Nucleotide sequence of the 3''-terminal region of rat 18S ribosomal DNA

Summary The 3-terminal 230 base-pairs (bp) of the gene for 18S rRNA and 40 bp of the adjoining spacer have been sequenced for the Sprague-Dawley rat. This mammalian sequence has been compared with the known sequences of yeast, fruit fly, silkworm, and frog. This study has shown that the nucleotide-sequence differences between rat and frog are the smallest among the five species, probably reflecting their evolutionary closeness and longer maturation time compared to the others. There is little similarity in the nucleotide sequences of the transcribed spacer regions of the five species compared.     

Nucleotide sequence of the 5'-terminal region of rat 18S ribosomal DNA

The 5'-terminal 597 base-pairs (bp) of the Sprague-Dawley rat 18S ribosomal RNA gee and 10 bp of the adjoining transcribed spacer have been sequenced. Previously sequenced 10 large oligonucleotides of rat 18S RNA were located in this region. This mammalian sequence has been compared with the known sequences of yeast and frog 18S rDNA's. The analysis indicates that 534 bp of the 597 bp (89%) are conserved between rat and frog sequences but only 75% of the nucleotides are conserved between rat and yeast in this region. Two large and two small sections have been identified where insertions have been introduced during evolution. Of these 58 bp long inserted sections of the rat rDNA sequence, 50 bp (86%) were G-C base-pairs.     

Nucleotide sequence relationships between vertebrate 5.8 S ribosomal RNAs.

Nucleotide sequences of the 5.8 S ribosomal RNAs from HeLa cells, Xenopus laevis and chick embryo fibroblasts were compared. Xenopus laevis 5.8 S RNA differs from that of HeLa cells in four internal positions and at the 3' end of the molecule. Chick 5.8 S RNA differs from that of HeLa cells in two positions. Six out of the seven interspecies differences are due to base substitutions. The other difference is due to the presence of an extra nucleotide, internally located, within the Xenopus 5.8 S sequence.     

Nucleotide sequence of a mosquito 18S ribosomal RNA gene.

We have sequenced an 18S ribosomal RNA gene from the mosquito, Aedes albopictus. Computer alignment of the 1950 nucleotide coding region (56% A + T) with 18S rRNA sequences from two insect and three vertebrate species revealed greater sequence divergence among the insects than among the vertebrates. Sequence alignments showed that variable region V4, which has been considered to be the most poorly conserved domain in the 18S rRNA gene, was better conserved among insects and vertebrates than was the V6 domain.     

Nucleotide sequence of a crustacean 18S ribosomal RNA gene and secondary structure of eukaryotic small subunit ribosomal RNAs

The primary structure of the gene for 18 S rRNA of the crustacean Artemia salina was determined. The sequence has been aligned with 13 other small ribosomal subunit RNA sequences of eukaryotic, archaebacterial, eubacterial, chloroplastic and plant mitochondrial origin. Secondary structure models for these RNAs were derived on the basis of previously proposed models and additional comparative evidence found in the alignment. Although there is a general similarity in the secondary structure models for eukaryotes and prokaryotes, the evidence seems to indicate a different topology in a central area of the structures.     

Nucleotide sequence and evolution of the 18S ribosomal RNA gene in maize mitochondria.

The nucleotide sequence of the gene coding for the 18S ribosomal RNA of maize mitochondria has been determined and a model for the secondary structure is proposed. Dot matrix analysis has been used to compare the extent and distribution of sequence similarities of the entire maize mitochondrial 18S rRNA sequence with that of 15 other small subunit rRNA sequences. The mitochondrial gene shows great similarity to the eubacterial sequences and to the maize chloroplast, and less similarity to mitochondrial rRNA genes in animals and fungi. We propose that this similarity is due to a slow rate of nucleotide divergence in plant mtDNA compared to the mtDNA of animals. Sequence comparisons indicate that the evolution of the maize mitochondrial 18S, chloroplast 16S and nuclear 17S ribosomal genes have been essentially independent, in spite of evidence for DNA transfer between organelles and the nucleus.     

Nucleotide sequence neighbouring a late modified guanylic residue within the 28S ribosomal RNA of several eukaryotic cells.

The nucleotide sequence of a particular T1 oligonucleotide found in 41S and 28S RNAs of several cellular cell lines (human, mouse, rat and chicken fibroblast) but absent in 45S ribosomal RNA has been deduced. Its primary structure : A-U-U*-G*-psi-U-C-A-C-C-C-A-C-U-A-A-U-A-Gp shows the presence of a modified G residue which explains the existence of this oligonucleotide in the T1 fingerprint of 41S RNA and 28S. Its absence on the 45S RNA T1 fingerprint is accounted for by a late modification.