Investigation of the regulatory function of archaeal ribosomal protein L4.

Ribosomal protein L4 is a regulator of protein synthesis in the Escherichia coli S10 operon, which contains genes of 11 ribosomal proteins. In this work, we have investigated regulatory functions of ribosomal protein L4 of the thermophilic archaea Methanococcus jannaschii. The S10-like operon from M. jannaschii encodes not 11, but only five ribosomal proteins (L3, L4, L23, L2, S19), and the first protein is L3 instead of S10. We have shown that MjaL4 and its mutant form lacking an elongated loop specifically inhibit expression of the first gene of the S10-like operon from the same organism in a coupled transcription-translation system in vitro. By deletion analysis, an L4-binding regulatory site has been found on MjaL3 mRNA, and a fragment of mRNA with length of 40 nucleotides has been prepared that is necessary and sufficient for the specific interaction with the MjaL4 protein.

Mutant forms of Escherichia coli protein L25 unable to bind to 5S rRNA are incorporated efficiently into the ribosome in vivo.

5S rRNA-binding ribosomal proteins of the L25 family are an evolutional acquisition of bacteria. Earlier we showed that (i) single replacements in the RNA-binding module of the protein of this family result in destabilization or complete impossibility to form a complex with 5S rRNA in vitro; (ii) ΔL25 ribosomes of Escherichia coli are less efficient in protein synthesis in vivo than the control ribosomes. In the present work, the efficiency of incorporation of the E. coli protein L25 with mutations in the 5S rRNA-binding region into the ribosome in vivo was studied. It was found that the mutations in L25 that abolish its ability to form the complex with free 5S rRNA do not prevent its correct and efficient incorporation into the ribosome. This is supported by the fact that even the presence of a very weakly retained mutant form of the protein in the ribosome has a positive effect on the activity of the translational machinery in vivo. All this suggests the existence of an alternative incorporation pathway for this protein into the ribosome, excluding the preliminary formation of the complex with 5S rRNA. At the same time, the stable L25-5S rRNA contact is important for the retention of the protein within the ribosome, and the conservative amino acid residues of the RNA-binding module play a key role in this.

Structural analysis of interdomain mobility in ribosomal L1 proteins.

Ribosomal protein L1 consists of two domains connected by two oppositely directed fragments of the polypeptide chain in a hinge-resembling fashion. The domain arrangement determines the overall shape of the protein, corresponding to an open or a closed conformation. Ribosomal L1 proteins from archaea demonstrate the open conformation in both isolated and RNA-bound forms. RNA-free ribosomal L1 proteins from bacteria display the closed conformation, whereas in complex with RNA these proteins exist in an open conformation similar to their archaeal counterparts. Analysis of all available L1 amino-acid sequences shows that in comparison to the archaeal proteins, the bacterial proteins possess an extra residue in one of the two interdomain fragments which could be responsible for their closed conformation. To verify this suggestion, a Thermus thermophilus L1 mutant lacking one residue in the fragment corresponding to the hinge was obtained and its crystal structure was solved. It was found that this mutation transformed the closed conformation of the bacterial L1 protein into an open conformation similar to that of the archaeal L1 proteins.

Stability of the 'L12 stalk' in ribosomes from mesophilic and (hyper)thermophilic Archaea and Bacteria.

The ribosomal stalk complex, consisting of one molecule of L10 and four or six molecules of L12, is attached to 23S rRNA via protein L10. This complex forms the so-called 'L12 stalk' on the 50S ribosomal subunit. Ribosomal protein L11 binds to the same region of 23S rRNA and is located at the base of the 'L12 stalk'. The 'L12 stalk' plays a key role in the interaction of the ribosome with translation factors. In this study stalk complexes from mesophilic and (hyper)thermophilic species of the archaeal genus Methanococcus and from the Archaeon Sulfolobus solfataricus, as well as from the Bacteria Escherichia coli, Geobacillus stearothermophilus and Thermus thermophilus, were overproduced in E.coli and purified under non-denaturing conditions. Using filter-binding assays the affinities of the archaeal and bacterial complexes to their specific 23S rRNA target site were analyzed at different pH, ionic strength and temperature. Affinities of both archaeal and bacterial complexes for 23S rRNA vary by more than two orders of magnitude, correlating very well with the growth temperatures of the organisms. A cooperative effect of binding to 23S rRNA of protein L11 and the L10/L12(4) complex from mesophilic and thermophilic Archaea was shown to be temperature-dependent.

Archaeal ribosomal protein L1: the structure provides new insights into RNA binding of the L1 protein family.

BACKGROUND: L1 is an important primary rRNA-binding protein, as well as a translational repressor that binds mRNA. It was shown that L1 proteins from some bacteria and archaea are functionally interchangeable within the ribosome and in the repression of translation. The crystal structure of bacterial L1 from Thermus thermophilus (TthL1) has previously been determined. RESULTS: We report here the first structure of a ribosomal protein from archaea, L1 from Methanococcus jannaschii (MjaL1). The overall shape of the two-domain molecule differs dramatically from that of its bacterial counterpart (TthL1) because of the different relative orientations of the domains. Two strictly conserved regions of the amino acid sequence, each belonging to one of the domains and positioned close to each other in the interdomain cavity of TthL1, are separated by about 25 A in MjaL1 owing to a significant opening of the structure. These regions are structurally highly conserved and are proposed to be the specific RNA-binding sites. CONCLUSIONS: The unusually high RNA-binding affinity of MjaL1 might be explained by the exposure of its highly conserved regions. The open conformation of MjaL1 is strongly stabilized by nonconserved interdomain interactions and suggests that the closed conformations of L1 (as in TthL1) open upon RNA binding. Comparison of the two L1 protein structures reveals a high conformational variability of this ribosomal protein. Determination of the MjaL1 structure offers an additional variant for fitting the L1 protein into electron-density maps of the 50S ribosomal subunit.

Nucleotide sequence of a gene cluster encoding NusG and the L11-L1-L10-L12 ribosomal proteins from the thermophilic archaeon Sulfolobus solfataricus.

The complete nucleotide sequence of a gene cluster encoding the NusG and the L 11-L1-L10-L12 ribosomal proteins from the thermophilic crenarchaeon Sulfolobus solfataricus has been determined. The genes are arranged in the same order as the equivalent genes in the rif region of Escherichia coli. The ribosomal proteins exhibit between 66% (L10) and 80% (L12) identity with their respective equivalents from Sulfolobus acidocaldarius. The short distance (5 nucleotides) between the nusG stop codon and the L11 start codon suggests that nusG and the genes for the ribosomal proteins are transcribed as a single unit.

Detailed analysis of RNA-protein interactions within the ribosomal protein S8-rRNA complex from the archaeon Methanococcus jannaschii.

The crystal structure of ribosomal protein S8 bound to its target 16 S rRNA from a hyperthermophilic archaeon Methanococcus jannaschii has been determined at 2.6 A resolution. The protein interacts with the minor groove of helix H21 at two sites located one helical turn apart, with S8 forming a bridge over the RNA major groove. The specificity of binding is essentially provided by the C-terminal domain of S8 and the highly conserved nucleotide core, characterized by two dinucleotide platforms, facing each other. The first platform (A595-A596), which is the less phylogenetically and structurally constrained, does not directly contact the protein but has an important shaping role in inducing cross-strand stacking interactions. The second platform (U641-A642) is specifically recognized by the protein. The universally conserved A642 plays a pivotal role by ensuring the cohesion of the complex organization of the core through an array of hydrogen bonds, including the G597-C643-U641 base triple. In addition, A642 provides the unique base-specific interaction with the conserved Ser105, while the Thr106 - Thr107 peptide link is stacked on its purine ring. Noteworthy, the specific recognition of this tripeptide (Thr-Ser-Thr/Ser) is parallel to the recognition of an RNA tetraloop by a dinucleotide platform in the P4-P6 ribozyme domain of group I intron. This suggests a general dual role of dinucleotide platforms in recognition of RNA or peptide motifs. One prominent feature is that conserved side-chain amino acids, as well as conserved bases, are essentially involved in maintaining tertiary folds. The specificity of binding is mainly driven by shape complementarity, which is increased by the hydrophobic part of side-chains. The remarkable similarity of this complex with its homologue in the T. thermophilus 30 S subunit indicates a conserved interaction mode between Archaea and Bacteria.

Control of ribosomal protein L1 synthesis in mesophilic and thermophilic archaea.

The mechanisms for the control of ribosomal protein synthesis have been characterized in detail in Eukarya and in Bacteria. In Archaea, only the regulation of the MvaL1 operon (encoding ribosomal proteins MvaL1, MvaL10, and MvaL12) of the mesophilic Methanococcus vannielii has been extensively investigated. As in Bacteria, regulation takes place at the level of translation. The regulator protein MvaL1 binds preferentially to its binding site on the 23S rRNA, and, when in excess, binds to the regulatory target site on its mRNA and thus inhibits translation of all three cistrons of the operon. The regulatory binding site on the mRNA, a structural mimic of the respective binding site on the 23S rRNA, is located within the structural gene about 30 nucleotides downstream of the ATG start codon. MvaL1 blocks a step before or at the formation of the first peptide bond of MvaL1. Here we demonstrate that a similar regulatory mechanism exists in the thermophilic M. thermolithotrophicus and M. jannaschii. The L1 gene is cotranscribed together with the L10 and L11 gene, in all genera of the Euryarchaeota branch of the Archaea studied so far. A potential regulatory L1 binding site located within the structural gene, as in Methanococcus, was found in Methanobacterium thermoautotrophicum and in Pyrococcus horikoshii. In contrast, in Archaeoglobus fulgidus a typical L1 binding site is located in the untranslated leader of the L1 gene as described for the halophilic Archaea. In Sulfolobus, a member of the Crenarchaeota, the L1 gene is part of a long transcript (encoding SecE, NusG, L11, L1, L10, L12). A previously suggested regulatory L1 target site located within the L11 structural gene could not be confirmed as an L1 binding site.

Translation termination factor aRF1 from the archaeon Methanococcus jannaschii is active with eukaryotic ribosomes.

Class-1 translation termination factors (release factors (RFs)) from Eukarya (eRF1) and Archaea (aRF1) exhibit a high degree of amino acid sequence homology and share many common motifs. In contrast to eRF1, function(s) of aRF1 have not yet been studied in vitro. Here, we describe for the first time the cloning and expression in Escherichia coli of the gene encoding the peptide chain RF from the hyperthermophilic archaeon Methanococcus jannaschii (MjaRF1). In an in vitro assay with mammalian ribosomes, MjaRF1, which was overproduced in E. coli, was active as a RF with all three termination codon-containing tetraplets, demonstrating the functional resemblance of aRF1 and eRF1. This observation confirms the earlier prediction that eRF1 and aRF1 form a common structural-functional eRF1/aRF1 protein family, originating from a common ancient ancestor.

DNA amplification and genetic instability in Streptomyces.

Genetic instability is very common in Streptomyces species, but only affects specific genes in any one strain. It sometimes occurs at high frequency spontaneously, but may be stimulated by treatments such as UV irradiation or intercalating agents. Deletion of genes occurs and may be accompanied by DNA amplifications. It is unlikely that there is plasmid involvement in most cases. Little is yet known about the molecular mechanisms of deletion and DNA amplification. Genetic instability can be a problem during commercial antibiotic production. DNA amplification of cloned genes is potentially useful for achieving both stability and high gene dosage.

Structure of the ribosomal protein L1-mRNA complex at 2.1 A resolution: common features of crystal packing of L1-RNA complexes.

The crystal structure of a hybrid complex between the bacterial ribosomal protein L1 from Thermus thermophilus and a Methanococcus vannielii mRNA fragment containing an L1-binding site was determined at 2.1 A resolution. It was found that all polar atoms involved in conserved protein-RNA hydrogen bonds have high values of density in the electron-density map and that their hydrogen-bonding capacity is fully realised through interactions with protein atoms, water molecules and K(+) ions. Intermolecular contacts were thoroughly analyzed in the present crystals and in crystals of previously determined L1-RNA complexes. It was shown that extension of the RNA helices providing canonical helix stacking between open-open or open-closed ends of RNA fragments is a common feature of these and all known crystals of complexes between ribosomal proteins and RNAs. In addition, the overwhelming majority of complexes between ribosomal proteins and RNA molecules display crystal contacts formed by the central parts of the RNA fragments. These contacts are often very extensive and strong and it is proposed that they are formed in the saturated solution prior to crystal formation.

Ribosomal resistance in the gentamicin producer organism Micromonospora purpurea.

The mechanism of resistance of the gentamicin-producing organism Micromonospora purpurea was analyzed. Determination of minimal inhibitory concentrations revealed high resistance to the 4,6-substituted deoxystreptamine aminoglycosides amikacin, gentamicin, kanamycin, netilmicin, sisomicin, and tobramycin and also to lividomycin A and hygromycin B, but susceptibility to streptomycin, dihydrostreptomycin, paromomycin, and neomycin during all phases of the growth cycle. The nonproducing, closely related Micromonospora melanosporea was susceptible to these compounds. In agreement with results from previous studies (R. Benveniste and J. Davies, Proc. Natl. Acad. Sci. U.S.A. 70:2276-2280, 1973), extracts from M. purpurea showed no activity of enzymes specifically modifying gentamicin. 70S ribosomes from M. purpurea but not from M. melanosporea were resistant to inhibition by gentamicin, kanamycin, tobramycin, and lividomycin in a polyuridylic acid-dependent polyphenylalanine synthesis system and susceptible to those compounds which were inhibitory in vivo. The former antibiotics were also unable to induce misreading. Subunit exchange experiments between M. purpurea and M. melanosporea showed that the main site for inhibition and induction of misreading is the 30S subunit (up to gentamicin concentrations of 10 micrograms/ml).

Genetic instability in streptomycetes.

Genetic instability is very common in Streptomyces species and is usually due to large chromosomal deletions. In the case of Streptomyces lividans 66, instability can be separated into two steps, each of which involves deletion of over 200 kb of DNA. Extreme DNA amplification often accompanies deletion and in S. lividans 66 this property has been used to amplify cloned genes to obtain stable high-copy-number derivatives.

Involvement of 16S ribosomal RNA in resistance of the aminoglycoside-producers Streptomyces tenjimariensis, Streptomyces tenebrarius and Micromonospora purpurea.

Resistance to aminoglycoside antibiotics in Micromonospora purpurea (the producer of gentamicin C complex), Streptomyces tenebrarius (the nebramycin producer) and Streptomyces tenjimariensis (which makes istamycin) occurs at the level of the ribosome. Reconstitution analysis has revealed, in each case, that 16S rRNA plays a critical role in determining such resistance.

Use of T7 RNA polymerase in an optimized Escherichia coli coupled in vitro transcription-translation system. Application in regulatory studies and expression of long transcription units.

An Escherichia coli coupled in vitro transcription-translation system has been modified to allow efficient expression of genes under the control of a T7 promoter. We describe both the characterization and use of two S30 crude extracts prepared from E. coli, namely S30 BL21(DE3) (containing endogenous T7 RNA polymerase) and S30 BL21 (supplemented with exogenous T7 RNA polymerase). Since transcription by the highly active T7 RNA polymerase is known to overload the translational machinery of E. coli, the ratio between mRNA and ribosomes has to be regulated in the coupled in vitro system. For this purpose, the level of mRNA is controlled by varying the amount of DNA template (S30 extract with endogenous T7 RNA polymerase) or by limited amounts of exogenously added T7 RNA polymerase. The coupled in vitro system described in this paper provides two especially useful applications. First, it is most suitable for studying the regulation of gene expression in vitro, second, it can be used to express DNA templates carrying up to 10 genes. We show that genes which are not well expressed in E. coli in vivo because of unfavourable codon usage or plasmid instability are synthesized efficiently in the coupled in vitro system.

TTG serves as an initiation codon for the ribosomal protein MvaS7 from the archaeon Methanococcus vannielii.

The ribosomal protein MvaS7 from the methanogenic archaeon Methanococcus vannielii is a protein of 188 amino acids, i.e., it is 42 amino acids longer than previously suggested. The triplet TTG serves as a start codon. The methanogenic translation initiation region that includes the rare TTG start codon is recognized in Escherichia coli.

MvaL1 autoregulates the synthesis of the three ribosomal proteins encoded on the MvaL1 operon of the archaeon Methanococcus vannielii by inhibiting its own translation before or at the formation of the first peptide bond.

The control of ribosomal protein synthesis has been investigated extensively in Eukarya and Bacteria. In Archaea, only the regulation of the MvaL1 operon (encoding ribosomal proteins MvaL1, MvaL10 and MvaL12) of Methanococcus vannielii has been studied in some detail. As in Escherichia coil, regulation takes place at the level of translation. MvaL1, the homologue of the regulatory protein L1 encoded by the L11 operon of E. coli, was shown to be an autoregulator of the MvaL1 operon. The regulatory MvaL1 binding site on the mRNA is located about 30 nucleotides downstream of the ATG start codon, a sequence that is not in direct contact with the initiating ribosome. Here, we demonstrate that autoregulation of MvaL1 occurs at or before the formation of the first peptide bond of MvaL1. Specific interaction of purified MvaL1 with both 23S RNA and its own mRNA is confirmed by filter binding studies. In vivo expression experiments reveal that translation of the distal MvaL10 and MvaL12 cistrons is coupled to that of the MvaL1 cistron. A mRNA secondary structure resembling a canonical L10 binding site and preliminary in vitro regulation experiments had suggested a co-regulatory function of MvaL10, the homologue of the regulatory protein L10 of the beta-operon of E. coil. However, we show that MvaL10 does not have a regulatory function.

Structure, organization and evolution of the L1 equivalent ribosomal protein gene of the archaebacterium Methanococcus vannielii.

The gene for ribosomal protein MvaL1 from the arachaebacterium Methanococcus vannielii was cloned and characterized. It is clustered together with the genes for MvaL10 and MvaL12, thus is organized in the same order as in E.coli and other archaebacteria. Unexpectedly, analysis of the sequence in front of the MvaL1 gene revealed an ORF of unknown identity, whereas in E.coli, Halobacterium and Sulfolobus solfataricus the gene for the L11 equivalent protein is located in this position. Northern blot analysis revealed a single tricistronic transcript encoding proteins MvaL1, MvaL10 and MvaL12. The 5'-end of the MvaL1-L10-L12 transcript contains a region that has a sequence and structure almost identical to a region on the 23S rRNA which is the putative binding domain for MvaL1, and is highly similar to the E.coli L11-L1 mRNA leader sequence that has been implicated in autogenous translational regulation. Amino acid sequence comparison revealed that MvaL1 shares 30.5% identity with ribosomal protein L1 from E.coli and 41.5% and 33.3% identity with the L1-equivalent proteins from the archaebacteria H.cutirubrum and S.solfataricus respectively.

Crystals of ribosomal protein L1 from a hyperthermophilic archaeon Methanococcus jannaschii.

Crystallographic studies of ribosomal proteins from bacteria progressed rapidly during the last decade, though the structures of ribosomal proteins from other kingdoms have not yet been published. Here we describe crystals of archaeal ribosomal protein L1 from Methanococcus jannaschii. The protein crystals were grown in 10% PEG 10 K, 50 mM Hepes-HCl (pH 7.5) in hanging drops equilibrated against 33% PEG 10 K, 100 mM Hepes-HCl (pH 7.5). The crystals diffract to at least 2.5 A resolution and belong to the space group P1 with cell parameters a = 34.09 A, b = 39.39 A, c = 55.84 A, alpha = 83.65 degrees, beta = 80.38 degrees, gamma = 75.37 degrees.

Analysis of putative DNA amplification genes in the element AUD1 of Streptomyces lividans 66.

The amplifiable AUD1 element of Streptomyces lividans 66 consists of two copies of a 4.7 kb sequence flanked by three copies of a 1 kb sequence. The DNA sequences of the three 1 kb repeats were determined. Two copies (left and middle repeats) were identical: (1009 bp in length) and the right repeat was 1012 bp long and differed at 63 positions. The repeats code for open reading frames (ORFs) with typical Streptomyces codon usage, which would encode proteins of about 36 kD molecular weight. The sequences of these ORFs suggest that they specify DNA-binding proteins and potential palindromic binding sites are found adjacent to the genes. The putative amplification protein encoded by the right repeat was expressed in Escherichia coli.