Bending of a highly repetitive component in rat nuclear DNA.

A highly repetitive component in rat nuclear DNA was isolated by HindIII digestion and cloned. A 370-bp cloned component was highly AT-rich (68.3%) in about one third of the region from the 3'-terminus and showed an anomalously slow gel electrophoretic mobility (k-factor = 1.19). These results indicated that a sequence-directed bending of the helix axis occurs in the component. Accordingly, a subclone containing a tandem dimer of the component was isolated and subjected to a circular permutation analysis for exploring the bend center (1). In consequence, the center was shown to be present in the sequence ranging from position near 270 to the 3'-terminus and estimated to be located around position 340.     

Nucleotide sequence of a highly repetitive component of rat DNA.

A highly repetitive component of rat DNA which could not yet be enriched by density gradient centrifugation was isolated with the help of the restriction nuclease Sau3AI. This nuclease converted the bulk of the DNA to small fragments and left a repetitive DNA component as large fragments which were subsequently purified by gel filtration and electrophoresis. This DNA component which was termed rat satellite DNA I is composed of tandemly repeated 370 bp blocks. According to sequence analysis the 370 bp repeats consist of alternating 92 and 93 bp units with homologous but not identical sequences. Methylation of CpG residues was correlated to the rate of cleavage by restriction nucleases. Significant homologies exist between the sequences of rat satellite DNA I and satellite DNAs of several other organisms. The divergence of the sequence of rat satellite DNA I was discussed with respect to evolutionary considerations.     

Structure and properties of a highly repetitive DNA sequence in sheep

Cleavage of sheep DNA with the restriction endonuclease EcoR I yields three discrete size classes (370, 435 and 800bp) of highly repetitive DNA. The 435bp long fragment was cloned and its nucleotide sequence determined. All three classes of repetitive DNA are related to each other as seen by cross-hybridisation. They are tandemly arranged in the genome and in situ hybridisation to sheep lymphocyte chromosomes show their location mainly in the centromere region of all chromosomes. The primary sequence of the repetitive DNA shows a close structural similarity to the bovine 1.715 satellite DNA, however only poor cross-hybridisation between the sheep and cattle repetitive DNA could be shown.     

Evaluation of methods for sequence analysis of highly repetitive DNA templates.

The DNA Sequencing Research Group (DSRG) of the ABRF conducted a study to assess the ability of DNA sequencing core facilities to successfully sequence a set of well-defined templates containing difficult repeats. The aim of this study was to determine whether repetitive templates could be sequenced accurately by using equipment and chemistries currently utilized in participating sequencing laboratories. The effects of primer and template concentrations, sequencing chemistries, additives, and instrument formats on the ability to successfully sequence repeat elements were examined. The first part of this study was an analysis of the results of 361 chromatograms from participants representing 40 different laboratories who attempted to sequence a panel of difficult-to-sequence templates using their best in-house protocols. The second part of this study was a smaller multi-laboratory evaluation of a single robust protocol with the same panel of templates. This study provides a measure of the potential success of different approaches to sequencing across homopolymer tracts and repetitive elements.     

Interspersion of repetitive sequences in rat liver DNA

In rat liver DNA, which contains only 20% repetitive sequences, a close interspersion of repetitive and unique sequences is found in about 35 % of the total DNA. The mean length of repetitive and unique alternating sequences is respectively 230 and 400 base pairs.     

Characterisation of a novel repetitive DNA sequence from Mycobacterium bovis

We report characterisation of three copies of a novel repeat sequence isolated from a Mycobacterium bovis genomic library. The repeat occurs within open reading frames, potentially encoding a conserved tandem array of a pentapeptide sequence with the consensus X-Gly-Asn-X-Gly. The tandem array is present up to five times in M. bovis and it is proposed that they may occur in a family of genes expressing functionally related proteins. We postulate that these proteins may play a role in binding of M. bovis to host cell receptors.     

A new moderately repetitive rat DNA sequence detected by a cloned 4.5 SI DNA

4.5 SI RNA is an abundant, noncapped, small nuclear RNA found in rodent cells. The 4.5 SI RNA is 98 or 99 nucleotides long and contains no modified nucleotides; it is synthesized by RNA polymerase III, is partly hydrogen-bonded to poly(A+) hnRNA, and was the first small nuclear RNA to be purified and sequenced (Busch, H., Reddy, R., Ruthblum, L., and Choi, Y. C. (1982) Annu. Rev. Biochem. 51, 617-654). In studies on the structure and organization of genes coding for this abundant RNA, it was found that this RNA is homologous to an apparently novel family of repetitive sequences. Two clones were characterized; one clone showed that its sequence is identical to the RNA in the first 92 residues and differed only in the last six nucleotides. In addition, the 3'-end of the sequence contained an A,T-rich region, and the sequence was flanked by a 15-nucleotide long direct repeat of AAAATATAGACACTG. The second clone characterized contained nucleotide sequences 1-57 corresponding to the RNA and was flanked by a 15-nucleotide long direct repeat. The structural features of these two DNAs are consistent with RNA-mediated DNA synthesis and integration of this DNA into the genome at random sites. It is estimated that there are about 10,000 copies of this family of sequences in the haploid rat genome.     

Isolation of nuclear acidic proteins from rat tissues. Characterization of acetylated liver nuclear acidic proteins

Nuclear acidic proteins isolated from rat brain, heart, kidney and liver showed similar, complex patterns on electrophoresis in sodium dodecyl sulphate-polyacrylamide gels. The contamination of nuclear acidic proteins by nuclear-membrane acidic proteins was found to the extent of 11%. Incorporation of [(3)H]acetate into the various nuclear acidic proteins in vivo, which were fractionated by polyacrylamide-gel electrophoresis, differed from tissue to tissue. Hydrolysis of these acetylated nuclear acidic proteins with 6m-HCl at 110 degrees C released 70% of the radioactivity, which indicated that labile acetyl groups had been incorporated into these proteins. Analysis of [(3)H]acetate-labelled nuclear acidic proteins revealed two acetylated amino acid residues, N(2)-acetylserine and N(2)-acetyl-lysine. The significance of the role played by nuclear acidic proteins in relation to gene regulation is discussed.     

Nucleotide sequences of highly repetitive DNA from scleractinian corals

The staghorn coral genome contains 5% of a satellite DNA, consisting of 80 to 300 x 10(3) copies of a 118-bp repeat unit per haploid Acropora genome.     

Sequence analysis of nuclear matrix associated DNA from rat liver

The DNA associated with the nuclear matrix of rat liver was studied. The amount of DNA associated with the matrix varied with the concentration of DNase used in its preparation, but approached a plateau value of 1% of total nuclear DNA. We next studied the sequence complexity of this residual DNA. Using C₀t analyses, it was found that the complexity of matrix DNA was the same as that of total nuclear DNA, indicating that matrix DNA does not represent any specific sequence class. However, using ¹²⁵I-labeled ribosomal RNA (rRNA) as a probe, we found that the genes for rRNA are significantly enriched in the residual matrix DNA. The implications of these results are discussed.     

A comparison of nuclear and nucleolar matrix proteins from rat liver

The comparison of the gel electrophoresis patterns of nuclear and nucleolar matrix proteins reveals marked differences between these structures. The nucleolar matrix contains 5 prominent protein bands ( mol.wt.: 8.2; 7.0; 5.6; 4.0 and 3.0 x 10 4 ) which are not found in nuclei. It is suggested that the nucleolar matrix has a distinct structure participating in selective interactions.