Two translational initiation sites in the infB gene are used to express initiation factor IF2 alpha and IF2 beta in Escherichia coli.

The gene infB codes for the two forms of translational initiation factor IF2: IF2 alpha (97 300 daltons) and IF2 beta (79 700 daltons). To determine whether the two forms differ at their N terminus, purified IF2 alpha and IF2 beta were subjected to 11 or more steps of Edman degradation. The N-terminal amino acid sequences are completely different, but match perfectly the DNA sequences at the beginning of the infB open reading frame and an in-phase region 471 bp downstream. A fusion was constructed between the proximal half of the infB gene and the lacZ gene lacking the region coding for the first eight amino acids. The fused gene expresses two products of 170 000 and 150 000 daltons, corresponding to the fused proteins IF2 alpha-beta-galactosidase and IF2 beta-beta-galactosidase, which confirms in vivo that the IF2 forms differ at their N terminus. A deletion of the 5'-non-translated region of the fused gene, including the Shine/Dalgarno ribosomal binding site, results in the expression of IF2 beta-beta-galactosidase but not IF2 alpha-beta-galactosidase. This strongly suggests that IF2 beta results from independent translation rather than from a precise proteolytic cleavage of IF2 alpha. Further evidence for initiation of protein synthesis at the putative IF2 alpha and IF2 beta start sites was sought by using an in vitro dipeptide synthesis assay. A DNA fragment containing the entire infB gene was cloned into three plasmid vectors and the resulting recombinant DNAs were used as templates in assays containing fMet-tRNA and various labelled aminoacyl-tRNAs.(ABSTRACT TRUNCATED AT 250 WORDS)     

Characterization of the translational start site for IF2 beta, a short form of Escherichia coli initiation factor IF2

The gene for initiation factor IF2, infB, represents one of the few examples in Escherichia coli of genes encoding two protein products in vivo. In a previous work, our group showed that both forms of IF2 (alpha and beta) are closely related and may arise from two independent translational events on infB mRNA. Unambiguous mapping and rigorous determination of the nature of the initiation triplet for IF2 beta, the smaller form of IF2, is critical for future mutagenesis of this codon, required for investigating the biological importance of both IF2 alpha and IF2 beta. Three types of experiments were carried out. First, a 77-bp deletion was created at the beginning of the structural gene leading to premature termination of IF2 alpha synthesis. Under these conditions, IF2 beta is still formed. Second, various Bal31 digests of infB containing the 77-bp deletion were fused to lacZ. Any synthesis of a fused protein with beta-galactosidase activity should reflect the occurrence of an initiation event on the messenger corresponding to this DNA segment. It was consequently possible to locate the IF2 beta initiation site within an 18-base region containing an in-phase GUG codon. Third, to avoid any artefactual reinitiation event possibly occurring under our experimental conditions, we fused to lacZ an infB fragment devoid of IF2 alpha start sequences but containing genetic information for this 18-base region. A hybrid protein with beta-galactosidase activity was synthesized. Moreover, its NH2-terminal amino acid sequence coincided with that of IF2 beta, demonstrating that GUG, located 471 bases downstream from the IF2 alpha external start codon, is the internal start codon for the shorter form of IF2.     

Discrimination by Escherichia coli initiation factor IF3 against initiation on non-canonical codons relies on complementarity rules.

Translation initiation factor IF3, one of three factors specifically required for translation initiation in Escherichia coli, inhibits initiation on any codon other than the three canonical initiation codons, AUG, GUG, or UUG. This discrimination against initiation on non-canonical codons could be due to either direct recognition of the two last bases of the codon and their cognate bases on the anticodon or to some ability to "feel" codon-anticodon complementarity. To investigate the importance of codon-anticodon complementarity in the discriminatory role of IF3, we constructed a derivative of tRNALeuthat has all the known characteristics of an initiator tRNA except the CAU anticodon. This tRNA is efficiently formylated by methionyl-tRNAfMettransformylase and charged by leucyl-tRNA synthetase irrespective of the sequence of its anticodon. These initiator tRNALeuderivatives (called tRNALI) allow initiation at all the non-canonical codons tested, provided that the complementarity between the codon and the anticodon of the initiator tRNALeuis respected. More remarkably, the discrimination by IF3, normally observed with non-canonical codons, is neutralised if a tRNALIcarrying a complementary anticodon is used for initiation. This suggests that IF3 somehow recognises codon-anticodon complementarity, at least at the second and third position of the codon, rather than some specific bases in either the codon or the anticodon.     

Tandem translation of E. coli initiation factor IF2 beta: purification and characterization in vitro of two active forms.

Two forms of E. coli initiation factor IF2, IF2 alpha and IF2 beta, have been known for several years. Both forms are products of the gene infB with translational initiation at codon 1 (AUG) and codon 158 (GUG) in the same reading frame. In this work we demonstrate that IF2 beta exists in two forms, IF2 beta and IF2 beta' with initiation codons 158 (GUG) and 165 (AUG) and molecular masses of 79.7 kDa and 78.8 kDa respectively. We have recently described a fast purification method for IF2 alpha, using an FPLC procedure consisting of ion-exchange liquid chromatography on Q Sepharose HP, Mono Q and Mono S. After the Mono Q step, an apparently homogeneous IF2 beta was observed when analyzed by SDS-PAGE. However the chromatography on Mono S results in the elution of two peaks containing IF2 beta. The N-terminal amino acid sequence of the two proteins identified the first peak to be IF2 beta and the second as a protein which we term IF2 beta' starting seven residues downstream at the AUG codon 165. The activity in vitro of the two purified forms of IF2 beta was tested by measuring the stimulation of binding of the initiator fMet-tRNA(fMet) to 70S ribosomes in the presence of GTP and poly(A,U,G) as messenger-RNA. In this assay no difference in activity is detected.     

A severely truncated form of translational initiation factor 2 supports growth of Escherichia coli.

We have constructed strains carrying null mutations in the chromosomal copy of the gene for translational initiation factor (IF) 2 (infB). A functional copy of the infB gene is supplied in trans by a thermosensitive lysogenic lambda phage integrated at att lambda. These strains enabled us to test in vivo the importance of different structural elements of IF2 expressed from genetically engineered plasmid constructs. We found that, as expected, the gene for IF2 is essential. However, a protein consisting of the C-terminal 55,000 Mr fragment of the wild-type IF2 protein is sufficient to allow growth when supplied in excess. This result suggests that the catalytic properties are localized in the C-terminal half of the protein, which includes the G-domain, and that this fragment is sufficient to complement the IF2 deficiency in the infB deletion strain.     

The unusual translational initiation codon AUU limits the expression of the infC (initiation factor IF3) gene of Escherichia coli

Summary The expression of infC, the structural gene for translational initiation factor IF3, has been studied in different constructs under the control of the P_L and tac promoters. The amount of synthesized IF3 has been determined by a quantitative functional test and the levels of IF3-specific mRNA have been estimated. The synthesis of IF3 is strongly enhanced when the unusual AUU initiation codon is changed to AUG by site-directed mutagenesis. Removal of the sequence upstream from the start codon including most of the Shine-Dalgarno sequence, as well as part of a 10 bp region with potential complementarity to an internal region of the 16S rRNA, which is unique to the IF3 mRNA, reduced but did not completely abolish the high expression of infC obtained after introduction of the AUG initiation codon. The level of IF3 mRNA was found to be positively influenced by the presence of the rplT gene in the plasmid downstream from the infC gene. In vivo accumulation of a large excess of IF3, obtained when the infC gene was placed under the control of an incompletely repressed tac promoter, was not accompanied by any noticeable adverse phenotype.     

Structure-function analysis of Escherichia coli translation initiation factor IF3: tyrosine 107 and lysine 110 are required for ribosome binding.

Translation initiation factor IF3 is required for peptide chain initiation in Escherichia coli. IF3 binds directly to 30S ribosomal subunits ensuring a constant supply of free 30S subunits for initiation complex formation, participates in the kinetic selection of the correct initiator region of mRNA, and destabilizes initiation complexes containing noninitiator tRNAs. The roles that tyrosine 107 and lysine 110 play in IF3 function were examined by site-directed mutagenesis. Tyrosine 107 was changed to either phenylalanine (Y107F) or leucine (Y107L), and lysine 110 was converted to either arginine (K110R) or leucine (K110L). These single amino acid changes resulted in a reduced affinity of IF3 for 30S subunits. Association equilibrium constants (M-1) for 30S subunit binding were as follows: wild-type, 7.8 x 10(7); Y107F, 4.1 x 10(7); Y107L, 1 x 10(7); K110R, 5.1 x 10(6); K110L, < 1 x 10(2). The mutant IF3s were similarly impaired in their abilities to specifically select initiation complexes containing tRNA(fMet). Toeprint analysis indicated that 5-fold more Y107L or K110R protein was required for proper initiator tRNA selection. K110L protein was unable to mediate this selection even at concentrations up to 10-fold higher than wild type. The results indicate that tyrosine 107 and lysine 110 are critical components of the ribosome binding domain of IF3 and, furthermore, that dissociation of complexes containing noninitiator tRNAs requires prior binding of IF3 to the ribosomes.     

X-ray crystallography shows that translational initiation factor IF3 consists of two compact alpha/beta domains linked by an alpha-helix.

The structures of the two domains of translational initiation factor IF3 from Bacillus stearothermophilus have been solved by X-ray crystallography using single wavelength anomalous scattering and multiwavelength anomalous diffraction. Each of the two domains has an alpha/beta topology, with an exposed beta-sheet that is reminiscent of several ribosomal and other RNA binding proteins. An alpha-helix that protrudes out from the body of the N-terminal domain towards the C-terminal domain suggests that IF3 consists of two RNA binding domains connected by an alpha-helix and that it may bridge two regions of the ribosome. This represents the first high resolution structural information on a translational initiation factor.     

Molecular dissection of translation initiation factor IF2. Evidence for two structural and functional domains

By means of limited proteolysis of Bacillus stearothermophilus initiation factor IF2 and genetic manipulation of its structural gene, infB, we have been able to produce (or hyperproduce) and purify two polypeptide fragments corresponding to two structurally and functionally separate domains of the protein. The first is the G-domain (approximately 41 kDa), which makes up the central part of the molecule and contains the conserved structural elements found in all GTP/GDP-binding sites of G-proteins. This domain is resistant to proteolysis in the presence of GTP or GDP, retains the capacity to interact with the 50 S subunit, binds weakly to the 30 S subunit, and displays ribosome-dependent GTPase activity with an approximately 2-fold higher Km for GTP and the same Vmax as compared with intact IF2. The second is the C-domain (approximately 24 kDa), which corresponds to the COOH-terminal part of IF2 and constitutes an extraordinarily compact domain containing the fMet-tRNA binding site of IF2. In spite of its negligible affinity for the ribosomes, the C-domain weakly stimulates the ribosomal binding of fMet-tRNA, presumably by affecting the conformation of the initiator tRNA molecule.     

Chemical synthesis and in vivo hyperexpression of a modular gene coding for Escherichia coli translational initiation factor IF1

Summary An artificial gene encoding the Escherichia coli translational initiation factor IF1 was synthesized based on the primary structure (71 amino acid residues) of the protein. Codons for individual amino acids were selected on the basis of the preferred codon usage found in the structural genes for the initiation factor IF2 of E. coli and Bacillus stearothermophilus, both of which can be expressed at high levels in E. coli cells. We gave the IF1 gene a modular structure by introducing specific restriction enzyme sites into the sequence, resulting in units of three to ten codons. This was conceived to facilitate site-directed mutagenesis of the gene and thus to obtain IF1 with specific amino acid alterations at desired positions. The IF1 gene was assembled by shot-gun ligation of 9 synthetic oligodeoxyri-bonucleotides ranging in size from 31 to 65 nucleotides and cloned into an expression vector to place the gene under the control of an inducible promoter. Upon induction, E. coli cells harbouring the artificial gene were found to produce large amounts (60 mg/100 g cells) of a protein indistinguishable from natural IF1 in both chemecal and biological properties.     

Interaction of bovine mitochondrial ribosomes with Escherichia coli initiation factor 3 (IF3)

Mammalian mitochondrial ribosomes are distinguished from their bacterial and eukaryotic-cytoplasmic counterparts, as well as from mitochondrial ribosomes of lower eukaryotes, by their physical and chemical properties and their high protein content. However, they do share more functional homologies with bacterial ribosomes than with cytoplasmic ribosomes. To search for possible homologies between mammalian mitochondrial ribosomes and bacterial ribosomes at the level of initiation factor binding sites, we studied the interaction of Escherichia coli initiation factor 3 (IF3) with bovine mitochondrial ribosomes. Bacterial IF3 was found to bind to the small subunit of bovine mitochondrial ribosomes with an affinity of the same order of magnitude as that for bacterial ribosomes, suggesting that most of the functional groups contributing to the IF3 binding site in bacterial ribosomes are conserved in mitochondrial ribosomes. Increasing ionic strength affects binding to both ribosomes similarly and suggests a large electrostatic contribution to the reaction. Furthermore, bacterial IF3 inhibits the Mg2+-dependent association of mitochondrial ribosomal subunits, suggesting that the bacterial IF3 binds to mitochondrial small subunits in a functional way.     

Translation initiation factor IF1 is essential for cell viability in Escherichia coli.

Translation initiation factor IF1 is a highly conserved element of the prokaryotic translational apparatus. It has been demonstrated earlier that the factor stimulates in vitro the initiation phase of protein synthesis. However, no mutation in its gene, infA, has been identified, and a role for IF1 in translation has not been demonstrated in vivo. To elucidate the function of IF1 and determine if the protein is essential for cell growth, the chromosomal copy of infA was disrupted. Cell viability is maintained only when infA is expressed in trans from a plasmid, thereby demonstrating that IF1 is essential for cell growth in Escherichia coli. Cells depleted of IF1 exhibit few polysomes, suggesting that IF1 functions in the initiation phase of protein synthesis.     

Metabolic stability of the two forms of initiation factor IF-3 in Escherichia coli during the growth cycle.

Possible alteration in the ratio of the long and short forms of initiation factor IF-3 (FEBS Lett. 79, 264-275, 1977) during the growth cycle of Escherichia coli was examined. The ratio was found to remain unchanged between the exponential and stationary growth phases. Contrary to an earlier report (Eur. J. Biochem. 29, 319-325, 1972), the total amount of IF-3 relative to the ribosome content in stationary phase cells was essentially the same as in midlogarithmic phase cells. The activity of IF-3, assayed after its separation from other initiation factors by chromatography, was also the same in extracts from midlogarithmic and stationary phase cells. The data show that in Escherichia coli the ratio of IF-3/ribosome is maintained constant. The ribosomes themselves have been shown to retain virtually full activity in vitro during this transition indicating that growth-cycle-dependent biochemical modifications of the ribosome do not affect its protein synthetic capacity per se.     

Structural and functional domains of E coli initiation factor IF2.

Initiation of translation in prokaryotes requires the participation of at least three soluble proteins: the initiation factors IF1, IF2 and IF3. Initiation factor 2, which is one of the largest proteins involved in translation (97.3 kDa) has been shown to stimulate in vitro the binding of fMet-tRNA(fMet) to the 30S ribosomal subunit. After formation of 70S translation initiation complex, IF2 is believed to participate in GTP hydrolysis, thereby promoting its own release. Here we review evidence which indicates the functional importance of the different structural domains of IF2, emphasizing new information obtained by in vivo experiments.     

Superexpression and fast purification of E coli initiation factor IF2.

For the production of large quantities of E coli initiation factor IF2 we have constructed an improved overexpression system. The gene infB was cloned into the thermo-inducible runaway plasmid pCP40 [1] and subsequently transformed into the E coli strain C600[pcI857]. In this system the expression of infB is under the control of the strong promoter lambda PL and the cells carry the plasmid pcI857, which contains a thermosensible lambda cI repressor. Overexpression of IF2, which is approximately 30 times higher than the expression in wild-type-cells, is induced at 42 degrees C and continues for 2 h at 37 degrees C. From these cells pure and active IF2 was obtained using a novel 3-step FPLC-procedure consisting of ion-exchange liquid chromatography on Q-sepharose HP, MonoQ and MonoS. In approximately 8 h, 5 mg of pure and active IF2 can be obtained from 10 g overproducing cells. This corresponds to 5 mg of IF2 per litre of medium. The purification was monitored by Western immunoblotting and the activity of the purified factor was tested by measuring the stimulation of binding of the initiator fMet-tRNA(Met)f to 70S ribosomes in the presence of GTP and poly(A,U,G) as messenger RNA. Compared with previous methods our purification procedure avoids the use of materials such as DEAE-cellulose and phosphocellulose which have relatively poor flow rates. In addition to the higher flow capacity of Q-sepharose HP, this new matrix can be loaded with an S30 supernatant.(ABSTRACT TRUNCATED AT 250 WORDS)     

Both CheA and CheW are required for reconstitution of chemotactic signaling in Escherichia coli.

If cells of Escherichia coli deleted for genes that specify transducers and all known cytoplasmic chemotaxis proteins are reconstituted with CheA, CheW, and CheY, they spin their flagella alternately clockwise and counterclockwise. If the aspartate receptor also is present, clockwise rotation is suppressed upon addition of aspartate. If either CheA or CheW is absent, the fraction of time that the flagella spin clockwise is reduced and responses to aspartate do not occur.     

Expression and purification of the subunits of human translational initiation factor 2 (eIF2): phosphorylation of eIF2 alpha and beta

Eukaryotic initiation factor 2 (eIF2) is a GDP-binding protein with three subunits: alpha, beta, and gamma. It delivers initiator tRNA (Met-tRNAi) to 40S ribosomes in a GTP-dependent manner. The factor regulates the translation of messenger RNAs through the phosphorylation of serine 51 residue in the small or alpha-subunit of eIF2 (eIF2alpha) and modulation of its interaction with a rate-limiting heteropentameric protein eIF2B. To understand the structural, functional, and regulatory roles of each of these subunits in the various activities of phosphorylated and unphosphorylated eIF2, such, as its ability to interact with GTP, Met-tRNAi, 40S ribosomes and with various proteins, we have for the first time over expressed all the three subunits of human eIF2 independently, and, also together in Sf9 cells using pFast Bac HT vector of baculovirus expression system. The expression of all subunits increased with increase in infection time up to 72 h. We have also over expressed three mutant forms of eIF2alpha viz, S51A, S51D, and S48A in which the serine at 51 or 48 position is replaced by an alanine or aspartic acid with 6x histidine tag at the N-terminus. Further, any of the two subunits or all the three subunits of eIF2 were coexpressed by multiple infection of cells with recombinant viruses. Purified alpha (wt and mutants) and beta subunits were found suitable to serve as substrates for different kinases. The recombinant subunits of eIF2alpha and beta-subunits were also phosphorylated in cultured insect cells. Phosphorylation of eIF2alpha in vitro was not significantly different in the presence and absence of the other subunits.