-containing RNA in embryos of the sand dollar,Dendraster excentricus

Summary The pattern of appearance of ribosomes, newly synthesized mRNA, and poly(A)-containing mRNA in polyribosomes has been examined in sand dollar embryos. From early blastula until shortly before hatching small polyribosomes engaged in histone synthesis predominate. At the time of hatching, when the rate of cell increase is maximal, the proportion of poly(A)-containing RNA in polyribosomes is low. After hatching a new class of large polyribosomes appears and the amount of poly(A)-containing polyribosomal RNA increases. Cordycepin, an inhibitor of RNA adenylylation, prevents the appearance of the large polyribosomes after hatching as well as the increase in poly(A)-containing polyribosomal RNA.     

Ribosomal subunit localization of hemoglobin messenger RNA.

When rabbit reticulocyte polyribosomes are treated with 0.5 M KCl, they dissociate into subunits and release a protein fraction which is required for peptide chain initiation in a cell-free system using KCl-treated subunits as the source of ribosomes. Three independent methods were used to determine the fate of mRNA after KCl treatment of the subunits. These three methods (sucrose gradient analysis of RNA after dissociating it from protein with sodium dodecylsulfate, acrylamide gel electrophoresis of RNA and electron microscopic analysis of subunits) all showed the 8--9-S mRNA to be associated with the small subunit, but not the large subunit. Furthermore, no mRNA was found to be associated with either "native" ribosomal subunit in a reticulocyte lysate.     

Mobility of ribosomes bound to microsomal membranes. A freeze-etch and thin-section electron microscope study of the structure and fluidity of the rough endoplasmic reticulum

The lateral mobility of ribosomes bound to rough endoplasmic reticulum (RER) membranes was demonstrated under experimental conditions. High- salt-washed rough microsomes were treated with pancreatic ribonuclease (RNase) to cleave the mRNA of bound polyribosomes and allow the movement of individual bound ribosomesmfreeze-etch and thin-section electron microscopy demonstrated that, when rough microsomes were treated with RNase at 4 degrees C and then maintained at this temperature until fixation, the bound ribosomes retained their homogeneous distribution on the microsomal surface. However, when RNase- treated rough microsomes were brought to 24 degrees C, a temperature above the thermotropic phase transition of the microsomal phospholipids, bound ribosomes were no longer distributed homogeneously but, instead, formed large, tightly packed aggregates on the microsomal surface. Bound polyribosomes could also be aggregated by treating rough microsomes with antibodies raised against large ribosomal subunit proteins. In these experiments, extensive cross-linking of ribosomes from adjacent microsomes also occurred, and large ribosome-free membrane areas were produced. Sedimentation analysis in sucrose density gradients demonstrated that the RNase treatment did not release bound ribosomes from the membranes; however, the aggregated ribosomes remain capable of peptide bond synthesis and were released by puromycin. It is proposed that the formation of ribosomal aggregates on the microsomal surface results from the lateral displacement of ribosomes along with their attached binding sites, nascent polypeptide chains, and other associated membrane proteins; The inhibition of ribosome mobility after maintaining rough microsomes at 4 degrees C after RNase, or antibody, treatment suggests that the ribosome binding sites are integral membrane proteins and that their mobility is controlled by the fluidity of the RER membrane. Examination of the hydrophobic interior of microsomal membranes by the freeze-fracture technique revealed the presence of homogeneously distributed 105-A intramembrane particles in control rough microsomes. However, aggregation of ribosomes by RNase, or their removal by treatment with puromycin, led to a redistribution of the particles into large aggregates on the cytoplasmic fracture face, leaving large particle-free regions.     

Analysis of cytoplasmic RNA and polyribosmomes from feline leukemia virus-infected cells.

Cytoplasmic virus-specific RNA and polyribosomes from a chronically infected feline thymus tumor cell line, F-422, were analyzed by using in vitro-synthesized feline leukemia virus (Rickard strain) (R-FeLV) complementary DNA (cDNA) probe. By hybridization kinetics analysis, cytoplasmic, polyribosomat, and nuclear RNAs were found to be 2.1, 2.6, and 0.7% virus specific, respectively. Size classes within subcellular fractions were determined by sucrose gradient centrifugation in the presence of dimethyl sulfoxide followed by hybridization. The cytoplasmic fraction contained a 28S size class, which corresponds to the size of virion subunit RNA, and 36S, 23S, and 15 to 18S RNA species. The virus-specific 36S, 23S, and 15 to 18S species but not the 28S RNA were present in both the total and polyadenylic acid-containing polyribosomal RNA. Anti-FeLV gamma globulin bound to rapidly sedimenting polyribosomes, with the peak binding at 400S. The specificity of the binding for nascent virus-specific protein was determined in control experiments that involved mixing polyribosomes with soluble virion proteins, absorption of specific gamma globulin with soluble virion proteins, and puromycin-induced nascent protein release. The R-FeLV cDNA probe hybridized to RNA in two polyribosomal regions (approximately 400 to 450S and 250S) within the polyribosomal gradients before but not after EDTA treatment. The 400 to 450S polyribosomes contained three major peaks of virus-specific RNA at 36S, 23S, and 15 to 18S, whereas the 250S polyribosomes contained predominantly 36S and 15 to 18S RNA. Further experiments suggest that an approximately 36S minor subunit is present in virion RNA.     

Protein synthesis kinetics with ribosomes from temperature-sensitive mutants of Escherichia coli.

The kinetics of MS2 ribonucleic acid (RNA) directed protein synthesis have been investigated at seven temperatures between 30 and 47 degrees C by using ribosomes isolated from a wild type strain and seven temperature-sensitive mutants of Escherichia coli. The amount of MS2 coat protein formed at each temperature was determined by gel electrophoresis of the products formed with control ribosomes. With ribosomes from each of the mutant strains, the activation energy required to drive protein synthesis below the maximum temperature (up to 40 degrees C) was increased relative to the control (wild type) activity. Preincubation of the ribosomes at 44 degrees C revealed the kinetics of thermal inactivation, with ribosomes from each of the mutants having a half-life for inactivation less than that of the control ribosomes. A good correlation was observed between the relative activity of the different ribosomes at 44 degrees C and their relative rate of thermal inactivation. Mixing assays allowed the identification of a temperature-sensitive ribosomal subunit for each of the mutants. Defects in one or more of three specific steps in protein synthesis (messenger RNA binding, transfer RNA binding, transfer RNA binding, and subunit reassociation) were identified for the ribosomes from each mutant. The relationship between temperature sensitivity and protein synthesis in these strains is discussed.     

The biosynthesis of ribulose bisphosphate carboxylase. Uncoupling of the synthesis of the large and small subunits in isolated soybean leaf cells

Isolated leaf cells from soybean (Glycine max) incorporate [35S]methionine into protein at a linear rate for at least 5h. Analysis of the products of incorporation by one-dimensional and two-dimensional polyacrylamide gel electrophoresis shows that major products are the large and small subunits of the chloroplast enzyme, ribulose bisphosphate carboxylase. The large subunit is synthesized by chloroplast ribosomes and the small subunit by cytoplasmic ribosomes. Addition of chloramphenicol to the cells reduces incorporation into the large subunit without affecting incorporation into the products of cytoplasmic ribosomes. Addition of cycloheximide or 2-(4-methyl-2,6-dinitroanilino)-N-methylpropionamide stops incorporation into the small subunit, but large subunit continues to be made for at least 4 h. For accurate estimates of incorporation into the large subunit, it is essential to use two-dimensional gel electrophoresis, because the large subunit region on one-dimensional gels is contaminated with the products of cytoplasmic ribosomes. Newly synthesized large subunits continue to enter complete molecules of ribulose bisphosphate carboxylase in the absence of small subunit synthesis. These results suggest that, in contrast to the situation in algal cells, the synthesis of the two subunits of ribulose bisphosphate carboxylase in the different subcellular compartments of higher plant cells is not tightly coupled over short time periods, and that a pool of small subunits exists in these cells. The results are disucssed in relation to possible mechanisms for the integration of the synthesis of the large and small subunits of ribulose bisphosphate carboxylase.     

Different binding of poly(A)-containing and poly(A)-free fractions of nuclear ribonucleic acid to ribosomes from rat liver.

Total nuclear RNA extracted from nuclei of rat liver cells by phenol/chloroform in the presence of sodium dodecyl sulphate was separated by combined gel filtration on Sepharose 4 B and affinity chromatography on poly(U) Sepharose into fractions differing in their molecular weights and contents of poly(A) sequences. The poly(A)-containing 45-S RNA became labelled most rapidly if rats were administered [3H] orotic acid. This fraction showed a high template activity when added to postmitochondrial supernatants of the Krebs ascites tumour. Fractions of nRNA, free of poly(A) sequences, had no stimulating effect on protein synthesis in this system. The 45-S RNA-containing poly(A) was readily bound to crude polyribosomes from rat liver at 0 degrees C and both ATP and GTP were necessary for this reaction. Sucrose gradient analyses provided evidence that this RNA species is bound predominantly to 80-S ribosomes. No binding was obtained with polyribosomes washed with 0.5 M KCl. The binding ability of washed polyribosomes was restored by the addition of the ribosomal wash fraction or rat liver cytosol. Crude polyribosomes bound significantly lower quantities of nRNA species free of poly(A) when compared with poly(A)-45-S RNA. The label was scattered through the whole ribosomal sedimentation pattern with no predominant peaks and the binding reaction required neither soluble factors nor nucleotide cofactors. The labelling kinetics and high template activity of poly(A)-45-S nRNA indicate that this fraction contains precursors of cytoplasmic mRNA. Requirements for soluble factors and nucleotide cofactors in the binding of this RNA species to 80-S ribosomes suggest that this binding, unlike that of other nRNA species, has a specific mechanism resembling that of mRNA binding during peptide initiation.     

Formation of the small subunit in the absence of the large subunit of ribulose 1,5-bisphosphate carboxylase in 70 S ribosome-deficient rye leaves.

Immunological tests with monospecific antisera to ribulosebisphosphate carboxylase (EC 4.1.1.39) and to its large and small subunits indicated the presence of a protein with antigenic properties of the small subunit in the absence of the large subunit in the leaves of young rye plants (Secale cereale L.) with a high-temperature-induced (32 °C) deficiency of 70 S plastid ribosomes. The small subunit-like protein was isolated from crude extracts of plastid ribosome-deficient 32 °C-grown leaf tissue by the use of columns with immobilized antibody. The main polypeptide retained by the immobilized antibodies had the same mobility after electrophoresis on sodium dodecyl sulfate-polyacrylamide gels as the small subunit of ribulosebisphosphate carboxylase and was also immunologically identical to the small subunit. The small subunit-like protein was present in the supernatant as well as in the membrane fraction of isolated 70 S ribosome-deficient plastids. At very young stages of normal leaves grown at a permissive temperature (22 °C) an excess of small subunit was observed that was also not integrated into the complete ribulosebisphosphate carboxylase molecule. From the results, we conclude that the synthesis of the small subunit occurs on cytoplasmic ribosomes and is not strictly coordinated with the translation of the large subunit in the chloroplast. During early leaf development, the formation of the large subunit seems to be the ratelimiting step in the synthesis of ribulosebisphosphate carboxylase.     

Nascent polypeptide chains exit the ribosome in the same relative position in both eucaryotes and procaryotes

We located the polypeptide nascent chain as it leaves cytoplasmic ribosomes from the plant Lemna gibba by immune electron microscopy using antibodies against the small subunit of the enzyme ribulose-1,5-bisphosphate carboxylase. Similar studies with Escherichia coli ribosomes, using antibodies directed against the enzyme beta-galactosidase, show that the polypeptide nascent chain emerges in the same relative position in plants and bacteria. The eucaryotic ribosomal exit site is on the large subunit, approximately 75 A from the interface between subunits and nearly 160 A from the central protuberance, the presumed site for peptidyl transfer. This is the first functional site on both the eucaryotic and procaryotic ribosomes to be determined.     

Polyribosomes from peas: an improved method for their isolation in the absence of ribonuclease inhibitors

Profiles of polyribosomes were obtained from etiolated stem segments of Pisum sativum L. var. Alaska isolated in various buffers. Tissue homogenized in a medium containing 0.2 m tris-HCl, pH 8.5, 0.2 m sucrose, 30 mm MgCl₂, and 60 mm KCl yielded polyribosomes exhibiting far less degradation than tissue homogenized in conventional media containing tris-HCl at lower ionic strength and pH. A further decrease in degradation was found when polyribosomes were sedimented through a sucrose pad buffered at pH 8.5 prior to centrifugation. Increased separation was obtained using heavy (125-500 mg/ml), linear sucrose gradients. Using these techniques, messenger RNA species bearing up to 12 ribosomes (dodecamers) were resolved, with messenger RNA chains bearing 9 ribosomes (nonamers) being the most abundant (having the highest absorption peak). The data presented suggest that buffer of high ionic strength and high pH was more effective in preventing degradation of polyribosomes than was diethyl pyrocarbonate and, furthermore, that ratios involving large polyribosomes (hexamers and larger) were more accurate indices of degradation than were ratios involving total polyribosomes.     

Protein synthesis defects in temperature-sensitive mutants of Escherichia coli with altered ribosomal proteins

The ribosomes from four temperature-sensitive mutants of Escherichia coli have been examined for defects in cell-free protein synthesis. The mutants examined had alterations in ribosomal proteins S10, S15, or L22 (two strains). Ribosomes from each mutant showed a reduced activity in the translation of phage MS2 RNA at 44 degrees C and were more rapidly inactivated by heating at this temperature compared to control ribosomes. Ribosomal subunits from three of the mutants demonstrated a partial or complete inability to reassociate at 44 degrees C. 70-S ribosomes from two strains showed a reducton in messenger RNA binding. tRNA binding to the 30 S subunit was reduced in the strains with altered 30-S proteins and binding to the 50 S subunit was affected in the mutants with a change in 50 S protein L22. The relation between ribosomal protein structure and function in protein synthesis in these mutants is discussed.     

Translating ribosomes inhibit poliovirus negative-strand RNA synthesis

Poliovirus has a single-stranded RNA genome of positive polarity that serves two essential functions at the start of the viral replication cycle in infected cells. First, it is translated to synthesize viral proteins and, second, it is copied by the viral polymerase to synthesize negative-strand RNA. We investigated these two reactions by using HeLa S10 in vitro translation-RNA replication reactions. Preinitiation RNA replication complexes were isolated from these reactions and then used to measure the sequential synthesis of negative- and positive-strand RNAs in the presence of different protein synthesis inhibitors. Puromycin was found to stimulate RNA replication overall. In contrast, RNA replication was inhibited by diphtheria toxin, cycloheximide, anisomycin, and ricin A chain. Dose-response experiments showed that precisely the same concentration of a specific drug was required to inhibit protein synthesis and to either stimulate or inhibit RNA replication. This suggested that the ability of these drugs to affect RNA replication was linked to their ability to alter the normal clearance of translating ribosomes from the input viral RNA. Consistent with this idea was the finding that the protein synthesis inhibitors had no measurable effect on positive-strand synthesis in normal RNA replication complexes. In marked contrast, negative-strand synthesis was stimulated by puromycin and was inhibited by cycloheximide. Puromycin causes polypeptide chain termination and induces the dissociation of polyribosomes from mRNA. Cycloheximide and other inhibitors of polypeptide chain elongation "freeze" ribosomes on mRNA and prevent the normal clearance of ribosomes from viral RNA templates. Therefore, it appears that the poliovirus polymerase was not able to dislodge translating ribosomes from viral RNA templates and mediate the switch from translation to negative-strand synthesis. Instead, the initiation of negative-strand synthesis appears to be coordinately regulated with the natural clearance of translating ribosomes to avoid the dilemma of ribosome-polymerase collisions.     

Proteins of mammalian mitochondrial ribosomes.

The bovine mitochondrial system is being developed as a model system for studies on mammalian mitochondrial ribosomes. Information is emerging on the structural organization and RNA binding properties of proteins in these mitochondrial ribosomes. Unexpectedly, these ribosomes appear to interact directly with GTP, via a high affinity binding site on the small subunit. Despite major differences in their RNA content and physical properties, mammalian mitochondrial and cytoplasmic ribosomes contain about the same number of proteins. The proteins in each kind of ribosome have a similar size distribution, and both sets are entirely coded by nuclear genes, raising the possibility that these different ribosomes may contain the same set of proteins. Comparison of bovine mitochondrial and cytoplasmic r-proteins by co-electrophoresis in two-dimensional gels reveals that most of the cytoplasmic ribosomal proteins are more basic than the mitochondrial ribosomal proteins, and that none are co-migratory with mitochondrial ribosomal proteins, suggesting that the proteins in the two ribosomes are different. To exclude the possibility that the electrophoretic differences result only from post-translational modification of otherwise identical proteins, antibodies against several proteins from the large subunit of bovine mitochondrial ribosomes were tested against cytoplasmic ribosomes by solid phase radioimmunoassay and against cytoplasmic ribosomal proteins on Western blots. The lack of cross-reaction of these antibodies with cytoplasmic r-proteins suggests that mitochondrial ribosomal proteins have different primary structures and thus are most likely encoded by a separate set of nuclear genes.     

The effect of cycloheximide upon polyribosome stability in two yeast mutants defective respectively in the initiation of polypeptide chains and in messenger RNA synthesis

Summary The effect of cycloheximide upon protein synthesis, RNA metabolism, and polyribosome stability was investigated in the parent and in two temperature-sensitive mutant yeast strains defective respectively in the initiation of polypeptide chains and in messenger RNA synthesis. Cycloheximide at high concentrations (100 g/ml) severely inhibits but does not completely stop protein synthesis (Fig. 1); the incorporation of ¹⁴C-amino acids into polyribosome-associated nascent polypeptide chains continues at a slow but measurable rate (Figs. 2 and 3). Polyribosome structures are stable in the parent strain at 36° whether or not cycloheximide is present (Fig. 5). However, in Mutant ts^- 136, a mutant defective in messenger as well as in stable RNA production, polyribosomes decay at the restrictive temperature (36° C) at the same rate whether or not cycloheximide is present (Fig. 5). Thus the maintenance of polyribosome structures is dependent upon the continued synthesis of messenger RNA even under conditions of extremely slow polypeptide chain elongation. In mutant ts^- 187, a mutant defective in the initiation of polypeptide chains, all of the polyribosomes decay to monoribosomes within 2 minutes after a shift to the restrictive temperature; cycloheximide completely prevents this decay demonstrating that this mutant is capable of continued messenger RNA synthesis at 36° C. Consistent with these observations is the fact that a newly synthesized heterogeneously sedimenting RNA fraction continues to enter polyribosomes in the presence of cycloheximide whereas the entrance of newly synthesized ribosomal RNA is severely inhibited (Figs. 7, 8, 9). The decay or lack of decay of polyribosomes at the restrictive temperature is, therefore, a rapid and discriminating test for the analysis of mutants defective in macromolecule synthesis. Mutants which exhibit a decay of polyribosomes in the presence of cycloheximide are likely to be defective directly or indirectly in the synthesis of messenger RNA whereas mutants in which decay is prevented or slowed by cycloheximide are likely to be defective in some factor required for the association of ribosomes and messenger RNA.     

Cell-free synthesis of tryptophanase from Escherichia coli. Use of ribonucleic acid isolated from induced cells and a comparison of the product from a system employing ribosomes with that from one employing ribosomes and exogenous ribonucleic acid

1. Polyribosomes and RNA were isolated from cultures in which tryptophanase (EC 4.2.1.-) was induced. The polyribosomes were incubated under conditions of protein synthesis, in the presence of a radioactive amino acid and a post-ribosomal supernatant fraction obtained from repressed cells. The RNA preparations were incubated under conditions of protein synthesis in the presence of a radioactive amino acid and a supernatant fraction containing ribosomes from repressed cells. 2. The system was characterized and the synthesis of a radioactive protein with the same chromatographic properties as tryptophanase was demonstrated. This synthesis was shown to be time-dependent and required the presence of RNA from induced cultures, ribosomes and an energy supply; it was inhibited by chloramphenicol. 3. The maximum activity for the synthesis of this protein was found to be associated with 23S rRNA isolated from sucrose gradients. 4. The N-terminal amino acid of tryptophanase was labelled in the protein synthesized in this system but not in the protein synthesized by polyribosomes (without added RNA). Conversely, the C-terminal amino acid of tryptophanase was labelled in the polyribosome system but not in the RNA-containing system. 5. Tryptic digests of protein labelled in vitro were compared with those of tryptophanase. No labelled tryptic peptides were identified other than tryptophanase tryptic peptides. An analysis of the results implied that in the polyribosome system almost the complete tryptophanase subunit chain was labelled but that in the RNA-containing system these chains were incompletely synthesized. 6. Sucrose-gradient analysis of protein synthesized in the RNA-containing system suggested that it cannot be converted into structures with the same sedimentation properties as native tryptophanase. 7. The significance of these results for the assay of tryptophanase mRNA and for an understanding of the control of the translation of this mRNA in vivo is discussed.     

Membrane-bound ribosomes of myeloma cells. II. Kinetic studies on the entry of newly made ribosomal subunits into the free and the membrane- bound ribosomal particles

The kinetics of appearance of newly made 60S and 40S ribosomal subunits in the free and membrane-bound ribosomal particles of P3K cells were explored by determining the specific radioactivities of their 18S and 28S RNA after various lengths of [3H]uridine pulse. Both 40S and 60S subunits enter free and membrane-bound polyribosomes at comparable rates from the cytoplasmic pool of newly made, free native subunits, the 40S subunits entering the native subunit pool and the polyribosomes slightly earlier than the 60S subunits. At all times, the specific radioactivity of the membrane-bound native 60S subunits was slightly lower than that of the polyribosomal 60S subunits. This indicates that the membrane-bound native 60S subunits are not precursors destined to enter membrane-bound polyribosomes and suggests that they result from the dissociation of ribosomes after chain termination. The results observed also suggest that the membrane-bound native 60S subunits are not reutilized before their release from the membranes, which probably takes place shortly after dissociation from their 40S subunits. The monoribosomes, both free and membrane-bound, had the lowest specific radioactivities in their subunits. Finally, a small amount of newly made native 40S subunits, containing 18S RNA of high specific radioactivity, and apparently also newly made messenger RNA were detected on the membranes. The high turnover of these membrane-bound native 40S subunits suggests that they may represent initiation complexes formed with mRNA which has just reached the membranes and which has not yet given rise to polyribosomes.     

The ribosomal peptidyl transferase center: structure, function, evolution, inhibition

The ribosomal peptidyl transferase center (PTC) resides in the large ribosomal subunit and catalyzes the two principal chemical reactions of protein synthesis: peptide bond formation and peptide release. The catalytic mechanisms employed and their inhibition by antibiotics have been in the focus of molecular and structural biologists for decades. With the elucidation of atomic structures of the large ribosomal subunit at the dawn of the new millennium, these questions gained a new level of molecular significance. The crystallographic structures compellingly confirmed that peptidyl transferase is an RNA enzyme. This places the ribosome on the list of naturally occurring ribozymes that outlived the transition from the pre-biotic RNA World to contemporary biology. Biochemical, genetic and structural evidence highlight the role of the ribosome as an entropic catalyst that accelerates peptide bond formation primarily by substrate positioning. At the same time, peptide release should more strongly depend on chemical catalysis likely involving an rRNA group of the PTC. The PTC is characterized by the most pronounced accumulation of universally conserved rRNA nucleotides in the entire ribosome. Thus, it came as a surprise that recent findings revealed an unexpected high level of variation in the mode of antibiotic binding to the PTC of ribosomes from different organisms.