Modification of translation factor aIF5A from Sulfolobus solfataricus.

Eukaryotic eIF5A and its bacterial orthologue EF-P are translation elongation factors whose task is to rescue ribosomes from stalling during the synthesis of proteins bearing particular sequences such as polyproline stretches. Both proteins are characterized by unique post-translational modifications, hypusination and lysinylation, respectively, which are essential for their function. An orthologue is present in all Archaea but its function is poorly understood. Here, we show that aIF5A of the crenarchaeum Sulfolobus solfataricus is hypusinated and forms a stable complex with deoxyhypusine synthase, the first enzyme of the hypusination pathway. The recombinant enzyme is able to modify its substrate in vitro resulting in deoxyhypusinated aIF5A. Moreover, with the aim to identify the enzyme involved in the second modification step, i.e. hypusination, a set of proteins interacting with aIF5A was identified.

Initiation factor IF 2 binds to the alpha-sarcin loop and helix 89 of Escherichia coli 23S ribosomal RNA.

During initiation of protein synthesis in bacteria, translation initiation factor IF2 is responsible for the recognition of the initiator tRNA (fMet-tRNA). To perform this function, IF2 binds to the ribosome interacting with both 30S and 50S ribosomal subunits. Here we report the topographical localization of translation initiation factor IF2 on the 70S ribosome determined by base-specific chemical probing. Our results indicate that IF2 specifically protects from chemical modification two sites in domain V of 23S rRNA, namely A2476 and A2478, and residues around position 2660 in domain VI, the so-called sarcin-ricin loop. These footprints are generated by IF2 regardless of the presence of fMet-tRNA, GTP, mRNA, and IF1. IF2 causes no specific protection of 16S rRNA. We observe a decreased reactivity of residues A1418 and A1483, which is an indication that the initiation factor has a tightening effect on the association of ribosomal subunits. This result, confirmed by sucrose density gradient analysis, seems to be a universally conserved property of IF2.

Translation during cold adaptation does not involve mRNA-rRNA base pairing through the downstream box.

The downstream box (DB) has been proposed to enhance translation of several mRNAs and to be a key element controlling the expression of cold-shocked mRNAs. However, the proposal that the DB exerts its effects through a base pairing interaction with the complementary anti-downstream box (antiDB) sequence (nt 1469-1483) located in the penultimate stem (helix 44) of 16S rRNA remains controversial. The existence of this interaction during initiation of protein synthesis under cold-shock conditions has been investigated in the present work using an Escherichia coli strain whose ribosomes lack the potential to base pair with mRNA because of a 12 bp inversion of the antiDB sequence in helix 44. Our results show that this strain is capable of cold acclimation, withstands cold shock, and its ribosomes translate mRNAs that contain or lack DB sequences with similar efficiency, comparable to that of the wild type. The structure of helix 44 in 30S ribosomal subunits from cells grown at 37 degrees C and from cells subjected to cold shock was also analyzed by binding a 32P-labeled oligonucleotide complementary to the antiDB region and by chemical probing with DMS and kethoxal. Both approaches clearly indicate that this region is in a double-stranded conformation and therefore not available for base pairing with mRNA.

Antagonistic involvement of FIS and H-NS proteins in the transcriptional control of hns expression.

Gel shift and DNase I footprinting experiments showed that Escherichia coli FIS (factor for inversion stimulation) protein binds to at least seven sites in the promoter region of hns. These sites extend from -282 to +25 with two sites, closely flanking the DNA bend located at -150 from the transcriptional startpoint, partly overlapping the H-NS binding sites involved in the transcriptional autorepression of hns. The interplay between FIS, H-NS and the hns promoter region were studied by examining the effects of FIS and H-NS on in vitro transcription of hns-cat fusions, as well as looking at the effect of FIS on preformed complexes containing H-NS and a DNA fragment derived from the hns promoter region. Taken together, our data suggest that in the cell, FIS and H-NS interact with the promoter region of hns and influence their respective interactions (possibly competing for the same binding site), eliciting antagonistic effects so that an interplay between these proteins might contribute to the transcriptional control of hns.

Late events in translation initiation. Adjustment of fMet-tRNA in the ribosomal P-site.

The requirements for the adjustment of fMet-tRNA in the ribosomal P-site have been analyzed by studying the formation of fMet-puromycin in a Bacillus stearothermophilus system. The binding of fMet-tRNA to the 30 S ribosomal subunit is not drastically affected by the omission of GTP, mRNA, mRNA and GTP, or by replacing GTP with GTP analogues. The adjustment of fMet-tRNA in the P site has stricter requirements and fMet-puromycin formation occurred at its maximum rate and extent when fMet-tRNA was bound to 30 S subunits programmed with the AUG triplet or with an mRNA in the presence of GTP. Neither GTP nor the mRNA, however, were found to be essential. Omission of GTP caused only a slight reduction in the rate of fMet-puromycin formation without a significant change of the activation energy, while omission of the template resulted in a requirement for a higher activation energy. In the absence of both GTP and template, however, essentially no fMet-puromycin was formed, indicating that these components cooperate in the adjustment of the initiator tRNA in the P-site. The contribution of various structural elements of the mRNA in determining this adjustment was investigated. It was found that the codon-anticodon interaction and the filling of the ribosomal mRNA channel with a polyribonucleotide are necessary (but not sufficient singly) for the correct orientation of the initiator tRNA in the absence of GTP. The nature of the initiation triplet and the occurrence and/or the strength of the Shine-Dalgarno interaction were also found to contribute to the orientation of the bound fMet-tRNA.

From stand-by to decoding site. Adjustment of the mRNA on the 30S ribosomal subunit under the influence of the initiation factors.

The hypothesis of an adjustment of the mRNA in its ribosomal channel under the influence of the initiation factors has been tested by site-directed crosslinking experiments. Complexes containing 30S subunits with bound mRNA having 4-thio-uracil at specific positions were prepared in the presence or absence of initiation factors and/or fMet-tRNA and subjected to UV irradiation to obtain specific crosslinks of the radioactively labeled mRNA with bases of the 16S rRNA and with ribosomal proteins. The subsequent identification of the specific sites of both mRNA and rRNA and individual ribosomal proteins involved in the crosslinking, obtained under different conditions of complex formation, provide direct evidence for the occurrence of a partial relocation of the mRNA on the 30S ribosomal subunits under the influence of the factors. The nature of this mRNA relocation is compatible with our previous proposal of a shift of the template from an initial ribosomal "stand-by site" to a second site closer to that occupied when the initiation triplet of the mRNA is decoded in the P-site.

Purification procedure for bacterial translational initiation factors IF2 and IF3.

In bacteria the initiation of protein synthesis is a complex phenomenon in which specific proteins, termed initiation factors (IFs) IF1, IF2, and IF3, are involved. Notwithstanding the progress made in understanding their functions, the precise molecular mechanisms of action of these factors remain somewhat obscure. One reason for this lack of knowledge is the difficulty involved in purifying sufficient quantities of these proteins. We have developed a new procedure for purification of IFs from recombinant Escherichia coli strains producing high levels of E. coli IF3 and Bacillus stearothermophilus IF2. This new procedure is quicker than previous methods, easily scaled up to large volumes, and can be used, with only minor modifications, for different IFs. This new purification method consists essentially of one chromatographic (FPLC) separation on an ion-exchange resin (S-Sepharose fast-flow or Mono-S HR). Using this procedure we have been able to obtain chromatographically pure and biologically active preparations of both IF2 and IF3.

Translation of mRNAs with degenerate initiation triplet AUU displays high initiation factor 2 dependence and is subject to initiation factor 3 repression.

The influence of the rare initiation triplet AUU on mRNA translation was investigated by comparing the activity of two pairs of model mRNAs that differ in the length of Shine-Dalgarno and spacer sequences. Irrespective of the initiation triplet (AUG or AUU), all mRNAs had similar template activity in vitro, but translation of AUU mRNAs depended more on initiation factor (IF) 2 and less on IF3 than that of AUG mRNAs. Increasing the IF3/ribosome ratio from 2 to 10 progressively inhibited the AUU mRNAs and abolished their capacity to compete for translating ribosomes with other mRNAs but did not affect activity of the AUG mRNAs. The effects induced by IF3 are from its different influence on on- and off-rates of the transition 30S preinitiation complex<==>30S initiation complex; depending on the nature of the initiation triplet (AUG or AUU) of the mRNA, IF3 shifts the position of equilibrium toward binding or dissociation of fMet-tRNA, respectively. Stimulation of fMet-tRNA binding and dissociation yields superimposable IF3 titration curves that saturate at an IF3/30S ratio of approximately 1, indicating that the data are from the interaction of one molecule of IF3 with the same 30S binding site. Both effects are either lost or strongly reduced with 30S mutants defective in IF3 binding. Translational repression of AUU mRNAs by IF3 is from the factor-dependent dissociation of fMet-tRNA from 30S subunits, which becomes relevant when excess IF3 interferes with the formation of 70S initiation complex, presumably by interacting with 50S subunit.

Proteolysis of Bacillus stearothermophilus IF2 and specific protection by fMet-tRNA.

Translation initiation factor IF2 from Bacillus stearothermophilus (741 amino acids, Mr 82,043) was subjected to trypsinolysis alone or in the presence of fMet-tRNA. The initiator tRNA was found to protect very efficiently the Arg308-Ala309 bond within the GTP binding site of IF2 and, more weakly, three bonds (Lys146-Gln147, Lys154-Glu155 and Arg519-Ser520). The first two are located at the border between the non-conserved, dispensable (for translation) N-terminal portion and the conserved G-domain of the protein, the third is located at the border between the G- and C-domains. Since IF2 is known to interact with fMet-tRNA through its protease-resistant C- (carboxyl terminus) domain, the observed protection suggests that, upon binding of fMet-tRNA, long-distance tertiary interactions between the IF2 domains may take place.

Lethal overproduction of the Escherichia coli nucleoid protein H-NS: ultramicroscopic and molecular autopsy.

The Escherichia coli hns gene, which encodes the nucleoid protein H-NS, was deprived of its natural promoter and placed under the control of the inducible lambda PL promoter. An hns mutant yielding a protein (H-NS delta 12) with a deletion of four amino acids (Gly112-Arg-Thr-Pro115) was also obtained. Overproduction of wild-type (wt) H-NS, but not of H-NS delta 12, resulted in a drastic loss of cell viability. The molecular events and the morphological alterations eventually leading to cell death were investigated. A strong and nearly immediate inhibition of both RNA and protein synthesis were among the main effects of overproduction of wt H-NS, while synthesis of DNA and cell wall material was inhibited to a lesser extent and at a later time. Upon cryofixation of the cells, part of the overproduced protein was found in inclusion bodies, while the rest was localized by immunoelectron microscopy to the nucleoids. The nucleoids appeared condensed in cells expressing both forms of H-NS, but the morphological alterations were particularly dramatic in those overproducing wt H-NS; their nucleoids appeared very dense, compact and almost perfectly spherical. These results provide direct evidence for involvement of H-NS in control of the organization and compaction of the bacterial nucleoid in vivo and suggest that it may function, either directly or indirectly, as transcriptional repressor and translational inhibitor.

Identification of a cold shock transcriptional enhancer of the Escherichia coli gene encoding nucleoid protein H-NS.

The hns (27 min) gene encoding the 15.4-kDa nucleoid protein H-NS was shown to belong to the cold shock regulon of Escherichia coli, its expression being enhanced 3- to 4-fold during the growth lag that follows a shift from 37 degrees C to 10 degrees C. A 110-base-pair (bp) DNA fragment containing the promoter of hns fused to a promoterless cat gene (hns-cat fusion) conferred a similar cold shock response to the expression of chloramphenicol acetyltransferase (CAT) activity in vivo and in coupled transcription-translation systems prepared with extracts of cold-shocked cells. Extracts of the same cells produce a specific gel shift of the 110-bp DNA fragment and this fragment, immobilized on a solid support, specifically retains a single 7-kDa protein present only in cold-shocked cells that was found to be identical to F10.6 (CS7.4), the product of cspA. This purified protein, which is homologous to human DNA-binding protein YB-1, recognizes some feature of the 110-bp promoter region of hns and acts as a cold shock transcriptional activator of this gene since it stimulates the expression of CAT activity and of cat transcription in in vitro systems programmed with plasmid DNA carrying the hns-cat fusion.

Ribosome-independent GTPase activity of translation initiation factor IF2 and of its G-domain.

In the absence of ribosomes, Bacillus stearothermophilus translation initiation factor IF2 (Mr = 82 kDa) and its GTP-binding domain (i.e. the G-domain, Mr = 41 kDa) promote barely detectable hydrolysis of GTP. Upon addition of some aliphatic alcohols, however, the rate of nucleotide cleavage is substantially increased with both IF2 and G-domain, the highest stimulation being observed with 20% (v/v) ethanol. Under these conditions, the rates of ribosome-independent GTP hydrolysis with both IF2 and G-domain are approximately 30-fold lower than the corresponding rates obtained in the presence of ribosomes, while the Km for GTP is approximately the same in all cases. These results indicate that, as with the other two prokaryotic G proteins involved in translation (i.e. elongation factors EF-Tu and EF-G), also in the case of IF2, the GTPase catalytic center resides in the factor and, more specifically, in its G-domain.

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.

Escherichia coli DNA-binding protein H-NS is localized in the nucleoid.

Electron microscope localization of the 15.4-kDa DNA-binding protein H-NS was carried out in Escherichia coli cells subjected to cryosubstitution followed by immuno-labelling with the protein A/gold technique. Three types of E. coli cells were used: (1) "normal" cells growing exponentially at 37 degrees C; (2) "cold-shocked" cells two hours after the shift from 37 degrees C to 10 degrees C; and (3) cells in which an expression vector had been induced to overproduce H-NS. The results clearly indicate that in all 3 cases, the vast majority of the molecules reacting with anti-H-NS antibodies are localized within the nucleoid and at the border between the nucleoid and the ribosome-rich cytoplasm, which supports the premise that H-NS is implicated in the condensation of the nucleoid.

Proteolysis of Bacillus stearothermophilus IF2 and specific protection by GTP.

Translation initiation factor IF2 from Bacillus stearothermophilus (741 amino acids, Mr = 82,043) was subjected to trypsinolysis alone or in the presence of GTP. Following electroblotting and automated amino acid sequencing of the resulting peptides, the location and the sequential order of the main cleavage sites were identified. Trypsinolysis of IF2 ultimately generates two compact domains: a 24.5 kDa C-terminal fragment and a 40 kDa G-fragment which is obtained only in the presence of GTP which strongly protects a cleavage site within the GTP binding domain.

Site-directed mutagenesis of Escherichia coli translation initiation factor IF1. Identification of the amino acid involved in its ribosomal binding and recycling.

Starting from a synthetic modular gene (infA) encoding Escherichia coli translation initiation factor IF1, we have constructed mutants in which amino acids are deleted from the carboxyl terminus or in which His29 or His34 are replaced by Tyr or Asp residues. The mutant proteins were overproduced, purified and tested in vitro for their properties in several partial reactions of the translation initiation pathway and for their capacity to stimulate MS2 RNA-dependent protein synthesis. The results allow for the conclusion that: (i) Arg69 is part of the 30S ribosomal subunit binding site of IF1 and its deletion results in the substantial loss of all IF1 function; (ii) neither one of its two histidines is essential for the binding of IF1 to the 30S ribosomal subunit, for the stimulation of fMet-tRNA binding to 30S or 70S ribosomal particles or for MS2 RNA-dependent protein synthesis; but (iii) His29 is involved in the 50S subunit-induced ejection of IF1 from the 30S ribosomal subunit.

Characterization of the structural genes for the DNA-binding protein H-NS in Enterobacteriaceae.

The promoter region of Escherichia coli hns, the structural gene for the DNA-binding protein H-NS, has been identified by use of a promoter search vector and the in vivo transcriptional start point by primer extension analysis. The homologous hns genes of two other Enterobacteriaceae, Proteus vulgaris and Serratia marcescens, were identified by heterologous hybridization with a DNA probe derived from E. coli hns, cloned and sequenced. Taking into account only the invariant nucleotides and amino acids, the homology of H-NS among the three organisms was found to be greater than 70% at the DNA level and greater than 75% at the protein level. The three hns genes were also found to have nearly identical transcriptional and translational signals.

Proteins from the prokaryotic nucleoid: primary and quaternary structure of the 15-kD Escherichia coli DNA binding protein H-NS.

The primary sequence of H-NS (136 amino acid residues, Mr = 15,402), an abundant Escherichia coli DNA-binding protein, has been elucidated and its quaternary structure has been investigated by protein-protein cross-linking reactions. It was found that H-NS exists predominantly as a dimer, even at very low concentrations, but may form tetramers at higher concentrations and that the protein-protein interaction responsible for the dimerization is chiefly hydrophobic.