Characterization of the bovine prothrombin gene

The bovine prothrombin gene was characterized by Southern blot analysis of bovine genomic DNA using bovine prothrombin cDNA fragments as hybridization probes. These analyses suggested that the bovine genome contains a single prothrombin gene that is at least 10 kilobase pairs (kbp) in size. To characterize the gene more thoroughly, two bovine genomic phage libraries were screened by using prothrombin cDNAs as hybridization probes. Heteroduplex analysis of the cloned genomic DNA and cDNA showed that the prothrombin gene is 14.9 kbp in size and contains at least 14 exons interrupted by 13 introns. The exons vary in size from 28 to 317 base pairs (bp), while the introns vary in size from less than 100 to 6940 bp. Regions of self-complementarity were observed within some of the introns, suggesting the presence of inverted repeat sequences. The bovine prothrombin gene shows similarities in structure to both the human prothrombin gene and the human factor IX gene.     

Features of the DNA fingerprinting probe pITZ1

Stringently controlled plasmids generate DNA fingerprint patterns in mammals when used at low hybridization temperatures. In order to develop a probe for use in paternity testing in cattle we screened a bovine, partial genomic plasmid library with the PCR-amplified ori region of plasmid P1. Of eight isolated clones one generated strong band patterns at high stringency in various mammalian species (data not shown). Sequence analysis revealed an imperfect, compound dinucleotide repeat region, which was PCR-amplified and cloned into the plasmid vector pUC19. Fingerprint results generated by this probe (termed pITZ1) in cattle are compared with the results generated by VNTR-probe pV47, which itself was developed by screening a human chromosome 16 library with tandem repeats of bacteriophage M13. Probe pITZ1 is useful in conjunction with other VNTR-probes for DNA fingerprinting in cattle and donkey populations. The dinucleotide repeat region responsible for the band patterns generated with pITZ1 is close to an Alu -like sequence, which may be involved in eukaryotic replication mechanisms.     

Autonomous DNA replication in human cells is affected by the size and the source of the DNA.

We previously developed short-term and long-term assays for autonomous replication of DNA in human cells. This study addresses the requirements for replication in these assays. Sixty-two random human genomic fragments ranging in size from 1 to 21 kb were cloned in a prokaryotic vector and tested for their replication ability in the short-term assay. We found a positive correlation between replication strength and fragment length, indicating that large size is favored for efficient autonomous replication in human cells. All large fragments replicated efficiently, suggesting that signals which can direct the initiation of DNA replication in human cells are either very abundant or have a low degree of sequence specificity. Similar results were obtained in the long-term assay. We also used the same assays to test in human cells a random series of fragments derived from Escherichia coli chromosomal DNA. The bacterial fragments supported replication less efficiently than the human fragments in the short-term and long-term assays. This result suggests that while the sequence signals involved in replication in human cells are found frequently in human DNA, they are uncommon in bacterial DNA.     

Telomere repeat DNA forms a large non-covalent complex with unique cohesive properties which is dissociated by Werner syndrome DNA helicase in the presence of replication protein A

We describe the unique structural features of a large telomere repeat DNA complex (TRDC) of >20 kb generated by a simple PCR using (TTAGGG)₄ and (CCCTAA)₄ as both primers and templates. Although large, as determined by conventional agarose gel electrophoresis, the TRDC was found to consist of short single-stranded DNA telomere repeat units of between several hundred and 3000 bases, indicating that it is a non-covalent complex comprising short cohesive telomere repeat units. S1 nuclease digestion showed that the TRDC contains both single- and double-stranded portions stable enough to survive glycerol density gradient centrifugation, precipitation with ethanol and gel electrophoresis. Sedimentation analysis suggests that a part of the TRDC is non-linear and consists of a three-dimensional network structure. After treatment with Werner DNA helicase the TRDC dissociated into smaller fragments, provided that human replication protein A was present, indicating that: (i) the TRDC is a new substrate for the Werner syndrome helicase; (ii) the telomere repeat sequence re-anneals rapidly unless unwound single-stranded regions are protected by replication protein A; (iii) the TRDC may provide a new clue to understanding deleterious telomere–totelomere interactions that can lead to genomic instability. Some properties of the TRDC account for the extra-chromosomal telomere repeat (ECTR) DNA that exists in telomerase-negative immortalized cell lines and may be involved in maintaining telomeres.     

Human Sau3A repeated DNA is enriched in small polydisperse circular DNA from normal lymphocytes

Representatives of the Sau3A family of short human repeated sequences [Meneveri et al., J. Mol. Biol. 186 (1985) 483-489] have been isolated from the small polydisperse circular DNA (spcDNA) of peripheral human lymphocytes. The prototype repeat is a 72-bp element which is at least partially tandemly repeated in spcDNA and human genomic DNA. In comparison with three major families of human repeated DNA, the Sau3A repeats are enriched in spcDNA. The function of spcDNA in normal and transformed eukaryotic cells is not understood and most studies have attempted to resolve this problem by molecular analysis of circular DNA isolated from cells in culture [see Rush and Misra, Plasmid 14 (1985) 177-191 for references]. We have studied the spcDNA present in normal uncultured human lymphocytes and present data pointing to the selective accumulation of the Sau3A family of repeated DNA within this population. The sequences of twelve of these repeats, the consensus sequence for this family and the sequence of a genomic repeat, are presented.     

Genomic representation of the Hind II 1.9 kb repeated DNA.

The genomic representation and organization of sequences homologous to a cloned Hind III 1.9 kb repeated DNA fragment were studied. Approximately 80% of homologous repeated DNA was contained in a genomic Hind III cleavage band of 1.9 kb. Double digestion studies indicated that the genomic family, in the majority, followed the arrangement of the sequenced clone, with minor restriction cleavage variations compatible with a few base changes. Common restriction sites external to the 1.9 kb sequence were mapped, and hybridization of segments of the cloned sequence indicated the 1.9 kb DNA was itself not tandemly repeated. Kpn I bands which were homologous to the sequence contained specific regions of the repeat, and the molecular weight of these larger fragments could be simply explained. Mapping of common external restriction sites indicated that in some but not all cases the repeat could be organized in larger defined blocks of greater than or equal to 5.5 kb. In some instances, flanking regions adjacent to the repeat may contain common DNA elements such as other repeated DNA sequences, or possibly rearranged segments of the 1.9 kb sequence. It is suggested that although the 1.9 kb sequence is not strictly contiguous, at least some of these repeated sequences in the human genome are arranged in clustered or intercalary arrays. A region of the 1.9 kb sequence hybridized to a mouse repeated DNA, indicating homology beyond the primates.     

Replication time of interspersed repetitive DNA sequences in hamsters

The replication time of 34 hamster genomic DNA segments containing interspersed repeat sequences was determined by probing the cloned segments with nick-translated early- and late-replicating hamster DNA. One-third of these cloned families replicated early, one-third replicated late, and one-third replicated without temporal bias. 19 different inserts from these clones along with the SINE, Alu, and the LINE, A36Fc, were used to probe Southern blots of early- and late-replicating hamster or human DNA. We report long interspersed repeats, LINEs, are selectively partitioned into late-replicating DNA and are often concertedly hypomethylated, while short interspersed repeats, SINEs, are selectively partitioned into early-replicating DNA. For some interspersed repeat families, this partitioning is complete or almost complete. The CCGG frequency is very low in late-replicating DNA. The mammalian chromosome's pattern of early-replicating R-bands and late-replicating G-bands reflects a differential distribution of LINEs and SINEs.     

A large DNA repeat of the dispersion pattern common to wheat and rye genomes

A Hind III-generated fragment of wheat embryo nuclear DNA has been cloned and sequenced. The cloned fragment corresponds to a 1241 bp long, moderately repeated (60 000 copies/genome) segment of the genomic DNA. The repeat is AT-rich (67%), contains an open reading frame for 151 amino acids and several nucleotide blocks resembling the consensus domain of autonomously replicating sequences. Southern blot hybridization analyses indicate that the repeat is scattered through the wheat genome. A sequence homologous to this repeat occurs also in rye embryo nuclear DNA where it shows the same dispersion pattern as that observed for the wheat repeat.     

Chromosome-specific DNA repeat probes.

In research as well as in clinical applications, fluorescence in situ hybridization (FISH) has gained increasing popularity as a highly sensitive technique to study cytogenetic changes. Today, hundreds of commercially available DNA probes serve the basic needs of the biomedical research community. Widespread applications, however, are often limited by the lack of appropriately labeled, specific nucleic acid probes. We describe two approaches for an expeditious preparation of chromosome-specific DNAs and the subsequent probe labeling with reporter molecules of choice. The described techniques allow the preparation of highly specific DNA repeat probes suitable for enumeration of chromosomes in interphase cell nuclei or tissue sections. In addition, there is no need for chromosome enrichment by flow cytometry and sorting or molecular cloning. Our PCR-based method uses either bacterial artificial chromosomes or human genomic DNA as templates with alpha-satellite-specific primers. Here we demonstrate the production of fluorochrome-labeled DNA repeat probes specific for human chromosomes 17 and 18 in just a few days without the need for highly specialized equipment and without the limitation to only a few fluorochrome labels.     

Human thymidylate synthase gene: isolation of phage clones which cover a functionally active gene and structural analysis of the region upstream from the translation initiation codon

Two genomic DNA fragments partially encoding human thymidylate synthase (TS) [EC 2.1.1.45] were previously cloned in lambda phage from the mouse cell transformant, but had no transforming activity on mouse TS-negative mutant cells. In this study, an additional genomic DNA for human TS was cloned and demonstrated to have the transforming activity in combination with one of the two previously cloned DNAs and to produce human TS mRNA. The two transforming genomic DNAs overlapped and covered a region of 23 kb in total. Using fragments from one of these DNAs, the structure of the 1.2-kb region around the ATG initiator codon of the TS gene was analyzed in relation to regulatory sequences of the gene. Sequence determination demonstrated the presence of an unusual inverted repeat consisting of a triple tandem repeat of a 28-bp sequence and an inverted sequence of the same length. These sequences can form three possible, stable, stem-loop structures, which may be interconvertible. Based on S1 nuclease mapping data and a line of circumstantial evidence, we deduced two major mRNA cap sites within the inverted sequence. Comparison of the human and mouse sequences upstream from the ATG initiator codon revealed many significant blocks of sequence homology, especially in the regions around the deduced cap sites.     

Sequence analysis of bovine satellite I DNA (1.715 gm/cm3).

The 1402 bp Eco RI repeating unit of bovine satellite I DNA (rho CsCl = 1.715 gm/cm3) has been cloned in pBR322. The sequence of this cloned repeat has been determined and is greater than 97% homologous to the sequence reported for another clone of satellite I (48) and for uncloned satellite I DNA (49). The internal sequence structure of the Eco RI repeat contains imperfect direct and inverted repeats of a variety of lengths and frequencies. The most outstanding repeat structures center on the hexanucleotide CTCGAG which, at a stringency of greater than 80% sequence homology, occurs at 26 locations within the RI repeat. Two of these 6 bp units are found within the 31 bp consensus sequence of a repeating structure which spans the entire length of the 1402 bp repeat (49). The 31 bp consensus sequence contains an internal dodecanucleotide repeat, as do the consensus sequences of the repeat units determined for 3 other bovine satellite DNAs (rho CsCl = 1.706, 1.711a, 1.720 gm/cm3). Based on this evidence, we present a model for the evolutionary relationship between satellite I and the other bovine satellites.     

Molecular cloning of the cDNA of human X chromosomal gene (CCG1) which complements the temperature-sensitive G1 mutants, tsBN462 and ts13, of the BHK cell line.

The tsBN462 cell line, a temperature-sensitive (ts) mutant isolated from the hamster cell line, BHK21/13 has a ts defect in G1 progression and belongs to the same complementation group as the ts13 cell line. We cloned human cDNA which can complement both tsBN462 and ts13 mutations, from the cDNA library of the secondary ts+ transformant (K-1-1) of tsBN462 cells using, as a probe, the isolated human X chromosomal genomic DNA. The cloned DNA is 5.3 kb long and has an open reading frame of 4662 bp, encoding a protein of 178,768 daltons. The putative protein is hydrophilic with a tandem repeat of 120 amino acids in the C-terminal region. An amino acid sequence (PPKKKRRV), similar to the consensus sequence for the nuclear translocation signal, is located immediately before the tandem repeat of amino acids.     

Molecular cytogenetic analysis of DNA sequences with flanking telomeric repeats in Triticum aestivum cv. Begra.

A cloned genomic DNA fragment (pTa241) formerly derived from a DNA fraction obtained from isolated nuclei of embryos of a Polish cultivar of wheat (Triticum aestivum cv. Begra) comprises a tandem repeat of the telomeric array CCCTAAA, and hybridizes in situ exclusively to the telomeres of all chromosome arms of the somatic chromosome complement of wheat. A second cloned fragment (pTa637) derived from the same fraction is 637 bp long, flanked by 28 bp of the same telomeric repeat unit, and hybridizes in situ to the entire lengths of all the chromosomes of the complement. The same pattern of hybridization was observed when the flanking telomeric sequences were removed. A third DNA fragment (pTa1439), derived from unfractionated genomic DNA and flanked with 62 bp of the same telomeric unit, showed the same patterns of distribution. Together with additional evidence from Southern analysis, these observations were interpreted to mean that these sequences are associated with mobile DNA elements and are distributed widely throughout the genome. The chromosomal distribution of the non-telomeric parts of the clones is consistent with the dispersed genomic distribution characteristic of transposons and retroelements.