Project description:1. The ability of chemically hypermethylated Escherichia coli B transfer RNA to accept 19 amino acids was studied and the results were compared with those obtained with a control sample of E. coli B transfer RNA incubated under similar conditions in the absence of methylating agent. 2. There is a marked decrease in the ability of the modified transfer RNA to accept amino acids in almost all instances. 3. The acceptance of cysteine appears to be unique in that it is enhanced in the hypermethylated transfer RNA. 4. More detailed studies on the kinetics of acceptance for six amino acids is presented, emphasizing the variation in response of the individual amino acids. 5. Increasing hypermethylation causes a progressive decrease in the amino acid acceptance. 6. The results are discussed in terms of methylation at functional sites within the transfer RNA and possible conformational alterations to the structure of the macromolecule.

Project description:Translocation of tRNAs through the ribosome during protein synthesis involves large-scale structural rearrangement of the ribosome and ribosome-bound tRNAs that is accompanied by extensive and dynamic remodeling of tRNA-ribosome interactions. How the rearrangement of individual tRNA-ribosome interactions influences tRNA movement during translocation, however, remains largely unknown. To address this question, we used single-molecule FRET to characterize the dynamics of ribosomal pretranslocation (PRE) complex analogs carrying either wild-type or systematically mutagenized tRNAs. Our data reveal how specific tRNA-ribosome interactions regulate the rate of PRE complex rearrangement into a critical, on-pathway translocation intermediate and how these interactions control the stability of the resulting configuration. Notably, our results suggest that the conformational flexibility of the tRNA molecule has a crucial role in directing the structural dynamics of the PRE complex during translocation.

Project description:In this work, we report the transfer of graphene onto eight commercial microfiltration substrates having different pore sizes and surface characteristics. Monolayer graphene grown on copper by the chemical vapor deposition (CVD) process was transferred by the pressing method over the target substrates, followed by wet etching of copper to obtain monolayer graphene/polymer membranes. Scanning electron microscopy (SEM), atomic force microscopy (AFM), and contact angle (CA) measurements were carried out to explore the graphene layer transferability. Three factors, namely, the substrate roughness, its pore size, and its surface wetting (degree of hydrophobicity) are found to affect the conformality and coverage of the transferred graphene monolayer on the substrate surface. A good quality graphene transfer is achieved on the substrate with the following characteristics; being hydrophobic (CA > 90°), having small pore size, and low surface roughness, with a CA to RMS (root mean square) ratio higher than 2.7°/nm.

Project description:1. A protein factor promoting the binding of initiator tRNA to the 40S ribosomal subunit was purified to homogeneity (more than 2500-fold) from rat liver cytosol. It has a mol.wt. of 265000 and is composed of four subunits of identical molecular weight. 2. This factor directs the binding of methionyl-tRNA(fMet) and to a lesser extent also of N-acetylphenylalanyl-tRNA, but not of methionyl-tRNA(Met) or phenylalanyl-tRNA, to the smaller ribosomal subunit at high concentrations of GTP (8-10mm) with an optimum at pH4.0. As evidenced by sucrose-density-gradient centrifugation, initiator tRNA becomes bound to the 40S subunit or to 80S ribosomes. 3. A deacylase activity specific for methionyl-tRNA(fMet) is associated with the pure factor. The factor significantly stimulates the translation of natural message in systems containing polyribosomes and both purified peptide-elongation factors. 4. The factor binds initiator tRNA or GTP to form unstable binary complexes and forms a ternary complex with methionyl-tRNA(fMet) and GTP. This complex is relatively stable. 5. In the absence of any cofactors the factor forms a stable complex with 40S and 80S ribosomes. This preformed ribosomal complex binds efficiently initiator tRNA at pH7.5 and low concentrations of GTP (1-2mm). The ternary complex of the factor with methionyl-tRNA(fMet) and GTP may be liberated from this ribosomal complex. 6. A protein factor capable of promoting the binding and simultaneously the deacylation of initiator tRNA may apparently have a regulatory function in physiological gene translation by removing an excess of methionyl-tRNA(fMet) not required for translation.

Project description:1. Transferase I of rat liver binds aminoacyl-tRNA to form a relatively stable complex, which is retained on cellulose nitrate filters. This reaction proceeds at both 0 degrees C and 37 degrees C and is inhibited by GTP. The resulting product is stabilized by GTP and Mg(2+). 2. Only very low quantities of deacylated tRNA are bound by transferase I. 3. Methods are described for the preparative isolation of the transferase I-aminoacyl-tRNA complex from incubation mixtures by using ion-exchange procedures. 4. The transferase I-aminoacyl-tRNA complex becomes readily bound to ribosomes. The presence of Mg(2+) is essential for the binding. GTP stimulates this reaction but is not absolutely required. 5. It is concluded that the formation of the transferase I-aminoacyl-tRNA complex may be the primary reaction in the binding of aminoacyl-tRNA to mammalian ribosomes and that, unlike in bacterial systems, GTP is not absolutely required for this step.

Project description:1. Different reaction steps involved in protein synthesis were studied in skeletal muscles from control and myopathic hamsters. 2. There was no difference between partially purified aminoacyl-tRNA synthetases from myopathic and control animals in yield or catalytic activity, as tested with exogenous deacylated tRNA. 3. However, isolated deacylated tRNA from myopathic muscle was aminoacylated by these synthetases to a lesser extent than that derived from control muscle. 4. Addition of deacylated tRNA isolated from control muscle improved the performance of pH5 enzymes from myopathic muscle in polypeptide synthesis on homologous polyribosomes; tRNA isolated from myopathic animals did not. 5. Preparation of extracts from both types of animals in the presence of the ribonuclease-absorbent bentonite led to an increased capacity of endogenous tRNA to accept amino acids in pH5 enzymes prepared from normal and abnormal tissue, but the difference between the two systems remained the same. 6. Total tRNA nucleotidyltransferase activity, tested with twice-pyrophosphorolysed rat liver tRNA, was identical in both extracts. 7. Added tRNA nucleotidyltransferase incorporated more AMP and CMP into endogenous tRNA with the pH5 enzyme from myopathic muscle than with that from control muscle. 8. Preincubation of deacylated tRNA from myopathic muscle with ATP, CTP and tRNA nucleotidyltransferase more than doubled its subsequent aminoacyl-acceptor activity, and halved the extent of the defect relative to aminoacylation of control tRNA similarly treated. Endogenous tRNA in pH5 enzyme preparations behaved likewise. 9. It is suggested that a 3'-exonuclease in myopathic muscles attacks tRNA molecules in such a way that some of them remain substrates for tRNA nucleotidyltransferase, which may incorporate into RNA not only AMP and CMP, but also GMP. 10. Cell-free protein synthesis in preparations from myopathic hamster muscles is limited by the supply of intact tRNA molecules.

Project description:The properties of a site, on Escherichia coli ribosomes, which binds peptidyl-s-RNA (where s-RNA refers to ;soluble' or transfer RNA) have been investigated. The binding is stable both in low Mg(2+) concentration (0.1mm), and in high Mg(2+) concentration (10mm) in the absence or presence of potassium chloride (86mm). Puromycin has been used to break the bond between the s-RNA and the polypeptide, and in the absence of further protein synthesis this technique exposes free s-RNA molecules on the ribosomes. The s-RNA exposed remains bound in high Mg(2+) concentration, but the binding is unstable in high Mg(2+) concentration with potassium chloride and the s-RNA can be freed completely from the ribosomes by lowering the Mg(2+) concentration. It can also be displaced by s-RNA in the medium. It is suggested that this ribosomal binding site for peptidyl-s-RNA is the site for peptide bond formation. Further, it is proposed that it is the same site that can be demonstrated on ribosomes not engaged in protein synthesis and that, in high Mg(2+) concentration, will bind s-RNA molecules charged or uncharged with amino acids.

Project description:During exponential growth, the mutatn strain Escherichia coli 15-28 accumulates 47S particles, which are unusual precursors to 50S ribosomal subunits. The 47S particles have little ability to bind chloramphenicol, but binding of a fragment of aminoacyl-tRNA is about half that by completed subunits. The 70S (and 50S) ribosomes of strain 15-28 and its parent (strain 15TP) do not differ in chloramphenicol binding. Although ribosomes from the mutant are less able than those from the parent to bind the fragment, this difference is not as marked as was found previously [Sims & Wild (1976) Biochem. J. 160, 721-726] for the binding of an analogue of peptidyl-tRNA and for peptidyltransferase activity. The altered activities may arise because strain 15-28 misassembles 50S subunits of altered conformation and because the few proteins that 47S patricles lack have vital functions in some of the partial reactions of protein synthesis.

Project description:Increased protein misfolding and aggregation are key hallmarks of ageing and many age-related diseases. As generating and maintaining a functional proteome (proteostasis) is crucial to every cellular process, this age-related decline in proteostasis is suggested to play a primary role in the breakdown of diverse cellular subsystems during ageing. Indeed, augmented proteostasis pathways are associated with extended lifespan across different species. With the ribosome as the earliest proteostasis checkpoint, decreased protein synthesis is also a conserved mechanism that extends lifespan. Yet, it remains unclear whether ageing impacts translation after initiation. Here, we use worms and yeast to investigate how ageing influences translation elongation. We show an age-dependent increase in ribosome pausing at diverse positions in coding sequences. This pausing is conserved in both worms and yeast, particularly at Arg and polybasic regions. We further show that such pausing is associated with the age-dependent aggregation of truncated nascent proteins involved in proteostasis pathways, notably aminoacyl tRNA synthetases. Moreover, we find that impairment in clearing truncated nascent proteins is associated with decreased lifespan. These data establish elongation kinetics and co-translational quality control as critical contributors of the age-related proteostasis collapse, which may precipitate the systemic decline observed during ageing.

Project description:Nascent polypeptide-associated complex (NAC) was identified in eukaryotes as the first cytosolic factor that contacts the nascent polypeptide chain emerging from the ribosome. NAC is present as a homodimer in archaea and as a highly conserved heterodimer in eukaryotes. Mutations in NAC cause severe embryonically lethal phenotypes in mice, Drosophila melanogaster, and Caenorhabditis elegans. In the yeast Saccharomyces cerevisiae NAC is quantitatively associated with ribosomes. Here we show that NAC contacts several ribosomal proteins. The N terminus of betaNAC, however, specifically contacts near the tunnel exit ribosomal protein Rpl31, which is unique to eukaryotes and archaea. Moreover, the first 23 amino acids of betaNAC are sufficient to direct an otherwise non-associated protein to the ribosome. In contrast, alphaNAC (Egd2p) contacts Rpl17, the direct neighbor of Rpl31 at the ribosomal tunnel exit site. Rpl31 was also recently identified as a contact site for the SRP receptor and the ribosome-associated complex. Furthermore, in Escherichia coli peptide deformylase (PDF) interacts with the corresponding surface area on the eubacterial ribosome. In addition to the previously identified universal adapter site represented by Rpl25/Rpl35, we therefore refer to Rpl31/Rpl17 as a novel universal docking site for ribosome-associated factors on the eukaryotic ribosome.