The complete nucleotide sequence of a rice 25S.rRNA gene

The complete nucleotide (nt) sequence of a rice nuclear 25S.rRNA gene has been determined. The 25S.rRNA-coding region is 3377 bp long. The G + C content is 59.4%. The structural organization of this rRNA is very similar to that of yeast 26S rRNA.     

The complete nucleotide sequence of a rice 17S rRNA gene.

The complete nucleotide sequence of a rice nuclear 17S rRNA gene (rDNA) has been determined. The rice rDNA is 1812 bp long and its G + C content is 51.3%. This nucleotide sequence shows 79%, 80% and 80% homology to those of yeast, Xenopus laevis and rat 18S rDNAs, respectively. Divergency of nucleotide sequences is largely attributed to five blocks of highly variable regions, where eukaryotic specific sequences can be observed.     

Conserved organization of the murine immunoglobulin epsilon gene region: restriction endonuclease maps and switch-region nucleotide sequence

Various inbred mouse strains showed remarkable conservation of organization in the epsilon germline region as determined by restriction mapping. Restriction fragment length polymorphisms (RFLP) were seen in the epsilon gene region for only two of eight restriction enzymes tested. Furthermore, the RFLP did not correlate with the IgE-response phenotype for the murine strains SJL, SJA, C57BL/6, BALB/c, A/ST, and A/J. The IgE class-switch region (S epsilon) DNA from an SJL genomic clone was sequenced and was compared with S epsilon sequences from BALB/c mice. These S epsilon sequences were at least 95% homologous. Most of the S epsilon sequence differences observed between the two strains were single base pair substitutions, deletions, or insertions. The largest difference between the S epsilon sequences resulted from an insertion of seven contiguous bases seen in the SJL S epsilon region.     

Corrected nucleotide sequence of M13mp18 gene III.

There are seven differences between the actual nucleotide (nt) sequence of bacteriophage M13mp18 gene III and the previously reported nt sequence (which had been compiled based on the nt sequence of wild-type bacteriophage M13 gene III).     

The nucleotide sequence of oocyte 5S DNA in Xenopus laevis. II. The GC-rich region

The primary sequence of the GC-rich half of the repeating unit in X. laevis 5S DNA has been determined in both a single plasmid-cloned repeating unit and in the total population of repeatig units. The GC-rich half of the repeating unit contains a single long duplication of 174 nucleotides. The duplicated segment commences 73 nucleotides preceding the 5' end of the gene and terminates at nucleotide 101 of the gene. The duplicated portion of the gene, termed the pseudogene, differs by 10 nucleotides from the corresponding portion of the gene, and the remaining duplicated sequence of 73 nucleotides differs by 13 nucleotides. The plasmid-cloned repeating unit differs from the dominant sequence in the total population repeating units by 6 nucleotides in the GC-rich region. Evidence is provided that most of the CpG dinucleotides in 5S DNA are at least partially methylated.     

Nucleotide sequence and genome organization of bacteriophage S13 DNA

The complete sequence of bacteriophage S13 DNA has been determined. The molecule has 5386 nucleotides and differs from φX174 by 87 transitions and 24 transversions. All the proteins, A, A^*, B, C, D, E, F, G, H, J and K found in φX174 are also present in S13. Due to changes in the H/A intergenic region of S 13, the start of an additional protein. A′, has been identified. Genes F and H coding for the capsid and spike proteins, respectively, are the least conserved in comparison to φX174. Many of the silent changes, as well as some amino acid changes, are found in the same nucleotide sequence positions in phage G4, confirming the interrelationship between the three phages.     

Physical mapping and complete nucleotide sequence of the denV gene of bacteriophage T4.

Phage T4 deletion mutants that are folate analog resistant (far) and contain deletions in the region of the T4 genome near denV have been isolated previously. We showed that one of these mutants (T4farP12) expressed normal denV gene activity, whereas another mutant (T4farP13) was defective in the denV gene. The rII-distal (right) physical endpoints of these deletions defined the limits of the interval in which the rII-proximal (left) endpoint of the denV gene should be located. The deletion endpoints were identified by restriction and Southern hybridization analyses of phage derivatives containing deoxycytidine instead of hydroxymethyldeoxycytidine in their DNAs. The results of these analyses localized the rII-proximal (left) end of the denV gene to a region between 62.4 and 64.3 kilobases on the T4 physical map. denV+ phage resulted from marker rescue with two of five denV- alleles tested, using plasmids containing a 1.8-kilobase fragment from this region or a 179-base-pair terminal fragment derived from it. Sequencing of the 179-base-pair fragment from wild-type DNA showed a 130-base-pair open reading frame with its termination codon at the rII-proximal end. Confirmation that this open reading frame is part of the denV coding sequence was obtained by identifying a TAG amber codon in the homologous DNA derived from a denV amber mutant strain. This mutant strain rescued the denV+ allele from plasmids containing the wild-type sequence. An adjacent overlapping restriction fragment was also cloned, permitting determination of the remaining denV gene sequence. Based on these results, the 3' end of the coding region of the denV locus was mapped to kilobase position 64.07 on the T4 physical map, and the 5' end was mapped to position 64.48.