Phylogenomics of prokaryotic ribosomal proteins

Archaeal and bacterial ribosomes contain more than 50 proteins, including 34 that are universally conserved in the three domains of cellular life (bacteria, archaea, and eukaryotes). Despite the high sequence conservation, annotation of ribosomal (r-) protein genes is often difficult because of their short lengths and biased sequence composition. We developed an automated computational pipeline for identification of r-protein genes and applied it to 995 completely sequenced bacterial and 87 archaeal genomes available in the RefSeq database. The pipeline employs curated seed alignments of r-proteins to run position-specific scoring matrix (PSSM)-based BLAST searches against six-frame genome translations, mitigating possible gene annotation errors. As a result of this analysis, we performed a census of prokaryotic r-protein complements, enumerated missing and paralogous r-proteins, and analyzed the distributions of ribosomal protein genes among chromosomal partitions. Phyletic patterns of bacterial and archaeal r-protein genes were mapped to phylogenetic trees reconstructed from concatenated alignments of r-proteins to reveal the history of likely multiple independent gains and losses. These alignments, available for download, can be used as search profiles to improve genome annotation of r-proteins and for further comparative genomics studies.     

Fission yeast and a plant have functional homologues of the Sar1 and Sec12 proteins involved in ER to Golgi traffic in budding yeast.

Sec12p and Sar1p are required for the formation of transport vesicles generated from the endoplasmic reticulum (ER) in the yeast Saccharomyces cerevisiae. Sec12p is an ER type II membrane protein that mediates the membrane attachment of the GTP-binding Sar1 protein. The SAR1 gene is a multi-copy suppressor of a thermosensitive sec12 mutation. In an attempt to identify functional homologues of Sec12p and Sar1p from other eukaryotic organisms, we screened cDNA expression libraries derived from the fission yeast Schizosaccharomyces pombe and from the plant Arabidopsis thaliana for complementation of the sec12ts mutation. Four individual cDNAs were isolated, two of which encode the S. pombe and A. thaliana homologues of Sar1p. The three Sar1 proteins are 67% identical on average. The two other cDNAs encode type II membrane proteins which were designated Stl1p for the S. pombe protein and Stl2p for the A. thaliana protein (Stl stands for Sec12p-like). Both proteins have NH2-terminal cytoplasmic domains which resemble that of Sec12p: they are similar in size and present a significant degree of amino acid identity with the cytoplasmic domain of Sec12p. In contrast, the lumenal domains of Sec12p, Stl1p and Stl2p are very different in size and do not show any appreciable homology. That Stl1p and Stl2p are functional homologues of Sec12p was confirmed by showing that expression of either cloned gene complements a sec12 null mutation. Our results indicate that some of the mechanisms regulating vesicle formation at the ER are conserved not only in yeasts, but also in plants.     

Subcellular distribution of ribosomal proteins S6 and eL12

Summary The process of ribosome assembly in eukaryotes was studied by injecting tritium-labeled ribosomal proteins S6 and eL12 into oocytes of Xenopus laevis. The subcellular distribution of the two proteins was visualized by means of autoradiography in sections of oocytes. Protein S6 but not eL12 was found in the nucleus where it accumulated at the nucleoli. In the presence of actinomycin D the accumulation of S6 at the nucleoli was reduced. In-situ immunofluorescence studies indicated that S6 is located at the nucleoli and eL12 exclusively in the cytoplasm. It appears that S6 is involved in the early ribosomal assembly process at the nucleoli, whereas eL12 is restricted to the cytoplasm where it is incorporated into 60S ribosomal subunits in a late assembly step.     

Structural comparison of the prokaryotic ribosomal proteins L7/L12 and L30

The structures of two prokaryotic ribosomal proteins, the carboxyterminal half of L7/L12 from Escherichia coli (L12CTF) and L30 from Bacilus stearothermophilus display a remarkably similar fold in which alpha-helices pack onto one side of an antiparallel, three-stranded, beta-pleated sheet. A detailed comparison of the structures by least-squares methods reveals that more than two-thirds of the alpha carbons can be superimposed with a root mean square distance of 2.33 A. The principal difference is an extra alpha-helix in L12CTF. The sequences of the proteins display a distinct conservation in regions which are crucial to the common fold, in particular the hydrophobic core. It is proposed that the similarity is a result of divergent evolution.     

Cloning and analysis of the nuclear genes for two mitochondrial ribosomal proteins in yeast

Summary Two mitochondrial ribosomal proteins of yeast (Saccharomyces cerevisiae) were purified and their N-terminal amino acid sequences determined. The sequence data were used for the synthesis of oligonucleotide probes to clone the corresponding genes. Thus, the genes for two proteins, termed YMR-31 and YMR-44, were cloned and their nucleotide sequences determined. From the nucleotide sequence data, the coding region of the gene for protein YMR-31 was found to be composed of 369 nucleotide pairs. Comparison of the amino acid sequence of protein YMR-31 and the one deduced from the nucleotide sequence of its gene suggests that it contains an octapeptide leader sequence. The calculated molecular weight of protein YMR-31 without the leader sequence is 12792 dalton. The gene for protein YMR-44 was found to contain a 147 bp intron which contains two sequences conserved among yeast introns. The length of the two exons flanking the intron totals 294 nucleotide pairs which can encode a protein with a calculated molecular weight of 11476 dalton. The gene for protein YMR-31 is located on chromosome VI, while the gene for protein YMR-44 is located on either chromosome XIII or XVI.     

Identification of yeast 60 S ribosomal proteins crosslinked to rRNA by 2-iminothiolane

Saccharomyces carlsbergensis 60 S ribosomal subunits were treated with the hetero-bifunctional crosslinking agent 2-iminothiolane and then subjected to mild UV irradiation to introduce protein-rRNA crosslinks. The major crosslinked products were identified as proteins L2, L3, L5, L19 and L23 of which L5 was found to be crosslinked at a 3-5-fold higher efficiency than the other four. Several additional proteins were cross-linked to a detectable but much lower extent.     

Regulation of mitochondrial ribosomal RNA synthesis in yeast

Summary Studies were undertaken to determine if mitochondrial rRNA synthesis in yeast is regulated by general cellular stringent control mechanism. Those variables affecting the relaxation of a cycloheximide-induced stringent response as a result of medium-shift-down or tyrosine limitation include: 1) the stage of cell growth, 2) carbon source, 3) strain differences and, 4) integrity of the cell wall. The extent of phenotypic relaxation decreased or was eliminated entirely in a strain dependent manner as cells entered stationary phase of growth or by growth of cells on galactose or in osmotically stabilized spheroplast cultures.Cytoplasmic and mitochondrial RNA species were extracted from regrowing spheroplast cultures subjected to different experimental regimens and analyzed by electrophoresis on 2.5% polyacrylamide gels. Relative rates of synthesis were determined in pulse experiments and normalized by double-label procedures to longterm label material. Tyrosine starvation was found to inhibit synthesis of the large and small rRNA species of both cytoplasmic and mitochondrial rRNAs to about 5–20% of the control values. Chloramphenicol inhibits mitochondrial and cytoplasmic rRNA synthesis to 60–80% of control; however, chloramphenicol addition does not relax the stringent inhibition of either class of rRNAs. Cycloheximide addition results in 70–80% inhibition of synthesis of both cellular species of rRNAs. As noted above, cycloheximide does not relax the stringent response of cytoplasmic rRNA synthesis in spheroplasts, and also does not relax the stringent inhibition of mitochondrial rRNA synthesis. From these studies, we conclude that both cytoplasmic and mitochondrial rRNA synthesis share common control mechanisms related to regulation of protein synthesis by shift-down or amino acid limitation.     

Involvement of mitochondrial ribosomal proteins in ribosomal RNA-mediated protein folding

The peptidyl transferase center of the domain V of large ribosomal RNA in the prokaryotic and eukaryotic cytosolic ribosomes acts as general protein folding modulator. We showed earlier that one part of the domain V (RNA1 containing the peptidyl transferase loop) binds unfolded protein and directs it to a folding competent state (FCS) that is released by the other part (RNA2) to attain the folded native state by itself. Here we show that the peptidyl transferase loop of the mitochondrial ribosome releases unfolded proteins in FCS extremely slowly despite its lack of the rRNA segment analogous to RNA2. The release of FCS can be hastened by the equivalent activity of RNA2 or the large subunit proteins of the mitochondrial ribosome. The RNA2 or large subunit proteins probably introduce some allosteric change in the peptidyl transferase loop to enable it to release proteins in FCS.     

Characterization and comparison of ribosomal proteins from two prokaryotic organisms

Ribosomal proteins from the prokaryotic bacteria. Streptococcus mutans and Escherichia coli, were separated by two dimensional gel electrophoresis as described by O'Farrell. The resulting protein spot patterns in the two types of gels are discussed in comparison with one another and with ribosomal proteins from eukaryotic organisms. More acidic proteins were found in ribosomal preparations from E. coli than from S. mutans, although this was probably a result of contamination of the former preparation with cellular components. Six ribosomal proteins from these organisms traversed to similar positions on the gels and this suggested that they were identical with respect to molecular weight and electrostatic charge. The data indicate that the six proteins were conserved through the evolution of these two prokaryotic organisms.     

Identification and comparative analysis of the large subunit mitochondrial ribosomal proteins of Neurospora crassa

The mitochondrial ribosome (mitoribosome) has highly evolved from its putative prokaryotic ancestor and varies considerably from one organism to another. To gain further insights into its structural and evolutionary characteristics, we have purified and identified individual mitochondrial ribosomal proteins of Neurospora crassa by mass spectrometry and compared them with those of the budding yeast Saccharomyces cerevisiae. Most of the mitochondrial ribosomal proteins of the two fungi are well conserved with each other, although the degree of conservation varies to a large extent. One of the N. crassa mitochondrial ribosomal proteins was found to be homologous to yeast Mhr1p that is involved in homologous DNA recombination and genome maintenance in yeast mitochondria.     

Electrophoretic and immunological comparisons of chloroplast and prokaryotic ribosomal proteins reveal that certain families of large subunit proteins are evolutionarily conserved

Summary Antibodies to individual chloroplast ribosomal (r-)proteins ofChlamydomonas reinhardtii synthesized in either the chloroplast or the cytoplasm were used to examine the relatedness ofChlamydomonas r-proteins to r-proteins from the spinach (Spinacia oleracea) chloroplast,Escherichia coli, and the cyanobacteriumAnabaena 7120. In addition,³⁵S-labeled chloroplast r-proteins from large and small subunits ofC. reinhardtii were coelectrophoresed on 2-D gels with unlabeled r-proteins from similar subunits of spinach chloroplasts,E. coli, andAnabaena to compare their size and net charge. Comigrating protein pairs were not always immunologically related, whereas immunologically related r-protein pairs often did not comigrate but differed only slightly in charge and molecular weight. In constrast, when³⁵S-labeled chloroplast r-proteins from large and small subunits of a closely related speciesC. smithii were coelectrophoresed with unlabeledC. reinhardtii chloroplast r-proteins, only one pair of proteins from each subunit showed a net displacement in mobility.Analysis of immunoblots of one-dimensional SDS and two-dimensional urea/SDS gels of large and small subunit r-proteins from these species revealed more antigenic conservation among the four species of large subunit r-proteins than small subunit r-proteins.Anabaena r-proteins showed the greatest immunological similarity toC. reinhardtii chloroplast r-proteins. In general, antisera made against chloroplast-synthesized r-proteins inC. reinhardtii showed much higher levels of cross-reactivity with r-proteins fromAnabaena, spinach, andE. coli than did antisera to cytoplasmically synthesized r-proteins. All spinach r-proteins that cross-reacted with antisera to chloroplast-synthesized r-proteins ofC. reinhardtii are known to be made in the chloroplast (Dorne et al. 1984b). FourE. coli r-proteins encoded by the S10 operon (L2, S3, L16, and L23) were found to be conserved immunologically among the four species. Two of the large subunit r-proteins, L2 and L16, are essential for peptidyltransferase activity. The third (L23) and two otherE. coli large subunit r-proteins (L5 and L27) that have immunological equivalents among the four species are functionally related to but not essential for peptidyltransferase activity.     

Self-splicing of yeast mitochondrial ribosomal and messenger RNA precursors

We have previously shown linear and circular splicing intermediates resembling intermediates that result from self-splicing of ribosomal precursor RNA of Tetrahymena to be present in mitochondrial RNA. Here we show that splicing of yeast mitochondrial precursor RNA also occurs in vitro in the absence of mitochondrial proteins. The large ribosomal RNA gene, consisting of the intron and part of the flanking exon regions, was inserted behind the SP6 promoter in a recombinant plasmid and was transcribed in vitro. The resulting RNA shows self-catalyzed splicing via incorporation of GTP at the 5'-end of the excised intron, 5'- to 3'-exon ligation, and intron circularization. When purified mitochondrial RNA is incubated under similar conditions with alpha-32P-GTP, the excised ribosomal intron RNA is also labeled, as well as several other RNA species. Some of these RNAs are derived from excised introns from the multiply split gene coding for cytochrome oxidase subunit I.     

Modification of yeast ribosomal proteins. Methylation.

Two-dimensional polyacrylamide-gel electrophoretic analysis of yeast ribosomal proteins uniformly labelled in vivo with [methyl-3H]methionine and [1-14C]methionine revealed that four ribosomal proteins are methylated, i.e. proteins S31, S32, L15 and L41. Lysine and arginine appear to be the predominant acceptors of the methyl groups. The degree of methylation ranges from 0.09 to 0.20 methyl group per modified ribosomal protein species.     

Modification of yeast ribosomal proteins. Phosphorylation.

Two-dimensional polyacrylamide-gel electrophoretic analysis of yeast ribosomal proteins labelled in vivo with 32PO43- revealed that the proteins S2 and S10 of the 40S ribosomal subunit, and the proteins L9, L30, L44 and L45 of the 60S ribosomal subunit, are phosphorylated in vivo. Most of the phosphate groups appeared to be linked to serine residues. Teh number of phosphate groups per molecule of phosphorylated protein species ranged from 0.01 to 0.79. Since most of the phosphorylated ribosomal proteins appear to associate with the pre-ribosomal particles at a very late stage of ribosome assembly, phosphorylation is more likely to play a role in the functioning of the ribosome than in its assembly.     

Identification of 12-lipoxygenase interaction with cellular proteins by yeast two-hybrid screening

The platelet isoform of 12-lipoxygenase (12-LOX) is expressed in a variety of human tumors. 12-LOX metabolizes arachidonic acid to 12(S)-hydroxyeicosateraenoic acid (12(S)-HETE), which induces a number of cellular responses associated with tumor progression and metastasis. Little is known about 12-LOX regulation and no direct regulators of 12-LOX activity have been identified. To identify potential regulators of 12-LOX, we isolated cDNAs encoding 12-LOX interacting proteins using the yeast two-hybrid system. We screened a yeast two-hybrid interaction library from human epidermoid carcinoma A431 cells and identified four cellular proteins that interact specifically with 12-LOX. We identified type II keratin 5, lamin A, the cytoplasmic domain of integrin beta4 subunit and a phosphoprotein C8FW as 12-LOX interacting proteins. Here, we demonstrated that keratin 5, a 58 kD protein required for formation of 8 nm intermediate filaments, binds to 12-LOX in human tumor cells and may contribute to the regulated trafficking of 12-LOX. We also showed that lamin A binds 12-LOX in human tumor cells. These proteins provide the first candidate regulators of 12-LOX.