Structural organization of alpha-satellite DNA in a single monkey chromosome

The organization of α-satellite sequences in a single monkey chromosome has been studied by restriction endonuclease analysis and molecular cloning. A somatic cell hybrid containing the monkey chromosome was isolated by cloning after fusion of the mouse L-cell line B82 (thymidine kinase minus) with primary African green monkey kidney cells and selective growth in HAT medium. Unlike the mouse cells, the hybrid cells contain DNA that hybridizes with the α-satellite DNA of the monkey. The presence of a single α-satellite containing monkey chromosome was demonstrated by Giemsa-11 staining and by the absence of both this chromosome and monkey α-satellite DNA sequences in cells after back-selection in bromodeoxyuridine. Hybridization of restriction endonuclease-digested hybrid cell DNA with a cloned segment of African green monkey α-satellite DNA showed distinctly different patterns from those observed with monkey total DNA. In particular, EcoRI and HaeIII restriction endonuclease sites are much more abundant in the satellite sequences in the thymidine kinase-carrying chromosome than they are in total satellite. A library of hybrid DNA was constructed in a λ bacteriophage. Analyses of purified recombinant phage that hybridized with α-satellite also indicated an abundance of EcoRI and HaeIII sites. Of nine phage studied in detail, no two showed identical distributions of the two restriction sites in the α-satellite sequences, suggesting the independent evolution of different domains within the single chromosome. These results indicate that the thymidine kinase-carrying chromosome contains distinct subsets (domains) of the α-satellite DNA of the whole monkey genome and further, that while the satellite sequence on the single chromosome is distinctive, it is also complex.     

Members of the KpnI family of long interspersed repeated sequences join and interrupt alpha-satellite in the monkey genome.

Three different members of a family (KpnI-family) of interspersed repeated DNA sequences were found linked to alpha-satellite sequences in cloned segments of the African green monkey genome. In two of these segments the KpnI-family member is over 6 kbp in length and one of them is flanked by alpha-satellite on both sides indicating that it was inserted into a satellite array. Hybridization of subcloned portions of the family members to restriction endonuclease digests of monkey and human DNA and to a genomic library of African green monkey DNA indicate that 1) family members are interspersed in both the monkey and human genomes, 2) some family members may include sequences in addition to those in the three characterized here, 3) some family members may contain only parts of the sequences characterized here and 4) while the overall organization of the family is similar in the human and monkey genome the majority of the family members in each of the two genomes are distinctly identified by the variant position of certain restriction endonuclease sites. This last observation suggests that within each genome there is a tendency to maintain particular versions of the sequence. Observations 2) and 3) suggest that the KpnI family is complex and includes a variety of subfamilies.     

Structure of simian virus 40-phiX174 recombinant genomes isolated from single cells.

Three simian virus (SV40)-phi X174 recombinant genomes were isolated from single BSC-1 monkey cells cotransfected with SV40 and phi X174 RF1 DNAs. The individual cell progenies were amplified, cloned, and mapped by a combination of restriction endonuclease and heteroduplex analyses. In each case, the 600 to 1,000 base pairs of phi X174 DNA (derived from different regions of the phi X174 genome) were present as single inserts, located in either the early or late SV40 regions; the deletion of SV40 DNA was greater than the size of the insert; and the remaining portions of the hybrid genome were indistinguishable from wild-type SV40 DNA, as judged by both mapping and biological tests. Hence, apart from the deletion which accommodates the phi X174 DNA insert, no other rearrangements of SV40 DNA were detected. The restriction map of a SV40-phi X174 recombinant DNA isolate before molecular cloning was indistinguishable from those of two separate cloned derivatives of that isolate, indicating that the species cloned was the major amplifiable recombinant structure generated by a single recombinant-producing cell. The relative simplicity of the SV40-phi X174 recombinant DNA examined is consistent with the notion that most recombinant-producing BSC-1 cells support single recombination events generating only one amplifiable recombinant structure.     

The nucleotide sequence of repetitive monkey DNA found in defective simian virus 40.

DNA fragments containing monkey DNA sequences have been isolated from defective SV40 genomes that carry host sequences in place of portions of the SV40 genome. The fragments were isolated by restriction endonuclease cleavage and contain segments homologous to sequences in both the highly repetitive and unique (or less repetitive) classes of monkey DNA. The complete nucleotide sequence of one such fragment [151 base pairs (bp)] predominantly homologous to the highly reiterated class of monkey DNA was determined using both RNA and DNA sequencing methods. The nucleotide sequence of this homogeneous DNA segment does not contain discernible multiple internal repeating units but only a few short oligonucleotide repeats. The reiteration frequency of the sequence in the monkey genome is >10⁶. Digestion of total monkey DNA (from uninfected cells) with endonuclease R Hind III produces relatively large amounts of discrete DNA fragments that contain extensive regions homologous to the fragment isolated from the defective SV40 DNA.A second fragment, also containing monkey sequences, was isolated from the same defective substituted SV40 genome. The nucleotide sequence of the 33 bp of this second fragment that are contiguous to the 151 bp fragment has also been determined.The sequences in both fragments are also present in other, independently derived, defective substituted SV40 genomes.     

Gene amplification in methotrexate-resistant mouse cells. IV. Different DNA sequences are amplified in different resistant lines

DNA was purified from double minutes isolated from MTX-resistant EL4/8 mouse lymphoma cells, digested to completion with Bam H1 restriction endonuclease and cloned in lambda-1059. The properties of the library suggest that the DNA from which it was made was not detectably contaminated with non-dm chromosome material, and that the library is essentially complete for sequences contained in Bam H1 restriction fragments between 9 and 19 kb. The inserts of some selected lambda-recombinants were subcloned in pBR328 or pAT153 to separate sequences of differing repetition frequency. Clones representative of different classes of sequences were used as probes to Southern transfers of Bam H1 digested total nuclear DNAs of various MTX-resistant cell lines. The results clearly show that the amplified unit of each cell line has a unique structure, and that different amplified units differ widely in their sequence composition.     

A family of moderately repetitive sequences in mouse DNA.

When mouse DNA is digested to completion with restriction endonuclease Eco R1, a distinct band of 1.3 kb segments comprising about 0.5-3% of the genome is observed upon agarose gel electrophoresis. This DNA is not tandemly repeated in the genome and is not derived from mouse satellite DNA. Restriction endonuclease analysis suggested that the 1.3 kb segments are heterogeneous. Specific sequences were selected from the 1.3 kb segments and amplified by cloning in plasmid pBR322. Southern transfer experiments indicated that three separately cloned mouse DNA inserts hybridized predominantly to the Eco R1 1.3 kb band and to the conspicuous subsegments generated by secondary restriction endonuclease cleavage of the sucrose gradient purified 1.3 kb segments. Segments were also excised by Hha I (Hha I segments) from the chimeric plasmids containing mouse DNA inserts and subjected to restriction endonuclease and cross-hybridization analysis. It was found that the three Hha I segments were different, although two of them exhibited partial sequence homology. Cot analysis indicated that each of the Hha I segments are repeated about 10(4) times in the mouse genome. These findings indicate that a family of related but non-identical, moderately repetitive DNA sequences, rather than a single homogeneous repeat, is present in the 1.3 kb Eco R1 band.     

Isolation of a polymorphic DNA segment unique to human chromosome 7 by molecular cloning of hybrid cell DNA

DNA isolated from a rodent-human hybrid cell line containing human chromosomes 3, 7, 9, 10, 14 and 22 was cloned in the plasmid vector pAT153. Recombinant plasmids containing inserts of human origin were identified by colony hybridization to 32P-labelled human DNA under conditions in which only repetitive sequences interact. Single- and low-copy sequences were liberated from these plasmids by restriction endonuclease digestion and used as hybridization probes against human DNA and DNA isolated from a panel of Chinese hamster-human hybrids. One single-copy probe was shown to react with a genomic sequence unique to human chromosome 7 and to recognize an apparent restriction fragment size polymorphism in human DNA.     

A family of DNA sequences is reproducibly rearranged in the somatic nucleus of Tetrahymena.

A small family of DNA sequences is rearranged during the development of the somatic nucleus in Tetrahymena. The family is defined by 266 bp of highly conserved sequence which restriction mapping, hybridization and sequence analysis have shown is shared by a cloned micronuclear fragment and three sequences which constitute the macronuclear family. Genomic Southern hybridization experiments indicate there are five members of the family in micronuclear DNA. All of the family members are present in whole genome homozygotes and are therefore nonallelic. The three macronuclear sequences are all present in clonal cell lines and are reproducibly generated in every developing macronucleus. The rearrangement event begins 14 hours after conjugation is initiated and is nearly completed by 16 hours.     

A dimer satellite sequence in bonnet monkey DNA consists of distinct monomer subunits

A family of 342 nucleotide fragments was isolated from total bonnet monkey DNA by the restriction endonuclease HaeIII and its base sequence was determined. This family was found to consist of a dimer of two related but distinct nucleotide sequences. Both sequences are closely related to previously reported sequences from African green monkey and human DNA. The two bonnet monkey sequences are unequally divergent from the African green monkey sequence, and have fewer bases in common with each other than they do with African green monkey. Restriction of the dimer with other endonucleases confirms the inequality of the two monomers.     

Isolation and characterization of a major tandem repeat family from the human X chromosome.

We report the identification and characterization of a family of repeated restriction fragments whose molecular organization is apparently specific to the human X chromosome. This fragment, identified as an ethidium bromide-staining 2.0 kilobase (kb) band in BamHI-digested DNA from a Chinese hamster-human somatic cell hybrid containing a human X chromosome, has been cloned into pBR325 and characterized. The 2.0 kb repeated family has been assigned to the Xp11 leads to Xq12 region on the X by Southern blot analysis of somatic cell hybrids and is predominantly arranged in tandem clusters of up to seven 2.0 kb monomers. Homologous DNA sequences, not organized as 2.0 kb BamHI fragments, are found elsewhere on the X chromosome and on at least some autosomes, but are not found on the Y chromosome. From a dosing experiment using various amounts of the cloned repeat, we estimate that there are 5,000-7,500 copies of the 2.0 kb BamHI repeat per haploid genome. Since the vast majority, if not all, of these are confined to the X chromosome, this repeated DNA family must account for 5-10% of all X chromosome DNA and must constitute the major sequence component of the pericentromeric region of the X.     

Colobus type C virus: molecular cloning of unintegrated viral DNA and characterization of the endogenous viral genomes of Colobus.

The unintegrated viral DNA intermediates of colobus type C virus (CPC-1) were isolated from infected human cells that were permissive for viral growth. There were two major species of DNA, linear molecules with two copies of the long terminal repeat and relaxed circles containing only a single long terminal repeat. In addition, there was a minor species (approximately 10%) composed of relaxed circles with two copies of the long terminal repeat. A restriction endonuclease map of the unintegrated DNA was constructed. The three EcoRI fragments of circular CPC-1 DNA were cloned in the EcoRI site of lambda gtWES . lambda B and then subcloned in the EcoRI site of pBR322. Using these subgenomic fragments as probes, we have characterized the endogenous viral sequences found in colobus cellular DNA. They are not organized in tandem arrays, as is the case in some other gene families. The majority of sequences detected in cellular DNA have the same map as the CPC-1 unintegrated DNA at 17 of 18 restriction endonuclease sites. There are, however, other sequences that are present in multiple copies and do not correspond to the CPC-1 map. They do not contain CPC-1 sequences either in an altered form or fused to common nonviral sequences. Instead, they appear to be derived from a distinct family of sequences that is substantially diverged from the CPC-1 family. This second family of sequences, CPC-2, is also different from the sequences related to baboon endogenous type C virus that forms a third family of virus-related sequences in the colobus genome.     

Distribution of endogenous murine leukemia virus DNA sequences among mouse chromosomes.

We used mouse-Chinese hamster somatic cell hybrids which lose mouse chromosomes to examine the distribution of murine leukemia virus DNA sequences in the genome of A/HeJ mice. We analyzed total cellular DNA from various hybrid clones for the presence of viral sequences by molecular hybridization and used the Southern blot hybridization procedure to identify viral DNA in cellular restriction endonuclease fragments. Our results show that murine leukemia virus DNA sequences are distributed among many mouse chromosomes in this strain. Chromosome 4 was shown to contain murine leukemia virus DNA sequences.     

Structure and organization of the highly repeated and interspersed 1.3 kb EcoRI-Bg1II sequence family in mice.

EcoRI digestion of total mouse DNA yields a prominant 1.3 kb fragment amounting to between 1 and 2% of the mouse genome. The majority of the 1.3 kb EcoRI fragments have a single Bg1II site 800 bp from one end. This EcoRI-Bg1II sequence family shows HindIII and HaeIII sequence heterogeneity. We have cloned representatives of the EcoRI-Bg1II gene family in Charon 16A and studied their structure and organization within the genome. The cloned 1.3 kb fragments show the expected restriction enzyme patterns as well as additional heterogeneity. Representatives of the EcoRI-Bg1II sequence family were found to be interspersed throughout the mouse genome as judged by CsCl density gradient centrifugation experiments. Family members were also found to be organized in higher order repeating units. Homologous sequences were also found in other rodent species including rat and Chinese hamster. Cross hybridization between a cloned 1.3 kb mouse fragment and a cloned CHO repeated sequence is of special interest since the latter has been shown to contain sequences homologous to the Human A1uI family by nucleotide sequencing.     

Propagation of a segment of bacteriophage lamda-DNA in monkey cells after covalent linkage to a defective simian virus 40 genome.

A 520 base pair DNA segment was excised from the bacteriophage lamda-genome by cleavage with the bacterial restriction endonuclease, endo R. Hindll. This segment was covalently joined in vitro to an 880 base pair simian virus 40 (SV40) DNA segment which contains the initation site for SV40 DNA replication. The latter segment was derived from the genome of a defective reiteration mutant of SV40 also by endo R. Hindlll cleavage. When the recombinant molecule, together with wild-type SV40 DNA as helper, was introduced into monkey cells by DNA infection, replication of the lamda-DNA sequences was observed, and hybrid genomes were encapsidated into progeny SV40 virions. The structure of the lamda-DNA segment after serial passage in monkey cells was examined by use of restriction endonucleases and electron microscopic heteroduplex analysis.     

Isolation and characterization of a family of sequences dispersed on the human X chromosome

During a systematic search for X-specific sequences we isolated a DNA fragment (called G1.3) that hybridizes to six further homologous X-specific genomic fragments that map to at least four different regions of the human X chromosome. Genomic segments of 11-30 kb (called G1.3 a, b, c, d, and e or DNF22S1 to DNF22S5) have been subsequently cloned for five of the seven repetitions and characterized by restriction mapping. Single-copy sequences have been used to analyze homology between cloned repetitions, to confirm X specificity, and to regionally localize the repetitions. Sequence homology between members of this family seems to be very high (80-90%) and to extend over at least 5 to 12 kb. In situ hybridization and Southern blotting experiments with a panel of human-rodent hybrid cell lines demonstrated that four of the cloned sequences map to three different regions within Xp21.2-pter and the fifth one (G1.3c) maps to Xq28. The family is present with the same complexity and X specificity in macaques (20-30 x 10(6) years divergence with man), whereas no related sequences were detected in the mouse. To our knowledge small families of dispersed chromosome-specific sequences have been described only for the human Y chromosome. The possible functional or evolutionary significance of this family is discussed.     

Overlap hybridization screening: isolation and characterization of overlapping DNA fragments surrounding the leu2 gene on yeast chromosome III.

A set of four plasmids containing overlapping segments comprising a total of about 30 kbp of cloned DNA from chromosome III of yeast (Saccharomyces cerevisiae) has been isolated and characterized by restriction endonuclease analyses and DNA:DNA hybridizations. Colony hybridization was carried out with labeled pYe(leu2)10, a plasmid carrying the yeast leu2 gene, to a bank of bacterial colonies containing recombinant plasmids constructed from the vector ColE1 and random fragments of yeast DNA. This resulted in the detection of two plasmids, pYe11G4 and pYe40C3, with DNA inserts which partially overlap the original cloned segment and contain additional DNA extending in opposite directions on the chromosome. By carrying out a second round of colony hybridization with pYe40C3, the cloned region was further extended in one direction. A region of DNA that is repeated at least ten times in the yeast genome was identified by hybridization of pYe11G4 to an EcoRI digest of total yeast DNA. The procedure described in this paper should allow the isolation of large sections of chromosomes, including non-transcribed regions, surrounding cloned genes.     

Assignment of the human gene for beta-microseminoprotein (MSMB) to chromosome 10 and demonstration of related genes in other vertebrates.

The gene for beta-microseminoprotein MSMB has been studied by DNA hybridization and molecular cloning techniques. Comparative analysis of restriction endonuclease digests of the cloned gene and of leukocyte DNA strongly suggested that the gene is present in a single copy in the haploid human genome. By Southern blot analysis of DNA from somatic cell hybrids, the gene was assigned to chromosome 10. The coding nucleotides of the human gene are separated into four exons by relatively large introns. A related gene might be present in other mammals, birds, and amphibians as revealed by DNA hybridization under conditions of low stringency.