We have determined the nucleotide sequences of the two internal transcribed spacers, the adjacent ribosomal coding sequences and the boundary between the external transcribed spacer and the 18S coding sequence in a cloned ribosomal transcription unit from Xenopus borealis. The transcribed spacers differ very extensively from those of X. laevis. Nevertheless, embedded in the internal transcribed spacers are several short sequence elements which are identical between the two species. These conserved elements are laterally displaced by substantial distances in the X. borealis sequence with respect to that of X. laevis. These relative displacements imply that insertions and deletions have played a major role in transcribed spacer divergence in Xenopus. This in turn implies that large regions of the transcribed spacers do not play a sequence-specific role in ribosome maturation. In contrast, the sequenced parts of the ribosomal coding regions, which encompass 670 nucleotides, differ at only three points from the corresponding sequences in X. laevis, each by a single substitution. These substitutions are readily accommodated by current models for rRNA higher order structure.
We report sequence data from a cloned rDNA unit from Xenopus borealis, extending leftwards from the 18S gene to overlap a region previously sequenced by R.Bach, B.Allet and M.Crippa (Nucleic Acids Research 9,[5311][5312][5313][5314][5315][5316][5317][5318][5319][5320][5321][5322][5323][5324][5325][5326][5327][5328][5329][5330].Comparison with data from other species of Xenopus leads to the inference that the transcription initiation site in X.borealis is in the newly sequenced region and not, as was previously thought, in the region sequenced earlier.The X.borealis external transcribed spacer thus defined is some 612 nucleotides long, about 100 nucleotides shorter than in X.laevis. The X.borealis and X.laevis external transcribed spacers show a pattern of extensive but interrupted sequence divergence, with a large conserved tract starting about 100 nucleotides downstream from the transcription initiation site and shorter conserved tracts elsewhere.The regions in between the conserved tracts differ in length between the respective external transcribed spacers indicating that insertions and deletions have contributed to their divergence, as previously inferred for the internal transcribed spacers.Much of the overall length difference is in the region flanking the 18S gene, where there are also length microheterogeneities in X.laevis rDNA.As in X.laevis, the transcribed spacer sequences flanking the 18S gene in X.borealis contain no major tracts of mutual complementarity. The accumulated data on transcribed spacers in Xenopus render it unlikely that processing of ribosomal precursor RNA involves interaction between the regions flanking 18S RNA.
The effects of infection with the herpes virus pseudorabies virus on the metabolism of HeLa cell ribosomal RNA were examined. There is a decline both in the synthesis of nucleolar 45S ribosomal precursor RNA and in its processing to mature cytoplasmic RNA. The methylated oligonucleotides in the ribosomal RNA species were studied. The methylation of cytoplasmic ribosomal RNA was essentially unchanged. However there was some undermethylation of the nucleolar precursor. If undermethylated RNA does not mature then this may partly explain the reduced processing in the infected cells.
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