Primary structures of five ribosomal proteins from the archaebacterium Halobacterium marismortui and their structural relationships to eubacterial and eukaryotic ribosomal proteins

siRNA knockdown of ribosomal protein gene RPL19 abrogates the aggressive phenotype of human prostate cancer

We provide novel functional data that posttranscriptional silencing of gene RPL19 using RNAi not only abrogates the malignant phenotype of PC-3M prostate cancer cells but is selective with respect to transcription and translation of other genes. Reducing RPL19 transcription modulates a subset of genes, evidenced by gene expression array analysis and Western blotting, but does not compromise cell proliferation or apoptosis in-vitro. However, growth of xenografted tumors containing the knocked-down RPL19 in-vivo is significantly reduced. Analysis of the modulated genes reveals induction of the non-malignant phenotype principally to involve perturbation of networks of transcription factors and cellular adhesion genes. The data provide evidence that extra-ribosomal regulatory functions of RPL19, beyond protein synthesis, are critical regulators of cellular phenotype. Targeting key members of affected networks identified by gene expression analysis raises the possibility of therapeutically stabilizing a benign phenotype generated by modulating the expression of an individual gene and thereafter constraining a malignant phenotype while leaving non-malignant tissues unaffected.

A new plant protein interacts with eIF3 and 60S to enhance virus-activated translation re-initiation

The plant viral re-initiation factor transactivator viroplasmin (TAV) activates translation of polycistronic mRNA by a re-initiation mechanism involving translation initiation factor 3 (eIF3) and the 60S ribosomal subunit (60S). QJ;Here, we report a new plant factor-re-initiation supporting protein (RISP)-that enhances TAV function in re-initiation. RISP interacts physically with TAV in vitro and in vivo. Mutants defective in interaction are less active, or inactive, in transactivation and viral amplification. RISP alone can serve as a scaffold protein, which is able to interact with eIF3 subunits a/c and 60S, apparently through the C-terminus of ribosomal protein L24. RISP pre-bound to eIF3 binds 40S, suggesting that RISP enters the translational machinery at the 43S formation step. RISP, TAV and 60S co-localize in epidermal cells of infected plants, and eIF3-TAV-RISP-L24 complex formation can be shown in vitro. These results suggest that RISP and TAV bridge interactions between eIF3-bound 40S and L24 of 60S after translation termination to ensure 60S recruitment during repetitive initiation events on polycistronic mRNA; RISP can thus be considered as a new component of the cell translation machinery.

Viral strategies of translation initiation: ribosomal shunt and reinitiation

Due to the compactness of their genomes, viruses are well suited to the study of basic expression mechanisms, including details of transcription, RNA processing, transport, and translation. In fact, most basic principles of these processes were first described in viral systems. Furthermore, viruses seem not to respect basic rules, and cases of "abnormal" expression strategies are quiet common, although such strategies are usually also finally observed in rare cases of cellular gene expression. Concerning translation, viruses most often violate Kozak's original rule that eukaryotic translation starts from a capped monocistronic mRNA and involves linear scanning to find the first suitable start codon. Thus, many viral cases have been described where translation is initiated from noncapped RNA, using an internal ribosome entry site. This review centers on other viral translation strategies, namely shunting and virus-controlled reinitiation as first described in plant pararetroviruses (Caulimoviridae). In shunting, major parts of a complex leader are bypassed and not melted by scanning ribosomes. In the Caulimoviridae, this process is coupled to reinitiation after translation of a small open reading frame; in other cases, it is possibly initiated upon pausing of the scanning ribosome. Most of the Caulimoviridae produce polycistronic mRNAs. Two basic mechanisms are used for their translation. Alternative translation of the downstream open reading frames in the bacilliform Caulimoviridae occurs by a leaky scanning mechanism, and reinitiation of polycistronic translation in many of the icosahedral Caulimoviridae is enabled by the action of a viral transactivator. Both of these processes are discussed here in detail and compared to related processes in other viruses and cells.

A plant viral "reinitiation" factor interacts with the host translational machinery

The cauliflower mosaic virus transactivator, TAV, controls translation reinitiation of major open reading frames on polycistronic RNA. We show here that TAV function depends on its association with polysomes and eukaryotic initiation factor eIF3 in vitro and in vivo. TAV physically interacts with eIF3 and the 60S ribosomal subunit. Two proteins mediating these interactions were identified: eIF3g and 60S ribosomal protein L24. Transient expression of eIF3g and L24 in plant protoplasts strongly affects TAV-mediated reinitiation activity. We demonstrate that TAV/eIF3/40S and eIF3/TAV/60S ternary complexes form in vitro, and propose that TAV mediates efficient recruitment of eIF3 to polysomes, allowing translation of polycistronic mRNAs by reinitiation, overcoming the normal cell barriers to this process.

Yeast ribosomal protein L24 affects the kinetics of protein synthesis and ribosomal protein L39 improves translational accuracy, while mutants lacking both remain viable

Four mutant strains from Saccharomyces cerevisiae were used to study ribosome structure and function. They included a strain carrying deletions of the two genes encoding ribosomal protein L24, a strain carrying a mutation spb2 in the gene for ribosomal protein L39, a strain carrying a deletion of the gene for L39, and a mutant lacking both L24 and L39. The mutant lacking only L24 showed just 25% of the normal polyphenylalanine-synthesizing activity followed by a decrease in P-site binding, suggesting the possibility that protein L24 is involved in the kinetics of translation. Each of the two L39 mutants displayed a 4-fold increase of their error frequencies over the wild type. This was accompanied by a substantial increase in A-site binding, typical of error-prone mutants. The absence of L39 also increased sensitivity to paromomycin, decreased the ribosomal subunit ratio, and caused a cold-sensitive phenotype. Mutant cells lacking both ribosomal proteins remained viable. Their ribosomes showed reduced initial rates caused by the absence of L24 but a normal extent of polyphenylalanine synthesis and a substantial in vivo reduction in the amount of 80S ribosomes compared to wild type. Moreover, this mutant displayed decreased translational accuracy, hypersensitivity to the antibiotic paromomycin, and a cold-sensitive phenotype, all caused mainly by the deletion of L39. Protein L39 is the first protein of the 60S ribosomal subunit implicated in translational accuracy.

Cartography of ribosomal proteins of the 30S subunit from the halophilic Haloarcula marismortui and complete sequence analysis of protein HS26

By two-dimensional polyacrylamide gel electrophoresis of 30S ribosomal subunit proteins (S proteins) from Haloarcula marismortui we identified 27 distinct spots and analyzed all of them by protein sequence analysis. We demonstrated that protein HmaS2 (HS2) is encoded by the open reading frame orfMSG and has sequence similarities to the S2 ribosomal protein family. The proteins HmaS5 and HmaS14 were identified as spots HS7 and HS21/HS22, respectively. Protein HS4 was characterized by amino-terminal sequence analysis. The spot HS25 was recognized as an individual protein and also characterized by sequence analysis. Furthermore, the complete primary sequence of HS26 is reported, showing similarity only to eukaryotic ribosomal proteins. The sequence data of a further basic protein shows a high degree of similarity to ribosomal protein S12, therefore, it was designated HmaS12. Slightly different results compared to published sequence data were obtained for the protein HS12 and HmaS19. The putative 'ribosomal' protein HSH could not be localized in the two-dimensional pattern of the total 30S ribosomal subunit proteins of H. marismortui. Therefore, it seems to be unlikely that this protein is a real constituent of the H. marismortui ribosome.

Amino acid sequence of the ribosomal protein HS23 from the halophilic Haloarcula marismortui and homology studies to other ribosomal proteins

The ribosomal protein HS23 from the 30S subunit of the extreme halophilic Haloarcula marismortui, belonging to the group of archaea, was isolated either by RP-HLPLC or two-dimensional polyacrylamide gel electrophoresis. The complete amino acid sequence was determined by automated N-terminal microsequencing. The protein consists of 123 residues with a corresponding molecular mass of 12,552 Da as determined by electrospray mass spectroscopy; the pI is 11.04. Homology studies reveal similarities to the eukaryotic ribosomal protein S8 from Homo sapiens, Rattus norvegicus, Leishmania major, and Saccharomyces cerevisiae.

Nucleotide sequence of a gene cluster encoding ribosomal proteins in the thermoacidophilic crenarchaeon Sulfolobus acidocaldarius

A 1.6 kb genomic DNA fragment derived from the extremely thermoacidophilic archaeon Sulfolobus acidocaldarius (DSM 639) comprises four open reading frames. The sequence contains three genes encoding crenarchaeal ribosomal proteins with apparent molecular masses of 6.3 kDa, 15.2 kDa and 9.9 kDa, which all represent strongly basic properties. These were identified by sequence comparison as RL46, RL31 and RL33. One open reading frame encodes a new polypeptide (22.1 kDa, pI = 7.3) with no homology to known proteins. The latter is transcribed as a common mRNA with RL46 and RL31. This gene cluster immediately precedes another cluster including genes encoding the putative SRP receptor alpha subunit as well as the putative secEp.

Two distinct yeast proteins are related to the mammalian ribosomal polypeptide L7

The RLP7 gene of Saccharomyces cerevisiae was cloned, sequenced and localized to the right arm of chromosome XIV, close to the centromere. It encodes a predicted polypeptide (RLP7p) of 322 amino acids, with a calculated molecular mass of 36 kDa and an isoelectric point of 9.6. Putative open reading frames very similar to RLP7 are present in two other yeasts, Kluyveromyces lactis and Candida utilis. The RLP7p gene product has significant sequence similarity to the S. cerevisiae YL8 polypeptide of the large ribosomal subunit (Mizuta et al., 1992), itself homologous to the L7 subunit of mammalian ribosomes. However, RLP7p and YL8 do not functionally replace each other, since an rlp7-delta::HIS3 strain is completely inviable. Judging from its predicted mass, isoelectric point and amino acid sequence, RLP7p does not correspond to any ribosomal component biochemically identified so far in S. cerevisiae, and also differs from all known ribosomal proteins by the low codon usage bias of its gene.

HL35e and HLA: primary structure of two very basic and cysteine-rich ribosomal proteins from Haloarcula marismortui

Two small and very basic ribosomal proteins have been purified from the 50S ribosomal subunit of the archaebacterium Haloarcula marismortui by RP-HPLC. The complete primary structures of these two proteins, which we refer to as HL35e and HLA, have been determined by protein chemical methods. Both proteins are characterized by a high content of basic amino acids and the presence of two pairs of cysteines in each polypeptide chain, one of which resembles the C4-zinc-finger motif. Comparison of the protein sequences with those of other ribosomal proteins revealed that HL35e shows significant sequence homology exclusively to eukaryotic ribosomal proteins, namely to yeast L35 and to L37 from rat. For HLA no homologous ribosomal protein so far known could be found. Obviously, HL35e and HLA have no counterparts in eubacterial ribosomes.

Yeast ribosomal proteins: XIII. Saccharomyces cerevisiae YL8A gene, interrupted with two introns, encodes a homolog of mammalian L7

We isolated and sequenced a gene, YL8A, encoding ribosomal protein YL8 of Saccharomyces cerevisiae. It is one of the two duplicated genes encoding YL8 and is located on chromosome VII while the other is on chromosome XVI. The haploid strains carrying disrupted YL8A grew more slowly than the parent strain. The open reading frame is interrupted with two introns. The predicted amino acid sequence reveals that yeast YL8 is a homolog of mammalian ribosomal protein L7, E.coli L30 and others.

Characterization of rps17, rp19 and rpl15: three nucleus-encoded plastid ribosomal protein genes

Approximately two-thirds of the 55 to 60 plastid ribosomal proteins are encoded in the nucleus. Since the protein products of each of these genes are needed in equal amounts for ribosome assembly, their expression may be coordinately regulated by common mechanisms. To begin to understand how the expression of these genes is regulated, we have isolated cDNA and genomic clones for three plastid ribosomal protein genes from an Arabidopsis thaliana library. The genes rps17, rpl9 and rpl15, encoding plastid ribosomal proteins CS17, CL9 and CL15, respectively, are located in the nuclear genome and Southern blot data suggest that each is a single copy gene in A. thaliana. Northern blot data show that transcripts from rps17, rpl9 and rpl15 are much more abundant in leaves and stems than they are in roots. The nucleotide sequences of each of these three genes were determined and their transcriptional initiation sites identified. rps17 transcripts have multiple 5' ends suggesting that they are initiated at multiple sites or are post-transcriptionally processed at their 5' end. rpl9 and rpl15 apparently have unique transcriptional initiation sites but are post-transcriptionally processed to remove six and three introns, respectively, from their primary transcripts. We have examined the genomic sequences for motifs that may be important for the proper expression of these genes. A 7 bp sequence motif, whose consensus is 5'-AGGCCCA-3', flanked by AT-rich regions was identified between 38 and 73 nucleotides upstream of the rps17, rpl9 and rpl15 transcriptional initiation sites.

The genes for ribosomal protein L15 and the protein equivalent to secY in the archaebacterium Haloarcula (Halobacterium) marismortui

The nucleotide sequences of the L15 gene and the secY gene, which form the last two genes of the S10/spc-operon region of Haloarcula marismortui, have been determined. The HmaL15 protein sequence translated from the DNA is 164 amino acids long, revealing 10 amino acids more at the C-terminus than the published protein sequence. The deduced HmasecY protein sequence has 487 amino acids and shows significant homology to its counterparts in Methanococcus vannielii and Escherichia coli. The gene order of the halobacterial gene cluster is similar to that in the methanogens and in eubacteria.

Organization and nucleotide sequence of ten ribosomal protein genes from the region equivalent to the spectinomycin operon in the archaebacterium Halobacterium marismortui

The nucleotide sequence has been determined of a 4700 bp region from a ribosomal protein gene cluster of Halobacterium marismortui (Haloarcula marismortui), which is equivalent to part of the spectinomycin operon of Escherichia coli. The genes were localized on the recombinant lambda EMBL3 clone PP*7, which also contains several other ribosomal protein genes from the DNA region in H. marismortui equivalent to the linked S10/spc operon. The genes analysed encode ten ribosomal proteins, namely HmaL5, HmaS14, HmaS8, HmaL6, HL5, HL24, HmaL18, HmaS5, HmaL30 and HmaL15. The gene organization of the archaebacterial cluster is similar to that in eubacteria but has two additional genes, namely those encoding HL5 and HL24, which were identified as extra proteins that are apparently not present in E. coli. These correspond to the gene products of orfd and orfe in Methanococcus vannielii and also have eukaryotic counterparts.

Primary structures of ribosomal proteins from the archaebacterium Halobacterium marismortui and the eubacterium Bacillus stearothermophilus

Approximately 40 ribosomal proteins from each Halobacterium marismortui and Bacillus stearothermophilus have been sequenced either by direct protein sequence analysis or by DNA sequence analysis of the appropriate genes. The comparison of the amino acid sequences from the archaebacterium H marismortui with the available ribosomal proteins from the eubacterial and eukaryotic kingdoms revealed four different groups of proteins: 24 proteins are related to both eubacterial as well as eukaryotic proteins. Eleven proteins are exclusively related to eukaryotic counterparts. For three proteins only eubacterial relatives-and for another three proteins no counterpart-could be found. The similarities of the halobacterial ribosomal proteins are in general somewhat higher to their eukaryotic than to their eubacterial counterparts. The comparison of B stearothermophilus proteins with their E coli homologues showed that the proteins evolved at different rates. Some proteins are highly conserved with 64-76% identity, others are poorly conserved with only 25-34% identical amino acid residues.

A small gene family in barley encodes ribosomal proteins homologous to yeast YL17 and L22 from archaebacteria, eubacteria, and chloroplasts

The amino acid sequences of two barley ribosomal proteins, termed HvL17-1 and HvL17-2, were decoded from green leaf cDNA clones. The N-terminal sequences of the derived barley proteins are 48% identical to the N-terminal amino acid sequence of protein YL17 from the large subunit of yeast cytoplasmic ribosomes. Via archaebacterial ribosomal proteins this homology extends to ribosomal protein L22 from eubacteria and chloroplast. Barley L17, and ribosomal proteins L22 and L23 from the archaebacteria Halobacterium halobium and H. marismortui, are 25-33% identical. Interestingly, the barley and archaebacterial proteins share a long, central stretch of amino acids, which is absent in the corresponding proteins from eubacteria and chloroplasts. Barley L17 proteins are encoded by a small gene family with probably only two members, represented by the cDNA clones encoding HvL17-1 and HvL17-2. Both these genes are active in green leaf cells. The expression of the L17 genes in different parts of the 7-day old barley seedlings was analyzed by semiquantitative hybridization. The level of L17 mRNA is high in meristematic and young cells found in the leaf base and root tip. In the leaf, the L17 mRNA level rapidly decreases with increasing cell age, and in older root cells this mRNA is undetectable.

Evidence for an additional archaebacterial gene cluster in Halobacterium marismortui encoding ribosomal proteins HL46e and HL30

A small and extremely basic ribosomal protein (HL46e) has been purified from Halobacterium marismortui using reversed-phase high-performance liquid chromatography (HPLC). The amino acid sequence of the protein was determined by automated N-terminal and internal sequence analysis. Comparison of this sequence with other ribosomal protein sequences from eubacteria, archaebacteria and eukaryotes revealed a strong homology to SL46e from Sulfolobus solfataricus, YeaL46 from yeast and RL39 from rat. No significant sequence similarly was found to any eubacterial ribosomal protein so far known. Using a specific oligonucleotide probe the HL46e gene was identified, cloned and the nucleotide sequence including the 5'- and 3'-flanking regions were analysed. The HL46e gene is followed by the gene coding for HL30. A putative halobacterial promoter sequence with the motive 'TTTAAA' has been localized 32 bp upstream of the HL46e gene and a putative terminator sequence localized downstream from the HL30 gene. An equivalent to this HL46e/HL30 operon is apparently not present in Escherichia coli.

Nucleotide sequence of four genes encoding ribosomal proteins from the 'S10 and spectinomycin' operon equivalent region in the archaebacterium Halobacterium marismortui

Four genes encoding ribosomal proteins HmaS17, HmaL14, HmaL24 and HS3, have been identified in the lambda EMBL3 clone PP*7 from a genomic library of the archaebacterium Halobacterium marismortui. The clone contains genes from the 'S10 and spectinomycin' operon equivalent region. Three of the deduced proteins are homologous to the corresponding Escherichia coli and Methancoccus vannielii S17, L14 and L24 proteins, as well as to eukaryotic proteins from rat or yeast. HS3 was identified as an extra protein corresponding to the gene product for orfc in M. vannielii and the eukaryotic ribosomal protein RS4 from rat. The equivalence of HmaL24 (HL16) and E. coli L24, which share only 28% identical amino acid residues, could now be shown by localizing the HmaL24 gene at the same position in the cluster.

Amino acid sequences of the ribosomal proteins HL30 and HmaL5 from the archaebacterium Halobacterium marismortui

The complete amino acid sequences of the ribosomal proteins HL30 and HmaL5 from the archaebacterium Halobacterium marismortui were determined. Protein HL30 was found to be acetylated at its N-terminal amino acid and shows homology to the eukaryotic ribosomal proteins YL34 from yeast and RL31 from rat. Protein HmaL5 was homologous to the protein L5 from Escherichia coli and Bacillus stearothermophilus as well as to YL16 from yeast. HmaL5 shows more similarities to its eukaryotic counterpart than to eubacterial ones.

Cloning and nucleotide sequence of an archaebacterial glutamine synthetase gene: phylogenetic implications

The glnA gene of the thermophilic sulphur-dependent archaebacterium Sulfolobus solfataricus was identified by hybridization with the corresponding gene of the cyanobacterium Spirulina platensis and cloned in Escherichia coli. The nucleotide sequence of the 1696 bp DNA fragment containing the structural gene for glutamine synthetase was determined, and the derived amino acid sequence (471 residues) was compared to the sequences of glutamine synthetases from eubacteria and eukaryotes. The homology between the archaebacterial and the eubacterial enzymes is higher (42%-49%) than that found with the eukaryotic counterpart (less than 20%). This was true also when the five most conserved regions, which it is possible to identify in both eubacterial and eukaryotic glutamine synthetases, were analysed.