Mutation that affects pepN translation initiation in Escherichia coli

Mutants altered in their expression of the hybrid pepN-lacZ gene have been selected for resistance to p-nitrophenyl-beta-D-thiogalactopyranoside (a bacteriostatic compound that enters the cells via lac permease). A unique mutation decreasing the level of pepN expression to 9% of that of the wild type has been studied in detail. This mutation controls in cis the expression of the pepN gene. The pepN region from a pepN-lacZ gene fusion has been cloned and sequenced. Comparison of the mutant and wild type sequences indicates that the mutation lies between the Shine-Dalgarno sequence (AGGT) and the initiation codon (AUG). This mutation is a T----C transition which might allow the formation of a stable secondary structure in the region of translation initiation thus decreasing the level of pepN expression.     

Escherichia coli translation initiation factor 3 discriminates the initiation codon in vivo

In a genetic selection designed to isolate Escherichia coli mutations that increase expression of the IS 10 transposase gene ( tnp ), we unexpectedly obtained viable mutants defective in translation initiation factor 3 (IF3). Several lines of evidence led us to conclude that transposase expression, per se , was not increased. Rather, these mutations appear to increase expression of the tnp'–'lacZ gene fusions used in this screen, by increasing translation initiation at downstream, atypical initiation codons. To test this hypothesis we undertook a systematic analysis of start codon requirements and measured the effects of IF3 mutations on initiation from various start codons. Beginning with an efficient translation initiation site, we varied the AUG start codon to all possible codons that differed from AUG by one nucleotide. These potential start codons fall into distinct classes with regard to translation efficiency in vivo : Class I codons (AUG, GUG, and UUG) support efficient translation; Class IIA codons (CUG, AUU, AUC, AUA, and ACG) support translation at levels only 1–3% that of AUG; and Class IIB codons (AGG and AAG) permit levels of translation too low for reliable quantification. Importantly, the IF3 mutations had no effect on translation from Class I codons, but they increased translation from Class II codons 3–5-fold, and this same effect was seen in other gene contexts. Therefore, IF3 is generally able to discriminate between efficient and inefficient codons in vivo , consistent with earlier in vitro observations. We discuss these observations as they relate to IF3 autoregulation and the mechanism of IF3 function.     

Trigger factor retards protein export in Escherichia coli

Trigger factor (TF) is a ribosome-associated protein that interacts with a wide variety of nascent polypeptides in Escherichia coli. Previous studies have indicated that TF cooperates with DnaK to facilitate protein folding, but the basis of this cooperation is unclear. In this study we monitored protein export in E. coli that lack or overproduce TF to obtain further insights into its function. Whereas inactivation of genes encoding most molecular chaperones (including dnaK) impairs protein export, inactivation of the TF gene accelerated protein export and suppressed the need for targeting factors to maintain the translocation competence of presecretory proteins. Furthermore, overproduction of TF (but not DnaK) markedly retarded protein export. Manipulation of TF levels produced similar effects on the export of a cytosolic enzyme fused to a signal peptide. The data strongly suggest that TF has a unique ability to sequester nascent polypeptides for a relatively prolonged period. Based on our results, we propose that TF and DnaK promote protein folding by distinct (but complementary) mechanisms.     

Mutation that suppresses the protein export defect of the secY mutation and causes cold-sensitive growth of Escherichia coli.

A cold-sensitive mutant was isolated among temperature-resistant revertants of the secY24 mutant defective in secretion of envelope proteins across the cytoplasmic membrane at 42 degrees C. A single mutation, designated ssyA3, is responsible both for the extragenic suppression of secY and for the cold-sensitive growth. In contrast to the parental secY24 mutant, the suppressed cells do not accumulate precursors of envelope proteins at any temperatures. The cells containing the ssyA3 mutation, whether in combination with secY24 or not, show an optimal growth at 42 degrees C and a very poor growth at 30 degrees C. At the low temperature, protein synthesis is generally slowed down, probably at the step of chain elongation. The gene ssyA was mapped at a new locus between hisS and glyA on the chromosome. It is possible that the product of this gene interacts both with the protein secretion system and the protein synthesizing system.     

Coupling between codon usage, translation and protein export in Escherichia coli

Proteins destined for export via the Sec-dependent pathway are synthesized with a short N-terminal signal peptide. A requirement for export is that the proteins are in a translocationally competent state. This is a loosely folded state that allows the protein to pass through the SecYEG apparatus and pass into the periplasm. In order to maintain pre-secretory proteins in an export-competent state, there are many factors that slow the folding of the pre-secretory protein in the cytoplasm. These include cytoplasmic chaperones, such as SecB, and the signal recognition particle, which bind the pre-secretory protein and direct it to the cytoplasmic membrane for export. Recently, evidence has been published that non-optimal codons in the signal sequence are important for a time-critical early event to allow the correct folding of pre-secretory proteins. This review details the recent developments in folding of the signal peptide and the pre-secretory protein.     

An Escherichia coli mutant defective in lipid export

Escherichia coli phospholipids and lipopolysaccharide, made on the inner surface of the inner membrane, are rapidly transported to the outer membrane by mechanisms that are not well characterized. We now report a temperature-sensitive mutant (WD2) with an A270T substitution in a trans-membrane region of the ABC transporter MsbA. As shown by (32)P(i) and (14)C-acetate labeling, export of all major lipids to the outer membrane is inhibited by approximately 90% in WD2 after 30 min at 44 degrees C. Transport of newly synthesized proteins is not impaired. Electron microscopy shows reduplicated inner membranes in WD2 at 44 degrees C, consistent with a key role for MsbA in lipid trafficking.     

Phosphorylation of Escherichia coli translation initiation factors by the bacteriophage T7 protein kinase.

The lytic coliphage T7 encodes a serine/threonine-specific protein kinase which supports viral reproduction under suboptimal growth conditions. Expression of the protein kinase in T7-infected Escherichia coli cells results in the phosphorylation of 30S ribosomal subunit protein S1, and initiation factors IF1, IF2, and IF3, as determined by high-resolution two-dimensional gel electrophoresis and specific immunoprecipitation analysis. Phosphorylation occurs either exclusively on threonine (IF1, IF3, S1) or on serine and threonine (IF2). There is no phosphorylation of these proteins in uninfected cells or in cells infected with T7 lacking the protein kinase function. Phosphorylation of the initiation factors coincides with the onset of T7 late protein synthesis, occurring 9-12-min postinfection. T7 late protein synthesis, otherwise inhibited in ColIb plasmid-containing cells, is specifically supported by expression of the protein kinase. These results provide the first evidence for the functional involvement of protein phosphorylation in the control of bacterial translation.     

In vivo study of engineered G-domain mutants of Escherichia coli translation initiation factor IF2

During the IF2-catalysed formation of the 30S initiation complex, the GTP requirement and Its subsequent hydrolysis during 70S complex formation are considered to be essential for translation initiation in Escherichia coli. In order to clarify the role of certain amino acid residues believed to be crucial for the GTP hydrolytic activity of E. coli IF2, we have introduced seven single amino acid substitutions into its GTP-binding site (Gly for Val-400; Thr for Pro-446; Gly, Glu, Gin for His-448; and Asn, Glu for Asp-501). These mutated IF2 proteins were expressed in vivo in physiological quantities and tested for their ability to maintain the growth of an E. coli strain from which the functional chromosomal copy of the infB gene has been deleted. Only one of the mutated proteins (Asp-501 to Giu) was able to sustain cell viability and several displayed a dominant negative effect. These results emphasize that the amino acid residues we substituted are essential for the iF2 functions and demonstrate the importance of GTP hydrolysis in translation initiation. These findings are discussed in relation to a previously proposed theoretical model for the IF2 G-domain.     

Solution structure of C-terminal Escherichia coli translation initiation factor IF2 by small-angle X-ray scattering

Initiation of protein synthesis in bacteria involves the combined action of three translation initiation factors, including translation initiation factor IF2. Structural knowledge of this bacterial protein is scarce. A fragment consisting of the four C-terminal domains of IF2 from Escherichia coli was expressed, purified, and characterized by small-angle X-ray scattering (SAXS), and from the SAXS data, a radius of gyration of 43 +/- 1 A and a maximum dimension of approximately 145 A were obtained for the molecule. Furthermore, the SAXS data revealed that E. coli IF2 in solution adopts a structure that is significantly different from the crystal structure of orthologous aIF5B from Methanobacterium thermoautotrophicum. This crystal structure constitutes the only atomic resolution structural knowledge of the full-length factor. Computer programs were applied to the SAXS data to provide an initial structural model for IF2 in solution. The low-resolution nature of SAXS prevents the elucidation of a complete and detailed structure, but the resulting model for C-terminal E. coli IF2 indicates important structural differences between the aIF5B crystal structure and IF2 in solution. The chalice-like structure with a highly exposed alpha-helical stretch observed for the aIF5B crystal structure was not found in the structural model of IF2 in solution, in which domain VI-2 is moved closer to the rest of the protein.     

Generation and characterization of functional mutants in the translation initiation factor IF1 of Escherichia coli.

Three protein factors IF1, IF2 and IF3 are involved in the initiation of translation in prokaryotes. No clear function has been assigned to the smallest of these three factors, IF1. Therefore, to investigate the role of this protein in the initiation process in Escherichia coli we have mutated the corresponding gene infA. Because IF1 is essential for cell viability and no mutant selection has so far been described, the infA gene in a plasmid was mutated by site-directed mutagenesis in a strain with a chromosomal infA+ gene, followed by deletion of this infA+ gene. Using this approach, the six arginine residues of IF1 were altered to leucine or aspartate. Another set of plasmid-encoded IF1 mutants with a cold-sensitive phenotype was collected using localized random mutagenesis. All mutants with a mutated infA gene on a plasmid and a deletion of the chromosomal infA copy were viable, except for an R65D alteration. Differences in growth phenotypes of the mutants were observed in both minimal and rich media. Some of the mutated infA genes were successfully recombined into the chromosome thereby replacing the wild-type infA+ allele. Several of these recombinants showed reduced growth rate and a partial cold-sensitive phenotype. This paper presents a collection of IF1 mutants designed for in vivo and in vitro studies on the function of IF1.     

Suppression of recJ mutations of Escherichia coli by mutations in translation initiation factor IF3.

We have isolated genetic suppressors of mutations in the recJ gene of Escherichia coli in a locus we term srjA. These srjA mutations cause partial to complete alleviation of the recombination and UV repair defects conferred by recJ153 and recJ154 mutations in a recBC sbcA genetic background. The srjA gene was mapped to 37.5 min on the E. coli chromosome. This chromosomal region from the srjA5 strain was cloned into a plasmid vector and was shown to confer recJ suppression in a dominant fashion. Mutational analysis of this plasmid mapped srjA to the infC gene encoding translation initiation factor 3 (IF3). Sequence analysis revealed that all three srjA alleles cause amino acid substitutions of IF3. Suppression of recJ was shown to be allele specific: recJ153 and recJ154 mutations were suppressible, but recJ77 and the insertion allele recJ284::Tn10 were not. In addition, growth medium-conditional lethality was observed for strains carrying srjA mutations with the nonsuppressible recJ alleles. When introduced into recJ+ strains, srjA mutations conferred hyperrecombinational and hyper-UVr phenotypes. An interesting implication of these genetic properties of srjA suppression is that IF3 may regulate the expression of recJ and perhaps other recombination genes and hence may regulate the recombinational capacity of the cell.     

Influence of mRNA determinants on translation initiation in Escherichia coli.

We have studied the classic initiation elements of mRNA sequence and structure to better understand their influence on translation initiation rates in Escherichia coli. Changes introduced in the initiation codon, the Shine and Dalgarno sequence, the spacing between those two elements, and in the secondary structures within initiation domains each change the rate of 30 S ternary complex formation. We measured these differences using extension inhibition analysis, a technique we have called "toeprinting". The rate of 30 S initiation complex formation in the absence of initiation factors agrees well with in vivo translation rates in some instances, although in others a regulatory role of initiation factors in 30 S complex formation is likely. Nucleotides 5' to the Shine and Dalgarno domain facilitate ternary complex formation.     

Function of initiation factor 1 in the binding and release of initiation factor 2 from ribosomal initiation complexes in Escherichia coli.

1. Studies on the function of initiation factor 1 (IF-1) in the formation of 30 S initiation complexes have been carried out. IF-1 appears to prevent the dissociation of initiation factor 2 (IF-2) from the 30 S initiation complex. The factor has no effect on either the initial binding of IF-2 nor does it increase the amount of IF-2 dependent fMet-tRNA and GTP bound to the 30 S subunit. Bound fMet-tRNA remains stable to sucrose gradient centrifugation even in the absence of IF-1. 2. It is postulated that the presence of IF-2 on the 30 S complex is necessary so that at the time of junction with the 50 S subunit to form a 70 S complex, the 70 S-dependent GTPase activity of IF-2 can hydrolyze GTP. This hydrolysis provides a means by which GTP can be removed to facilitate formation of a 70 S initiation complex active in peptidyl transfer. In support of this postulate, it was observed that 30 S initiation complexes formed in the absence of IF-1 could be depleted of their complexes were still able to accept 50 S subunits to form 70 S complexes which could still donate fMet-tRNA into peptide linkages. These results indicate that 30 S complexes lacking GTP do not require IF-2 for formation of active 70 S complexes. 3. IF-1, which is required to prevent dissociation of IF-2 from the 30 S initiation complex, is also required for release of IF-2 from ribosomes following 70 S initiation complex formation. The mechanisms of the release of IF-2 has been studied in greater detail. Evidence is presented which rules out the presence of a stable IF-2 GDP complex on the surface of the 70 S ribosome following GTP hydrolysis and of any exchange reactions between IF-1 and guanine nucleotides necessary for effecting the release of IF-2. IF-2 remains on the 70 S initiation complexes after release of guanine nucleotides and can be liberated solely by addition of IF-1.     

Escherichia coli 30S mutants lacking protein S20 are defective in translation initiation

The 30S ribosomal subunits derived from Escherichia coli TA114, a a temperature-sensitive mutant lacking ribosomal protein S20, were shown to be defective in two ways: (a) they have a reduced capacity for association with the 50S ribosomal subunit which results in the impairment of most of the functions requiring a coordinated interaction between the two subunits; (b) they are defective in functions which do not require their interaction with the large subunit (i.e., the formation of ternary complexes with aminocyl-tRNAs and templates, including the formation of 30S initiation complexes with fMet-tRNA and mRNA). The 30S (-S20) subunits seem to interact normally with both template and aminoacyl-tRNA individually, but appear to be impaired in the rate-limiting isomerization step leading to the formation of a codon-anticodon interaction in the P site.     

SecD and SecF facilitate protein export in Escherichia coli.

We show here that the rate of protein translocation in the bacterium Escherichia coli depends on the levels of the SecD and SecF proteins in the cell. Overexpression of SecD and SecF stimulates translocation in wild type cells and improves export of proteins with mutant signal sequences. Depletion of SecD and SecF from the cell greatly reduces but does not abolish protein translocation. A secDF::kan null mutant deleted for the genes encoding both proteins is cold-sensitive for growth and protein export, has a severe export defect at 37 degrees C and is barely viable. The phenotypes of a secD null mutant and a secF null mutant are identical to the secDF::kan double null mutant. These results partially resolve the conflict between genetic studies and results from in vitro translocation systems which do not require SecD and SecF for activity, affirm the importance of these proteins to the export process, and suggest that SecD and SecF function together to stimulate protein export in a role fundamentally different from other Sec proteins. Our results provide additional support for the notion that an early step in protein export is cold-sensitive.     

Photochemical cross-linking of translation initiation factor 3 to Escherichia coli 50S ribosomal subunits

Translation initiation factor 3 (IF-3) was bound noncovalently to Escherichia coli 50S ribosomal subunits. Irradiation of such complexes with near-ultraviolet light (greater than 285 nm) resulted in covalent attachment of initiation factor 3 to the 50S subunit. Photo-cross-linking attained its maximum level of 40% of that which was noncovalently bound after 90 min of irradiation. Cross-linking was abolished in the presence of either 0.5 M NH4C1 or 0.25 mM aurintricarboxylic acid, indicating that specific binding of initiation factor 3 to the ribosome was a prerequisite for subsequent covalent attachment. Further analysis showed that all the IF-3 was covalently bound to a small number of 50S subunit proteins. The major cross-linked proteins were identified as L2, L7/L12, L11, and L27 by immunochemical techniques. These results are discussed in light of the proposed mechanism for IF-3 function.