The effect of a hydrophobic N-terminal probe on translational pausing of chloramphenicol acetyl transferase and rhodanese

Enhancement of recombinant human ADAM15 disintegrin domain expression level by releasing the rare codons and amino acids restriction

This study was aimed at increasing the production of the recombinant human ADAM15 disintegrin domain (RADD) in Escherichia coli by releasing the rare codons and restricting amino acid residues. Three different strategies for increasing RADD production were examined: to select the suitable host strain, to optimize the rare codons, and to delete the amino acids residues. The total fusion protein glutathione-S-transferase (GST)-RADD concentration of 298 mg/l and 326 mg/l were achieved by selecting E. coli Rosetta (DE3) as the host strain and by changing GGA to GGC at the GST-RADD cassette, respectively. The RADD concentration was increased by 35.7% by eliminating the "Pro-Glu-Phe" residues at the GST-RADD junction. By combinational utilizing the preferred codon introduction and amino acid sequence optimization in E. coli Rosetta (DE3), the highest RADD concentration of 68 mg/l was achieved. The proposed strategy may provide an alternative approach for other enhanced recombinant protein production by E. coli.

Sequences downstream of the start codon and their relations to G + C content and optimal growth temperature in prokaryotic genomes

The mechanism of translation initiation is responsible for shaping the mRNA sequences downstream of the start codon. However, this region has not been systematically analyzed in prokaryotes. We used sequence logos and statistic methods to analyze the patterns of overrepresented sequences in this region for 125 species of bacteria and 23 species of archaea. The specific positions are compared to the first 33 amino acids in the proteins. At the 2nd amino acid position, Lys, Ser or Thr is highly overrepresented for 68% to 84% of the genomes examined and Ala is highly overrepresented for 57% of the genomes. Overrepresentation of Lys2 is negatively correlated with the G + C content and overrepresentation of Ser2 or Thr2 is positively correlated with the G + C content of genomes. Ile at the 4th to the 8th positions were found to be overrepresented for 91% of the genomes analyzed and this seemed to be conserved for both bacteria and archaea. Organisms growing at high temperatures have relatively low extent of nucleotides bias at 5' termini of open reading frames (ORFs). The extent of overrepresenting A and underrepresenting G at ORF 5' termini is reduced in thermophiles and hyperthermophiles for both archaea and bacteria.

A strategy for high-level expression of soluble and functional human interferon alpha as a GST-fusion protein in E. coli

Escherichia coli is the most extensively used host for the production of recombinant proteins. However, most of the eukaryotic proteins are typically obtained as insoluble, misfolded inclusion bodies that need solubilization and refolding. To achieve high-level expression of soluble recombinant human interferon alpha (rhIFNalpha) in E. coli, we have first constructed a recombinant expression plasmid (pGEX-hIFNalpha2b), in which we merged the hIFNalpha2b cDNA with the glutathione S-transferase (GST) coding sequence downstream of the tac-inducible promoter. Using this plasmid, we have achieved 70% expression of soluble rhIFNalpha2b as a GST fusion protein using E. coli BL21 strain, under optimized environmental factors such as culture growth temperature and inducer (IPTG) concentration. However, release of the IFN moiety from the fusion protein by thrombin digestion was not optimal. Therefore, we have engineered the expression cassette to optimize the amino acid sequence at the GST-IFN junction and to introduce E. coli preferred codon within the thrombin cleavage site. We have used the engineered plasmid (pGEX-Delta-hIFNalpha2b) and the modified E. coli trxB(-)/gor(-) (Origami) strain to overcome the problem of removing the GST moiety while expressing soluble rhIFNalpha2b. Our results show the production of soluble and functional rhIFNalpha2b at a yield of 100 mg/l, without optimization of any step of the process. The specific biological activity of the purified soluble rhIFNalpha2b was equal to 2.0 x 10(8) IU/mg when compared with the WHO IFNalpha standard. Our data are the first to show that high yield production of soluble and functional rhIFNalpha2b tagged with GST can be achieved in E. coli.

Experimental and Computational Analysis of Translation Products in Apomyoglobin Expression

This work focuses on the experimental analysis of the time-course of protein expression in a cell-free system, in conjunction with the development of a computational model, denoted as progressive chain buildup (PCB), able to simulate translation kinetics and product formation as a function of starting reactant concentrations. Translation of the gene encoding the apomyoglobin (apoMb) model protein was monitored in an Escherichia coli cell-free system under different experimental conditions. Experimentally observed protein expression yields, product accumulation time-course and expression completion times match with the predictions by the PCB model. This algorithm regards elementary single-residue elongations as apparent second-order events and it accounts for aminoacyl-tRNA regeneration during translation. We have used this computational approach to model full-length protein expression and to explore the kinetic behavior of incomplete chains generated during protein biosynthesis. Most of the observed incomplete chains are non-obligatory dead-end species, in that their formation is not mandatory for full-length protein expression, and that they are unable to convert to the expected final translation product. These truncated polypeptides do not arise from post-translational degradation of full-length protein, but from a distinct subpopulation of chains which expresses intrinsically more slowly than the population leading to full-length product. The PCB model is a valuable tool to predict full-length and incomplete chain populations and formulate experimentally testable hypotheses on their origin. PCB simulations are applicable to E.coli cell-free expression systems (both in batch and dialysis mode) under the control of T7 RNA polymerase and to other environments where transcription and translation can be regarded as kinetically decoupled.

Whole genome analysis reveals a high incidence of non-optimal codons in secretory signal sequences of Escherichia coli

Translational pausing may occur due to a number of mechanisms, including the presence of non-optimal codons, and it is thought to play a role in the folding of specific polypeptide domains during translation and in the facilitation of signal peptide recognition during sec-dependent protein targeting. In this whole genome analysis of Escherichia coli we have found that non-optimal codons in the signal peptide-encoding sequences of secretory genes are overrepresented relative to the "mature" portions of these genes; this is in addition to their overrepresentation in the 5'-regions of genes encoding non-secretory proteins. We also find increased non-optimal codon usage at the 3' ends of most E. coli genes, in both non-secretory and secretory sequences. Whereas presumptive translational pausing at the 5' and 3' ends of E. coli messenger RNAs may clearly have a general role in translation, we suggest that it also has a specific role in sec-dependent protein export, possibly in facilitating signal peptide recognition. This finding may have important implications for our understanding of how the majority of non-cytoplasmic proteins are targeted, a process that is essential to all biological cells.

A nascent polypeptide domain that can regulate translation elongation

The evolutionarily conserved fungal arginine attenuator peptide (AAP), as a nascent peptide, stalls the translating ribosome in response to the presence of a high concentration of the amino acid arginine. Here we examine whether the AAP maintains regulatory function in fungal, plant, and animal cell-free translation systems when placed as a domain near the N terminus or internally within a large polypeptide. Pulse-chase analyses of the radiolabeled polypeptides synthesized in these systems indicated that wild-type AAP functions at either position to stall polypeptide synthesis in response to arginine. Toeprint analyses performed to map the positions of stalled ribosomes on transcripts introduced into the fungal system revealed that ribosome stalling required translation of the AAP coding sequence. The positions of the stalled ribosomes were consistent with the sizes of the radiolabeled polypeptide intermediates. These findings demonstrate that an internal polypeptide domain in a nascent chain can regulate eukaryotic translational elongation in response to a small molecule. Apparently the peptide-sensing features are conserved in fungal, plant, and animal ribosomes. These data provide precedents for translational strategies that would allow domains within nascent polypeptide chains to modulate gene expression.

Single synonymous codon substitution eliminates pausing during chloramphenicol acetyl transferase synthesis on Escherichia coli ribosomes in vitro

The coding sequence for chloramphenicol acetyl transferase (CAT) contains several rare codons; three of them are ATA encoding isoleucine in positions 13, 84 and 119 of the amino acid sequence. Expression of CAT on Escherichia coli ribosomes in vitro results in mostly full-length product but also distinct smaller polypeptides from less than 3 kDa to over 20 kDa. As reported earlier, the smaller polypeptides are the predominant products, if translation is initiated with fluorophore-Met-tRNA(f). All this translational pausing is eliminated when the first ATA codon is mutated to ATC, a frequently used codon for isoleucine in E. coli. Addition of large amounts of E. coli tRNA to the coupled transcription/translation reaction does not reduce the number of pause-site peptides seen in the expression of wild-type CAT. Thus we hypothesize that the mRNA structure may be an important determinant for translational pausing.

Folding of a nascent peptide on the ribosome

Even though very significant progress has been made recently in elucidating the structure of the bacterial ribosome and topological assignments of its functional parts, the molecular mechanism of how a peptide is formed and how the nascent peptides is folded on the ribosomes remains uncertain. Here, the current progress and remaining problems are considered from the standpoint of the authors. Topics considered include formation of peptide bonds and models that represent this process, the vicinity of RNA to the nascent peptide, the cotranslational folding hypothesis, evidence that some but not all nascent peptides pass through a region within the 50S ribosomal subunit, presumably the tunnel, in which they are folded and sheltered, pause-site peptides, and the involvement of chaperones in folding of nascent proteins on ribosomes. The chaperone-like activity of the large ribosomal subunit in renaturation of denatured proteins is reviewed. It is concluded that cotranslational folding of some but not all nascent peptides occurs in the large ribosomal subunit. It is suggested that this folding is facilitated by changes in the conformation of the ribosome that are related to the reaction cycle of peptide elongation.

Expression of different coding sequences in cell-free bacterial and eukaryotic systems indicates translational pausing on Escherichia coli ribosomes

Five different coding sequences of bacterial or eukaryotic origin in plasmids under the T7 promoter were expressed in a cell-free system derived from Escherichia coli. Translation on E. coli ribosomes resulted in a full-length product only in four of the five coding sequences tested. A unique pattern of less than full-length polypeptides was generated in each case. Many of these polypeptides on E. coli ribosomes reacted with a puromycin derivative, cytidylic acid-puromycin, which was radioactively labeled. Thus these incomplete polypeptides can be defined as nascent peptides bound to the ribosomal P site. Certain nascent peptides could be shifted into full-length protein indicating that they resulted from translational pausing. In contrast to these results, expression of the same coding sequences in a wheat germ or reticulocyte cell-free system resulted in a 80-90% full-length product with no evidence for nascent polypeptides and translational pausing.

The PAUSE software for analysis of translational control over protein targeting: application to E. nidulans membrane proteins

The PAUSE software has been developed as a new tool to study translational control over protein targeting. This makes it possible to correlate the position of clusters of rare codons in a gene, predicted to cause a translational pause, with the position of hydrophobic stretches in the encoded protein, predicted to span a membrane or to act as a cleavable signal for targeting to the secretory pathway. Furthermore, this software gathers these correlations over whole sets of genes. The PAUSE software is described here, and its use is illustrated on a set of membrane proteins from the fungus Emericella nidulans. Preferential distances of about 45 codons and of about 70 codons between putative transmembrane domains and predicted translational pauses were observed. Given that approximately 30 residues are required to span the large ribosomal subunit, the predicted pauses would therefore occur when the hydrophobic domain starts protruding from the ribosome ('+45 pause'), or fully protrudes as a hairpin ('+70 pause'). Thus, these specific pauses might reflect a translational control over membrane protein targeting or early recognition ('+45 pause'), and over insertion or folding ('+70 pause').

Initiation of protein synthesis with fluorophore-Met-tRNA(f) and the involvement of IF-2

The complicity of initiation factor 2 (IF-2) in causing the observed low incorporation of N-terminal fluorophore from fluorophore-methionyl-tRNA(f) during protein synthesis in an in vitro coupled transcription/translation system was investigated. The low incorporation in comparison to formyl-methionine was not due to the lack of interaction of fluorophore-Met-tRNA(f) with IF-2. Fluorescence measurements of cascade yellow-, eosin-, pyrene-, or coumarin-Met-tRNA(f) determined that all were capable of binding IF-2 at 4 mM Mg(2+) and 37 degrees C. Filter binding assays conducted in the absence of magnesium ions on fMet-tRNA(f), eosin-Met-tRNA(f), and cascade yellow-Met-tRNA(f) confirmed the previously reported value for the dissociation constant of fMet-tRNA(f) of about 1 microM and placed the binding constants for the two fluorophore derivatives about three-fold higher. Binding of the fluorophore-Met-tRNA(f) species to salt-washed ribosomes showed a more significant decrease compared to fMet-tRNA(f). Stimulation in the amount of tRNA bound to the ribosomes upon the addition of IF-2 was observed in each case. All ribosome-bound cascade yellow-Met-tRNA(f) and eosin-Met-tRNA(f) were as puromycin-reactive as fMet-tRNA(f). Cumulatively, the effects observed for the fluorophore-Met-tRNA species in partial reactions of initiation may account for the reduced incorporation of these probes at the N terminus of polypeptides.

Fluorophores at the N terminus of nascent chloramphenicol acetyltransferase peptides affect translation and movement through the ribosome

Structurally different fluorescent probes were covalently attached to methionyl-tRNA(f) and tested for their incorporation into nascent peptides and full-length protein using an Escherichia coli cell-free coupled transcription/translation system. Bovine rhodanese and bacterial chloramphenicol acetyltransferase (CAT) were synthesized using derivatives of cascade yellow, eosin, pyrene, or coumarin attached to [(35)S]Met-tRNA(f). All of the probes tested were incorporated into polypeptides, although less efficiently when compared with formyl-methionine. Eosin, the largest of the fluorophores used with estimated dimensions of 20 x 11 A, caused the largest reduction in product formed. The rate of initiation was reduced with the fluorophore-Met-tRNA(f) compared with fMet-tRNA(f) with pyrene having the least and eosin the biggest effect. Analysis of the nascent polypeptides showed that the modifications at the N terminus affected the rate at which nascent CAT peptides were elongated causing accumulation of peptides of about 4 kDa, possibly by steric hindrance inside the tunnel within the 50 S ribosomal subunit. Fluorescence measurements indicate that the probe at the N terminus of nascent pyrene-CAT peptides is in a relatively hydrophilic environment. This finding is in agreement with recent data showing cross-linking of the N terminus of nascent peptides to nucleotides of the 23 S ribosomal RNA.

Synonymous codon substitutions affect ribosome traffic and protein folding during in vitro translation

To investigate the possible influence of the local rates of translation on protein folding, 16 consecutive rare (in Escherichia coli) codons in the chloramphenicol acetyltransferase (CAT) gene have been replaced by frequent ones. Site-directed silent mutagenesis reduced the pauses in translation of CAT in E. coli S30 extract cell-free system and led to the acceleration of the overall rate of CAT protein synthesis. At the same time, the silently mutated protein (with unaltered protein sequence) synthesized in the E. coli S30 extract system was shown to possess 20% lower specific activity. The data suggest that kinetics of protein translation can affect the in vivo protein-folding pathway, leading to increased levels of protein misfolding.