The Drosophila melanogaster RPS17 gene encoding ribosomal protein S17

A human ribosomal protein S17 cDNA [Chen et al., Proc. Natl. Acad. Sci. USA 83 (1986) 6907-6911] was used as heterologous probe to isolate S17 clones from Drosophila genomic and cDNA recombinant libraries. Five S17 genomic clones were recognized; all contained overlapping regions of a single chromosomal site. Subsequently the Drosophila RPS17 gene was mapped by in situ hybridization to chromosome 3L, band 67B1-5. The locus spans approximately 1000 bp of DNA and includes four exons. It is preceded by conventional CAAT and TATA RNA polymerase II promoter motifs. The 131 amino acid protein encoded within Drosophila RPS17 is similar to ribosomal proteins from several other eukaryotes. Comparison of eukaryotic S17 proteins' primary structures as well as the number and location of their genes' intervening sequences suggest that S17 is a relatively recent addition to the ribosomal protein family, probably post-dating divergence of eukaryotes and prokaryotes.     

rig encodes ribosomal protein S15. The primary structure of mammalian ribosomal protein S15

rig, a gene originally isolated from a rat insulinoma cDNA library, codes for a basic 145 amino acid protein [( 1986) Diabetes 35, 1178-1180]. Here we show that the immunoreactivity to a monoclonal antibody against the deduced rig protein and the translation product of rig mRNA comigrated with ribosomal protein S15. The amino acid sequence of ribosomal protein S15 purified from rat liver coincided with that deduced from the nucleotide sequence of rig mRNA, but there were indications that the initiator methionine was removed and the succeeding alanyl residue was monoacetylated. From these results, we conclude that the product of rig is ribosomal protein S15.     

The human 18S ribosomal RNA gene: evolution and stability.

We report the 1,870-base-pair primary sequence of a human 18S rRNA gene and propose a secondary structure based on this sequence and the general mammalian structure. A basic secondary structure for the small subunit rRNA has been preserved throughout evolution by compensatory and neutral base changes in double-stranded regions. The molecule contains eight regions that can vary in structure and that comprise 432 bases, while 1,438 bases belong to regions of conserved structure among all species tested. The conserved regions show a remarkably low sequence divergence rate of 0.1% between the human and mouse genes over the approximately 80 million years since the mammalian radiation. This value may make the small subunit rDNA the most highly conserved sequence known. Sequence conservation in higher eukaryotes with multiple copies of the gene is probably achieved by the combination of strong selection and the correction of tandem genes by unequal homologous exchange.     

Plant cytosolic ribosomal protein S11 and chloroplast ribosomal protein CS17. Their primary structures and evolutionary relationships

We have isolated cDNA clones specific for Arabidopsis thaliana cytosolic ribosomal protein S11 and plastid ribosomal protein CS17, both of which are encoded in the nuclear genome, through the use of the corresponding soybean and pea cDNAs as probes, respectively. The nucleotide sequences of all four cDNAs were determined. The amino acid sequences derived from these cDNA sequences show that the soybean and A. thaliana S11 cDNAs encode proteins that are homologous to rat ribosomal protein S11 and that the pea and A. thaliana CS17 cDNAs encode proteins that are homologous to Escherichia coli ribosomal protein S17. The plant S11 cytosolic ribosomal proteins also show significant sequence similarity to both E. coli ribosomal protein S17 and plastid CS17 indicating that these are all related proteins. Comparison of A. thaliana CS17 with A. thaliana S11 and with E. coli S17 suggests that CS17 is more related to S17 than it is to S11. These results support the idea that the gene encoding CS17 was derived from a prokaryotic endosymbiont and not from a duplication of the eukaryotic S11 gene.     

The human ribosomal protein S6 gene: isolation, primary structure and location in chromosome 9.

Using PCR cloning we isolated the first intron of the human ribosomal protein S6 gene (hRPS6). By screening the human HeLa cell cDNA library in lambda ZAPII vector (Stratagene, La Jolla, CA), we identified and sequenced a partially spliced pre mRNA copy of hRPS6. The complete hRPS6 gene was isolated from a lambda DASH library with an intron-specific probe. The gene and flanking regions were sequenced, and the mRNA 5' end was mapped by primer extension experiments. The hRPS6 gene has 6 exons and 5 introns and is 3.6 kb long. Using intron-specific primers in PCR and a panel of human-hamster cell lines we localized the hRPS6 gene in human chromosome 9.