cDNA sequence analysis of ribosomal protein S13 gene in Plutella xylostella （Lepidoptera： Plutellidae）

Ribosomal protein S 13 gene has been cloned and analyzed in many organisms,but there are few documents relating to insects. In this communication, the full-length cDNA sequence of ribosomal protein S 13 gene in the diamondback moth, Plutella xylostella(Lepidoptera: Plutellidae), was determined by using PCR amplification technique. The features of the ribosomal protein S 13 gene sequence were analyzed and the deduced amino acids sequence was compared with those from other insects. The results of multi-alignment of the amino acid sequences between the diamondback moth and other insect species revealed that this gene sequence is highly conserved in insects. Based on maximum likelihood method, a phylogenetic tree was constructed from 10 different species using PHYLIP software. It showed that nematode is one separate lineage and the five insect speciesbe long to another lineage, whereas those species higher than insects form the third one. The pattern of this phylogenetic tree evidently represented the evolution of different species.     

Diverse effects of residues 74–78 in ribosomal protein S12 on decoding and antibiotic sensitivity

Ribosomal protein S12 plays key roles in the ribosome’s response to the error-promoting antibiotic streptomycin and in modulating the accuracy of translation. The discovery that substitutions at His76 in S12, distant from the streptomycin binding site, conferred streptomycin resistance in the thermophilic bacterium Thermus thermophilus prompted us to make similar alterations in the S12 protein of Escherichia coli. While, none of the E. coli S12 mutations confers streptomycin resistance, they all have distinct effects on the accuracy of translation. In addition, a subset of the S12 alterations renders the cells hypersensitive to fusidic acid, an inhibitor of the translocation step of translation. These results indicate that the His 76 region of ribosomal protein S12 plays key roles in tRNA selection and translocation steps of protein synthesis, consistent with its interaction with elongation factors EF-Tu and EF-G, as deduced from structural studies of ribosomal complexes.     

Identification of the protein cross-linked to 3′-terminus of 5 S RNA in rat liver ribosomal 60 S subunits

To cross-link the 3′-terminus of 5 S RNA to its neighbouring proteins, ribosomal 60 S subunits of rat liver were oxidized with sodium periodate and reduced with sodium borohydride. 5 S RNP was then isolated by EDTA treatment followed by sucrose density-gradient centrifugation and subjected to SDS-polyacrylamide gel electrophoresis. The protein with a slower mobility than the L5 protein, which was thought to be cross-linked 5 S RNP, was labeled with ¹²⁵I, treated with RNAase, and analyzed by two-dimensional polyacrylamide gel electrophoresis, followed by radioautography. A radioactive spot located anodically from L5 protein was observed, suggesting that it is the L5 protein-oligonucleotide complex. When analyzed by SDS slab polyacrylamide gel electrophoresis followed by radioautography, the peptide pattern of the α-chymotrypsin digest of this ¹²⁵I-labeled protein-oligonucleotide complex was similar to that of the digest of ¹²⁵I-labeled L5 protein. The results indicate that L5 protein binds to the 3′-terminal region of 5 S RNA in rat liver 60 S subunits.     

Bonsaï, a ribosomal protein S15 homolog, involved in gut mitochondrial activity and systemic growth

The regulation of cellular growth is crucial in the control of cell proliferation. While most of the metabolic energy necessary to sustain growth is produced in mitochondria, the regulation of mitochondrial activity and its implications for growth have remained unexplored. Here, a gene named bonsa? is described, which is essential for normal growth in Drosophila. The Bonsa? protein bears strong homology to prokaryotic ribosomal protein S15 and localizes to mitochondria, suggesting a role in mitochondrial protein translation. Accordingly, bonsa? mutants have defective mitochondrial activity, but surprisingly, only the gut appears affected. Consistent with these observations, bonsa? is predominantly expressed in the gut. These results show that bonsa? plays a preponderant role in gut mitochondria. Although gut mitochondrial respiration is altered in bonsa? mutants, the digestive process appears normal, suggesting that a gut function other than digestion is impaired in the mutants. Cytochrome c oxidase, a respiratory chain enzyme partly encoded by the mitochondrial genome, is found to be active in bonsa? mutants. This suggests that mitochondrial translation is not abolished in the mutants. Altogether, these observations suggest that mitochondrial activity is regulated at the tissue-specific level and that this regulation has profound implications for growth and development.     

Yeast ribosomal protein S3 possesses a β-lyase activity on damaged DNA

Yeast ribosomal protein S3 has multifunctional activities that are involved in both protein translation and DNA repair. Here, we report that yeast Rps3p cleaves variously damaged DNA that contains not only AP sites and pyrimidine dimers but also 7,8-hydro-8-oxoguanine. This study also revealed that Rps3p has a β-lyase activity with a broad range of substrate specificity which cleaves phosphodiester bonds of UV or oxidatively damaged DNA substrates. Mutation analysis of the yeast Rps3 protein including introduction of domain deletions and residue replacements identified the residues Asp154 and Lys200 are important for the catalytic activity. In addition, the repair enzyme activity of yeast Rps3p was confirmed by complementation in xth, nfo Escherichia coli cells in which the DNA repair process is defective.     

Accuracy modulating mutations of the ribosomal protein S4-S5 interface do not necessarily destabilize the rps4-rps5 protein–protein interaction

During the process of translation, an aminoacyl tRNA is selected in the A site of the decoding center of the small subunit based on the correct codon–anticodon base pairing. Though selection is usually accurate, mutations in the ribosomal RNA and proteins and the presence of some antibiotics like streptomycin alter translational accuracy. Recent crystallographic structures of the ribosome suggest that cognate tRNAs induce a “closed conformation” of the small subunit that stabilizes the codon–anticodon interactions at the A site. During formation of the closed conformation, the protein interface between rpS4 and rpS5 is broken while new contacts form with rpS12. Mutations in rpS12 confer streptomycin resistance or dependence and show a hyperaccurate phenotype. Mutations reversing streptomycin dependence affect rpS4 and rpS5. The canonical rpS4 and rpS5 streptomycin independent mutations increase translational errors and were called ribosomal ambiguity mutations (ram). The mutations in these proteins are proposed to affect formation of the closed complex by breaking the rpS4-rpS5 interface, which reduces the cost of domain closure and thus increases translational errors. We used a yeast two-hybrid system to study the interactions between the small subunit ribosomal proteins rpS4 and rpS5 and to test the effect of ram mutations on the stability of the interface. We found no correlation between ram phenotype and disruption of the interface.     

Universal and domain-specific sequences in 23S–28S ribosomal RNA identified by computational phylogenetics

Comparative analysis of ribosomal RNA (rRNA) sequences has elucidated phylogenetic relationships. However, this powerful approach has not been fully exploited to address ribosome function. Here we identify stretches of evolutionarily conserved sequences, which correspond with regions of high functional importance. For this, we developed a structurally aligned database, FLORA (full-length organismal rRNA alignment) to identify highly conserved nucleotide elements (CNEs) in 23S–28S rRNA from each phylogenetic domain (Eukarya, Bacteria, and Archaea). Universal CNEs (uCNEs) are conserved in sequence and structural position in all three domains. Those in regions known to be essential for translation validate our approach. Importantly, some uCNEs reside in areas of unknown function, thus identifying novel sequences of likely great importance. In contrast to uCNEs, domain-specific CNEs (dsCNEs) are conserved in just one phylogenetic domain. This is the first report of conserved sequence elements in rRNA that are domain-specific; they are largely a eukaryotic phenomenon. The locations of the eukaryotic dsCNEs within the structure of the ribosome suggest they may function in nascent polypeptide transit through the ribosome tunnel and in tRNA exit from the ribosome. Our findings provide insights and a resource for ribosome function studies.     

Chromosomal localization of 5S and 18S–5.8S–25S ribosomal DNA sites in five Asian pines using fluorescence in situ hybridization

Fluorescence in situ hybridization (FISH) was employed on mitotic metaphase chromosome preparations of five Asian Pinus species: Pinus tabuliformis, Pinus yunnanensis, Pinus densata, Pinus massoniana and Pinus merkusii, using simultaneously DNA probes of the 18S rRNA gene and the 5S rRNA gene including the non-transcribed spacer sequences. The number and location of 18S rDNA sites varied markedly (5-10 pairs of strong signals) among the five pines. A maximum of 20 major 18S rDNA sites was observed in the diploid genome (2n = 24) of P. massoniana. The 5S rDNA FISH pattern was less variable, with one major site and one minor site commonly observed in each species. The differentiation of rDNA sites on chromosomes among the five pines correlates well with their phylogenic positions in Pinus as reconstructed from other molecular data. P. densata, a species of hybrid origin, resembles its parents ( P. tabuliformis and P. yunnanensis), including some components characteristic of each parent in its pattern. However, the species is unique, showing new features resulting possibly from recombination and genome reorganization.     

Affinity labelling of rat liver ribosomal protein S26 by heptauridylate containing a 5′-terminal alkylating group

Heptauridylate bearing a radioactive alkylating [¹⁴C]-4-(N-2-chloroethyl-N-methylamino)benzylamine attached to the 5-phosphate via amide bond, was bound to ribosomes and small ribosomal subunits from rat liver which thereby were coded to bind N-acylated Phe tRNA. After completion of the alkylating reaction and subsequent hydrolysis of the phosphamide bond ribosomal proteins were isolated. Radioactivity was found covalently associated preferentially with protein S26 and, to a very small extent, with proteins S3 and S3a. The affinity labelling reaction could be abolished by (pU)₁₄ and poly(U). From the results it is concluded that ribosomal protein S26 is located at the mRNA binding site of rat liver ribosomes.     

Escherichia coli ribosomal protein S1 does not protect the 49-nucleotide 3′ terminal cloacin fragment of 16 S rRNA from nuclease S1

Footprinting of ribosomal protein S1 on the 49-nucleotide 3′ terminal cloacin DF13 fragment of 16 S rRNA at physiological ionic strength, pH and temperature yielded no detectable protection of any nucleotides from subsequent attack by the single strand specific nuclease S1, even at large excesses of ribosomal protein S1.     

Do mRNA and rRNA binding sites of E.coli ribosomal protein S15 share common structural determinants?

Escherichia coli ribosomal protein S15 recognizes two RNA targets: a three-way junction in 16S rRNA and a pseudoknot structure on its own mRNA. Binding to mRNA occurs when S15 is expressed in excess over its rRNA target, resulting in an inhibition of translation start. The sole apparent similarity between the rRNA and mRNA targets is the presence of a G-U/G-C motif that contributes only modestly to rRNA binding but is essential for mRNA. To get more information on the structural determinants used by S15 to bind its mRNA target as compared to its rRNA site, we used site-directed mutagenesis, substitution by nucleotide analogs, footprinting experiments on both RNA and protein, and graphic modeling. The size of the mRNA-binding site could be reduced to 45 nucleotides, without loss of affinity. This short RNA preferentially folds into a pseudoknot, the formation of which depends on magnesium concentration and temperature. The size of the loop L2 that bridges the two stems of the pseudoknot through the minor groove could not be reduced below nine nucleotides. Then we showed that the pseudoknot recognizes the same side of S15 as 16S rRNA, although shielding a smaller surface area. It turned out that the G-U/G-C motif is recognized from the minor groove in both cases, and that the G-C pair is recognized in a very similar manner. However, the wobble G-U pair of the mRNA is not directly contacted by S15, as in rRNA, but is most likely involved in building a precise conformation of the RNA, essential for binding. Otherwise, unique specific features are utilized, such as the three-way junction in the case of 16S rRNA and the looped out A(-46) for the mRNA pseudoknot.     

TPA-induced cell transformation provokes a complex formation between Pin1 and 90?kDa ribosomal protein S6 kinase 2

The antioxidant properties of organoselenium compounds have been extensively investigated because oxidative stress is a hallmark of a variety of chronic human diseases. Here, we reported the influence of substituent groups in the antioxidant activity of β-selenoamines. We have investigated whether they exhibited glutathione peroxidase-like (GPx-like) activity and whether they could be substrate of thioredoxin reductase (TrxR). In the DPPH assay, the β-selenium amines did not exhibit antioxidant activity. However, the β-selenium amines with p-methoxy and tosyl groups prevented the lipid peroxidation. The β-selenium amine compound with p-methoxy substituent group exhibited thiol-peroxidase-like activity (GPx-like activity) and was reduced by the hepatic TrxR. These results contribute to understand the influence of structural alteration of non-conventional selenium compounds as synthetic mimetic of antioxidant enzymes of mammalian organisms.     

Nuclear protein in the liver in protein–calorie deficiency

1. The effect of protein–calorie deficiency on nuclear proteins was studied in growing and adult rats by using chemical and electrophoretic methods of fractionation. 2. After 7 days on protein-deficient diets, the amount of neutral-soluble proteins increased, and their electrophoretic pattern changed, with the appearance of a new component. 3. The histone fraction of the liver nuclei in rapidly growing rats was lower than that in either deficient or adult animals. 4. The possible role of nuclear proteins in relation to synthesis of the proteins and nucleic acids of the other parts of the cells is discussed.