A family of moderately repetitive sequences in mouse DNA

Mouse euchromatin specific "genome-painting" with a LINE probe: a rapid method for identification and mapping of human chromosomes in mouse-human microcell hybrids by two-color FISH

We describe the use of a long interspersed repetitive sequence (mCPE1.51) for mouse euchromatin specific "genome-painting". In fluorescence in situ hybridization (FISH) experiments, this probe was suitable for identification of the mouse genome and disclosure of translocations of mouse chromosome segments to chromosomes of different species without suppression hybridization. The euchromatin specificity of the probe allowed the discrimination between euchromatin and heterochromatin of mouse chromosomes. Simultaneous hybridization of the biotinylated mouse specific genome-painting probe and a digoxigenin-labeled human chromosome 3-specific cosmid probe to metaphase spreads of mouse-human microcell hybrid carrying a single deleted human chromosome 3 on a mouse fibrosarcoma background, allowed rapid identification and mapping of human chromosome 3.

Instability of long inverted repeats within mouse transgenes

Various sequences in the mammalian genomes are unstable. One class of sequence arrangement is long inverted repeats, which are known to be unstable in bacteria and yeast. While in mammals some evidence suggests that short inverted repeats (<10 bp long) may show instability, nothing is known about the stability of long inverted repeats. Here we describe two unrelated multicopy transgenes in the mouse (loci 109 and OX1-5), each of which contains a long inverted repeat that shows substantial mitotic instability. This instability also occurs in the germline so that mutant transgenes appear within pedigrees at a high frequency. The mutation processes acting at these two inverted repeats are complex and can involve insertion or deletion, and can result in stabilization of the transgene. At transgene 109 mutational events range from very small rearrangements at the centre of the inverted repeat to complete transgene deletion. In addition we show that the rates of mutation at the inverted repeat of transgene OX1-5 can vary between the male and female germlines and between inbred strains of mice, suggesting the possibility of a genetic analysis to identify loci that modulate inverted repeat instability.

Identification and characterization of a novel conserved DNA repeat

Homozygous In(10)17Rk mice contain a paracentric inversion within Chromosome (Chr) 10 and exhibit a pygmy phenotype, suggesting that the distal inversion breakpoint is within the pygmy (pg) locus. In order to obtain the pygmy gene by positional cloning procedures, In(10)17Rk DNA was subjected to RFLP analysis with single-copy probes derived from the wild-type pygmy locus. This analysis identified a DNA polymorphism in the DBA/2J mouse strain on which the In(10)17Rk mutation was originally induced. A detailed characterization of this polymorphism revealed the presence of a novel, tandemly repeated DNA element. Copy number estimation experiments indicate that there are approximately 100,000 copies of this element in the haploid DBA/2J genome. PCR typing studies revealed the presence of the repeat at the pygmy locus of 6 of the 18 Mus domesticus strains analyzed. The absence of the repeat from the pygmy locus of 12 strains of the M. domesticus species and from the M. caroli, M. spretus, M. castaneus, and M. molossinus species suggests that the repeat could serve as a strain-specific hybridization probe in genetic mapping studies. Finally, the novel tandem DNA repeat is conserved in both rat and human genomes as indicated by Southern hybridization experiments.

Identification of transcriptional regulatory activity within the 5' A-type monomer sequence of the mouse LINE-1 retroposon

LINE-1 (L1) is a retroposon found in all mammals. In the mouse, approximately 10% of L1 elements are full-length and can be grouped into two classes, A or F, based upon the type of monomer sequence repeated at the 5' end. In order to test for promoter activity in the 5' end of the A-type mouse L1 element, we cloned several different A-monomers into a promoterless chloramphenicol acetyltransferase (CAT) vector. The A-monomer constructs varied in their ability to regulate transcription of the CAT gene, exhibiting CAT activity 16-37% of that detected with the Rous sarcoma virus promoter and enhancer. A series of A-monomer deletions were tested for their ability to regulate CAT expression and gel retardation experiments were performed to identify regions of the A-monomer that may be involved in L1 transcriptional regulation. A-monomer sequences are usually found repeated 2-5 times at the 5' end of a full-length mouse L1. In the absence of long terminal repeats or an internal promoter, the tandem array of A-monomers may provide a mechanism for A-type L1 elements to generate transcripts containing transcriptional regulatory sequences.

Empty and occupied insertion site of the truncated LINE-1 repeat located in the mouse serum albumin-encoding gene

Taking advantage of the polymorphism created by the presence or the absence of a LINE-1 repeat in intron 12 of the mouse serum albumin-encoding gene, we sequenced the repeat (Alb-L1Md), as well as the flanking regions in BALB/c DNA. The empty insertion site in a wild-type mouse of the same species Mus domesticus was amplified using PCR and sequenced. The Alb-L1Md was truncated at its 5' end and bordered by two 14-bp repeats, which represented the duplication of the empty insertion site. The absence of mutations in the two direct repeats as well as in the poly(dA) tail suggests that the Alb-L1Md sequence had been inserted very recently. On the basis of the insertion sequence of intron 12 and of the sequence of the consensus L1Md repeat, 5' of the insertion, we discuss a model of integration of full-length L1Md-RNA leading to the truncation of the inserted repeat.

DNA synthesis arrest sites at the right terminus of rat long interspersed repeated (LINE or L1Rn) DNA family members

An approximately equal to 150-bp GC-rich (approximately equal to 60%) region is at the right end of rat long interspersed repeated DNA (LINE or L1Rn) family members. We report here that one of the DNA strands from this region contains several non-palindromic sites that strongly arrest DNA synthesis in vitro by the prokaryotic Klenow and T4 DNA polymerases, the eukaryotic alpha polymerase, and AMV reverse transcriptase. The strongest arrest sites are G-rich (approximately equal to 70%) homopurine stretches of 18 or more residues. Shorter homopurine stretches (12 residues or fewer) did not arrest DNA synthesis even if the stretch contains 11/12 G residues. Arrest of the prokaryotic polymerases was not affected by their respective single strand binding proteins or polymerase accessory proteins. The region of duplex DNA which contains DNA synthesis arrest sites reacts with bromoacetaldehyde when present in negatively supercoiled molecules. By contrast, homopurine stretches that do not arrest DNA synthesis do not react with bromoacetaldehyde. The presence of bromoacetaldehyde-reactive bases in a G-rich homopurine-containing duplex under torsional stress is thought to be caused by base stacking in the homopurine strand. Therefore, we suggest that base-stacked regions of the template arrest DNA synthesis.

Molecular cloning of the murine adenosine deaminase gene from a genetically enriched source: identification and characterization of the promoter region

A genomic library was prepared with DNA from a genetically enriched mouse cell line in which amplified copies of the adenosine deaminase (ADA) gene account for over 5% of the genome. Overlapping cosmid clones encompassing the entire ADA structural gene were isolated from this genomic library and used for subsequent structural and functional analyses. Nuclease protection and primer extension analyses served to identify the location of multiple transcription initiation sites at the 5' end of the structural gene. Promoter activity was found by functional analyses to reside within a 240-base-pair fragment which contains the transcription initiation sites. Sequences upstream of the transcription initiation sites are very G + C rich (77%) and include a 22 nucleotide stretch of deoxyguanylate residues and two potential Sp1 transcription factor-binding sites. Comparison of the mouse and human ADA gene promoters revealed the presence of several regions that are highly conserved with regard to both sequence content and location and may represent genetic elements which are involved in ADA gene expression.

Structure of the highly repeated, long interspersed DNA family (LINE or L1Rn) of the rat

We present the DNA sequence of a 6.7-kilobase member of the rat long interspersed repeated DNA family (LINE or L1Rn). This member (LINE 3) is flanked by a perfect 14-base-pair (bp) direct repeat and is a full-length, or close-to-full-length, member of this family. LINE 3 contains an approximately 100-bp A-rich right end, a number of long (greater than 400-bp) open reading frames, and a ca. 200-bp G + C-rich (ca. 60%) cluster near each terminus. Comparison of the LINE 3 sequence with the sequence of about one-half of another member, which we also present, as well as restriction enzyme analysis of the genomic copies of this family, indicates that in length and overall structure LINE 3 is quite typical of the 40,000 or so other genomic members of this family which would account for as much as 10% of the rat genome. Therefore, the rat LINE family is relatively homogeneous, which contrasts with the heterogeneous LINE families in primates and mice. Transcripts corresponding to the entire LINE sequence are abundant in the nuclear RNA of rat liver. The characteristics of the rat LINE family are discussed with respect to the possible function and evolution of this family of DNA sequences.

The sequence of a large L1Md element reveals a tandemly repeated 5' end and several features found in retrotransposons

The complete nucleotide sequence of a 6,851-base pair (bp) member of the L1Md repetitive family from a selected random isolate of the BALB/c mouse genome is reported here. Five kilobases of the element contains two overlapping reading frames of 1,137 and 3,900 bp. The entire 3,900-bp frame and the 3' 600 bp of the 1,137-bp frame, when compared with a composite consensus primate L1 sequence, show a ratio of replacement to silent site differences characteristic of protein coding sequences. This more closely defines the protein coding capacity of this repetitive family, which was previously shown to possess a large open reading frame of undetermined extent. The relative organization of the 1,137- and 3,900-bp reading frames, which overlap by 14 bp, bears resemblance to protein-coding, mobile genetic elements. Homology can be found between the amino acid sequence of the 3,900-bp frame and selected domains of several reverse transcriptases. The 5' ends of the two L1Md elements described in this report have multiple copies, 4 2/3 copies and 1 2/3 copy, of a 208-bp direct tandem repeat. The sequence of this 208-bp element differs from the sequence of a previously defined 5' end for an L1Md element, indicating that there are at least two different 5' end motifs for L1Md.

Specific association between type-II intracisternal A-particle elements and other repetitive sequences in the mouse genome

The majority of type-II intracisternal A-particle (IAP) element clones isolated from a mouse genomic library also contained highly repetitive DNA sequences in addition to the moderately repetitive IAP elements. Further analysis revealed that eleven of the twelve clones contained sequences of the mouse L1 family. One clone contained four copies of a limited region of the 3' end of the L1 element in a 12-kb stretch of sequence. This clone also contained a newly identified repetitive sequence which is found associated with type-II IAP elements. Type-II IAP elements were completely methylated in mouse embryo DNA; in myeloma cells, partial demethylation of the sequences correlated with known transcriptional activity of the IAP subclasses. Analysis of genomic DNA showed that association with other repetitive sequences appears to be a general property of many type-II IAP elements and may reflect their location in a particular chromosomal environment.

Molecular cloning of the murine adenosine deaminase gene from a genetically enriched source: identification and characterization of the promoter region

A genomic library was prepared with DNA from a genetically enriched mouse cell line in which amplified copies of the adenosine deaminase (ADA) gene account for over 5% of the genome. Overlapping cosmid clones encompassing the entire ADA structural gene were isolated from this genomic library and used for subsequent structural and functional analyses. Nuclease protection and primer extension analyses served to identify the location of multiple transcription initiation sites at the 5' end of the structural gene. Promoter activity was found by functional analyses to reside within a 240-base-pair fragment which contains the transcription initiation sites. Sequences upstream of the transcription initiation sites are very G + C rich (77%) and include a 22 nucleotide stretch of deoxyguanylate residues and two potential Sp1 transcription factor-binding sites. Comparison of the mouse and human ADA gene promoters revealed the presence of several regions that are highly conserved with regard to both sequence content and location and may represent genetic elements which are involved in ADA gene expression.

Characterization of a complementary deoxyribonucleic acid for the coagulogen of Limulus polyphemus

An 869-nucleotide-long cDNA clone for the coagulogen from Limulus amebocyte has been isolated and its nucleotide sequence has been determined. The deduced amino-acid sequence revealed a signal peptide, 20 amino acids long, and a mature protein of 175 amino acids. The amino-acid sequence of the coagulogen was compared to all known proteins by two computer programs. Using these programs, Limulus coagulogen showed 70% homology with the coagulogen of Tachypleus tridentatus (Japanese horseshoe crab). Further computer analysis showed no statistically significant homology to support an evolutionary origin of the horseshoe crab coagulogen common to other protein families. These results place horseshoe crab coagulogen in a new superfamily unrelated to any other proteins investigated. RNA blot analysis of Limulus RNA indicated that the coagulogen mRNA was about 900 bases long and represented an abundant species in the amebocyte while detected only in small quantities in the hepatopancreas. Besides mature RNA, high-molecular-weight forms of coagulogen RNA were also observed. Southern blot analysis of Limulus DNA digested with restriction endonucleases suggested that the Limulus coagulogen gene contains at least three introns, or belongs to a multigene family.

Conservation in the 5' region of the long interspersed mouse L1 repeat: implications of comparative sequence analysis

A clone of 7.1kb corresponding to the mouse L1 interspersed repeat family was selected for homology to a human interspersed repeat. This clone fairly represents mouse genomic members. Mapping of the clone revealed one common element at both the 5' and 3' ends in a head to tail arrangement, suggesting that at least some long L1 family members are tandemly arranged; genomic studies confirmed the unexpected tandem arrangement of a minor proportion of L1 members. A short SmaI tandem repeat appears to define the 5' end of most L1 family members. SmaI repeats may maintain, via a recursive regulatory function, the transcriptional viability of L1 members after retroposition events. A 2.5kb portion of the mouse L1 repeat that has not been previously sequenced is presented. It is 55-70% homologous to a corresponding portion of the human KpnI repeat family. Comparative sequence analysis revealed that one common open reading frame may conserve potential coding function across species. A second open reading frame bears an asymmetric distribution of codon replacements unlike both genes and pseudogenes. This latter feature could be consistent with a proposed chromosome organization function that is unrelated to peptide expression.

Structure of the highly repeated, long interspersed DNA family (LINE or L1Rn) of the rat

We present the DNA sequence of a 6.7-kilobase member of the rat long interspersed repeated DNA family (LINE or L1Rn). This member (LINE 3) is flanked by a perfect 14-base-pair (bp) direct repeat and is a full-length, or close-to-full-length, member of this family. LINE 3 contains an approximately 100-bp A-rich right end, a number of long (greater than 400-bp) open reading frames, and a ca. 200-bp G + C-rich (ca. 60%) cluster near each terminus. Comparison of the LINE 3 sequence with the sequence of about one-half of another member, which we also present, as well as restriction enzyme analysis of the genomic copies of this family, indicates that in length and overall structure LINE 3 is quite typical of the 40,000 or so other genomic members of this family which would account for as much as 10% of the rat genome. Therefore, the rat LINE family is relatively homogeneous, which contrasts with the heterogeneous LINE families in primates and mice. Transcripts corresponding to the entire LINE sequence are abundant in the nuclear RNA of rat liver. The characteristics of the rat LINE family are discussed with respect to the possible function and evolution of this family of DNA sequences.

Conservation throughout mammalia and extensive protein-encoding capacity of the highly repeated DNA long interspersed sequence one

We report an investigation of the structure, evolutionary history, and function of the highly repeated DNA family named Long Interspersed Sequence One (L1). Hybridization studies show, first, that L1 is present throughout marsupial and placental mammalian orders. Second, L1 is more homologous within these species than between them, which suggests that it has undergone concerted evolution within each mammalian lineage. Third, on the whole L1 diverges in accordance with the fossil record. This suggests that it arose in each lineage rather by inheritance from a common ancestral family, which was present in the progenitor to mammals, than by cross-species transmission. Alignment of 1.6 X 10(3) bases of primate and mouse L1 DNA sequences shows a predominance of silent mutations within aligned long open reading frames, indicating that at least this part of L1 has produced functional protein. The observation of additional long open reading frames in further unaligned DNA sequences suggests that a minimum of 3.2 X 10(3) bases or at least half of the L1 structure is a protein-coding sequence. Thus L1, which contains about 100,000 members in mouse, is by far the most repetitive family of which a subset comprises functional protein-encoding genes. The ability of the putative protein-encoding regions of mouse L1 to hybridize to L1 homologs throughout the Mammalia implies that these sequences have been subject to conservative selection upon protein function in all mammalian lineages, rather than in a few. L1 is therefore a highly repeated family of genes with both a widespread and an ancient history of function in mammals.

Decreased methylation of the major mouse long interspersed repeated DNA during aging and in myeloma cells

Sequences of DNA that hybridize on Southern blots with cloned EcoR1 1.3 kb (ER1) of long interspersed repeated sequence (L1Md) of mouse have been examined in genomic DNA of neonatal mice, livers and brains of adult mice (3, 10, 27, and 30 mo old), and the solid myeloma tumor MOPC-315. The isoschizomers Hpa II (CCGG or mCCGG) and Msp I (CCGG or CmCGG) were used to assess methylation. We found that the L1Md sequence is fully methylated in young animals but demethylated in myeloma. Demethylation of L1Md sequence also occurred in aged animals. By scanning the autoradiogram, we found that approximately 8% of the 10(4)-10(5) copies have been demethylated in 27-mo-old liver.

Complete nucleotide sequence of an EcoRI-1.35-kb repeated element of mouse: homology with the cellular flanking region between two intracisternal A-particle genes

The complete DNA sequence (1369 bp) of an EcoRI-1.35-kb repeated element (ER-1) of the mouse BamHI family has been determined. Analysis of this sequence revealed that a portion of the 3' end (positions 1277-1369) of ER-1 was found to share 91% homology with the flanking cellular sequence between two adjacent intracisternal A-particle (IAP) genes, IAP-19A and IAP-19B.

The sequence of a large L1Md element reveals a tandemly repeated 5' end and several features found in retrotransposons

The complete nucleotide sequence of a 6,851-base pair (bp) member of the L1Md repetitive family from a selected random isolate of the BALB/c mouse genome is reported here. Five kilobases of the element contains two overlapping reading frames of 1,137 and 3,900 bp. The entire 3,900-bp frame and the 3' 600 bp of the 1,137-bp frame, when compared with a composite consensus primate L1 sequence, show a ratio of replacement to silent site differences characteristic of protein coding sequences. This more closely defines the protein coding capacity of this repetitive family, which was previously shown to possess a large open reading frame of undetermined extent. The relative organization of the 1,137- and 3,900-bp reading frames, which overlap by 14 bp, bears resemblance to protein-coding, mobile genetic elements. Homology can be found between the amino acid sequence of the 3,900-bp frame and selected domains of several reverse transcriptases. The 5' ends of the two L1Md elements described in this report have multiple copies, 4 2/3 copies and 1 2/3 copy, of a 208-bp direct tandem repeat. The sequence of this 208-bp element differs from the sequence of a previously defined 5' end for an L1Md element, indicating that there are at least two different 5' end motifs for L1Md.

The 45-kb unit of major urinary protein gene organization is a gigantic imperfect palindrome

The multigene family which codes for the mouse major urinary proteins consists of about 35 genes. Most of these are members of two distinct groups, group 1 and group 2. The group 1 and group 2 genes are organized in head-to-head pairs within 12 to 15 remarkably uniform chromosomal units or domains about 45 kilobase pairs (kb) in size. The 45-kb units are located on chromosome 4, and many of them are adjacent to each other. We propose that the 45-kb unit is a unit both of organization and of evolutionary change. In this study the homologies within the unit were observed by examining, in an electron microscope, heteroduplex and foldback structures made from cloned major urinary protein genes. These show that the 45-kb unit is a gigantic imperfect palindrome. Each arm of the palindrome contains two regions of inverted symmetry of 9.5 and 4.5 kb separated by a 3-kb nonsymmetrical region. We argue that the nonsymmetrical regions arose by a series of deletion events in the two arms of the palindrome. The center of the 45-kb unit is an 8-kb sequence without inverted symmetry flanked by the 9.5-kb regions, which contain the 4-kb genes and their immediate 5' and 3' flanking regions. The junction between adjacent 45-kb units is a 2- to 4-kb sequence without inverted symmetry flanked by the 4.5-kb regions. Some of the 45-kb units are arranged as direct tandem repeats. Others appear to be in inverted orientation with respect to a neighboring unit. Cloned major urinary protein genes show few incidences of the repetitive elements B1, B2, R, and MIF. Two elements, a B1 and an R, may be a constant feature of the 45-kb units. If so, in those cases in which the units are in tandem array, both of these elements will occur with a 45-kb periodicity. A comparison of corresponding parts of different 45-kb units shows that they differ because of a number of deletion or insertion events, particularly in the regions 3' to the genes.

The 45-kb unit of major urinary protein gene organization is a gigantic imperfect palindrome

The multigene family which codes for the mouse major urinary proteins consists of about 35 genes. Most of these are members of two distinct groups, group 1 and group 2. The group 1 and group 2 genes are organized in head-to-head pairs within 12 to 15 remarkably uniform chromosomal units or domains about 45 kilobase pairs (kb) in size. The 45-kb units are located on chromosome 4, and many of them are adjacent to each other. We propose that the 45-kb unit is a unit both of organization and of evolutionary change. In this study the homologies within the unit were observed by examining, in an electron microscope, heteroduplex and foldback structures made from cloned major urinary protein genes. These show that the 45-kb unit is a gigantic imperfect palindrome. Each arm of the palindrome contains two regions of inverted symmetry of 9.5 and 4.5 kb separated by a 3-kb nonsymmetrical region. We argue that the nonsymmetrical regions arose by a series of deletion events in the two arms of the palindrome. The center of the 45-kb unit is an 8-kb sequence without inverted symmetry flanked by the 9.5-kb regions, which contain the 4-kb genes and their immediate 5' and 3' flanking regions. The junction between adjacent 45-kb units is a 2- to 4-kb sequence without inverted symmetry flanked by the 4.5-kb regions. Some of the 45-kb units are arranged as direct tandem repeats. Others appear to be in inverted orientation with respect to a neighboring unit. Cloned major urinary protein genes show few incidences of the repetitive elements B1, B2, R, and MIF. Two elements, a B1 and an R, may be a constant feature of the 45-kb units. If so, in those cases in which the units are in tandem array, both of these elements will occur with a 45-kb periodicity. A comparison of corresponding parts of different 45-kb units shows that they differ because of a number of deletion or insertion events, particularly in the regions 3' to the genes.

Transcription of the mouse dihydrofolate reductase gene proceeds unabated through seven polyadenylation sites and terminates near a region of repeated DNA

We observed equimolar transcription throughout the 35-kilobase mouse dihydrofolate reductase structural gene. Transcription termination occurred within a discrete region (900 base pairs) located 1 kilobase beyond the last of seven functional polyadenylation sites and near a repetitive DNA sequence element. The results imply that a distinct genetic signal may be associated with the process of transcription termination.

Repetitive DNA sequences within and around the rat prolactin gene

Repetitive DNA sequences in and around the rat prolactin gene were identified and mapped by hybridizing labeled total rat DNA to cloned prolactin DNA and by hybridizing labeled prolactin DNA fragments to total restricted rat DNA. Repeated sequences were found 12-8 and 2.5-0.5 kb upstream of the first exon, within the fourth intron and throughout almost the entire 15.5 kb of cloned DNA downstream from the last exon. By cross-hybridization of the major repeated sequences, it was found that these repeats could be grouped into three families, one of which is novel. Human alu and mouse alu-like probes did not hybridize to the rat prolactin DNA. Several of the repeats from the rat prolactin gene hybridized to the intron and downstream flanking regions of the rat growth hormone gene.

Structural organization of interspersed repetitive elements present in the DNA of Mus musculus

Two-dimensional displays of the restriction fragments from the DNA of Mus musculus revealed a complex species-specific pattern produced from nonsatellite repetitive sequences. The patterns have been used as a guide in the direct purification of a group of broadly interspersed repeated DNA sequences (characterized by a 1350-bp Eco-Bam fragment) that have been studied by molecular cloning, restriction mapping and genomic Southern blotting. These studies show that the cloned representatives originate from an abundant group of sequences that share homology with about 2% of the mouse genome. The sequences do not appear to share homology with mouse-interspersed-family-1 (MIF-1) nor with the major AT-rich satellite sequences of mouse. They appear to be part of a group of larger repetitive elements that is both broadly interspersed and heavily methylated in normal mouse tissue.

Transcription of the mouse dihydrofolate reductase gene proceeds unabated through seven polyadenylation sites and terminates near a region of repeated DNA

We observed equimolar transcription throughout the 35-kilobase mouse dihydrofolate reductase structural gene. Transcription termination occurred within a discrete region (900 base pairs) located 1 kilobase beyond the last of seven functional polyadenylation sites and near a repetitive DNA sequence element. The results imply that a distinct genetic signal may be associated with the process of transcription termination.

Most highly repeated dispersed DNA families in the mouse genome

The construction of a small library of mouse repetitive DNA has been previously reported (Pietras et al., Nucleic Acids Res. 11:6965-6983, 1983). Here we report that the 35 plasmids in this library corresponding to highly repeated (greater than 30,000 copies per genome) dispersed DNA sequences can be grouped into no more than 5 distinct families. These families together comprise 8 to 10% of the mouse genome. They include the previously described small elements B1, B2, and R and the large MIF-1 element. Twelve of the 35 clones contain evolutionarily conserved (EC) sequences. One EC clone in our library mostly consists of alternating dCdT residues; another consists of tandem repeats of the sequence CCTCT. The majority of B1s and B2s in the genome appear to be homogeneous, whereas R sequences, ECs, and MIF-1s are heterogeneous. Two earlier reports showed highly repeated mammalian DNA sequences in the herpesvirus genome (Peden et al., Cell 31:71-80, 1982; Puga et al., Cell 31:81-87, 1982). We show that sequences homologous to our EC clones are present in the herpesvirus genome, although these polypyrimidine stretches are not detected in poxvirus, adenovirus, and simian virus 40 genomes. We detect transcripts containing homology to all of these sequences in a nuclear transcription assay. Also, we show that small, polyadenylated RNA molecules homologous to B2 sequences are expressed in undifferentiated embryonal carcinoma cells but not in their differentiated derivatives. The significance of these findings is discussed.

Most highly repeated dispersed DNA families in the mouse genome

The construction of a small library of mouse repetitive DNA has been previously reported (Pietras et al., Nucleic Acids Res. 11:6965-6983, 1983). Here we report that the 35 plasmids in this library corresponding to highly repeated (greater than 30,000 copies per genome) dispersed DNA sequences can be grouped into no more than 5 distinct families. These families together comprise 8 to 10% of the mouse genome. They include the previously described small elements B1, B2, and R and the large MIF-1 element. Twelve of the 35 clones contain evolutionarily conserved (EC) sequences. One EC clone in our library mostly consists of alternating dCdT residues; another consists of tandem repeats of the sequence CCTCT. The majority of B1s and B2s in the genome appear to be homogeneous, whereas R sequences, ECs, and MIF-1s are heterogeneous. Two earlier reports showed highly repeated mammalian DNA sequences in the herpesvirus genome (Peden et al., Cell 31:71-80, 1982; Puga et al., Cell 31:81-87, 1982). We show that sequences homologous to our EC clones are present in the herpesvirus genome, although these polypyrimidine stretches are not detected in poxvirus, adenovirus, and simian virus 40 genomes. We detect transcripts containing homology to all of these sequences in a nuclear transcription assay. Also, we show that small, polyadenylated RNA molecules homologous to B2 sequences are expressed in undifferentiated embryonal carcinoma cells but not in their differentiated derivatives. The significance of these findings is discussed.

A large interspersed repeat found in mouse DNA contains a long open reading frame that evolves as if it encodes a protein

DNA sequence analysis of a region contained within a large, interspersed repetitive family of mice reveals a long open reading frame. This sequence extends 978 base pairs between two stop codons, creating a reading frame that is open for 326 amino acids. The DNA sequence in this region is conserved between three distantly related Mus species, as well as between mouse and monkey, in a manner that is characteristic of regions undergoing selection for protein function.

Methylation patterns of repetitive DNA sequences in germ cells of Mus musculus

The major and the minor satellite sequences of Mus musculus were undermethylated in both sperm and oocyte DNAs relative to the amount of undermethylation observed in adult somatic tissue DNA. This hypomethylation was specific for satellite sequences in sperm DNA. Dispersed repetitive and low copy sequences show a high degree of methylation in sperm DNA; however, a dispersed repetitive sequence was undermethylated in oocyte DNA. This finding suggests a difference in the amount of total genomic DNA methylation between sperm and oocyte DNA. The methylation levels of the minor satellite sequences did not change during spermiogenesis, and were not associated with the onset of meiosis or a specific stage in sperm development.

Long interspersed repeated sequences of the mouse genome

Long interspersed repeated sequences of the mouse genome can be prepared by digesting reassociated DNA with single-strand nuclease. Length resolution reveals many discrete bands that can be assigned to 15 kbp and 6 kbp groups. The reassociated 6 kbp group (which we identify with the MIF-1 family) possesses significant sequence heterogeneity, evidenced by the production of several smaller fragments upon single-strand nuclease digestion of heteroduplexes. The sites of sequence heterogeneity are relatively few and can be mapped using additional restriction endonuclease cuts. We have mapped additional restriction sites into this group, particularly within a cloned HindIII 400 bp fragment, and have also clearly mapped one end of this relatively homogeneous long interspersed repeated sequence.

The Bam repeats of the mouse genome belong in several superfamilies the longest of which is over 9 kb in size

Mouse DNA contains two equally abundant, homologous subfamilies of MspI 3.6 and 5 kb repeated fragments. The first subfamily corresponds to the previously described (1) Bam 4 kb repeats, the second one to Bam repeated fragments of higher molecular weight. These subfamilies account for the vast majority of long Bam repeats and are linked with contiguous short Bam 0.5 kb repeats. A minority of these composite Bam repeats extend, on the 0.5 kb side, into R repeats. In turn, a fraction of the composite Bam/R repeats extend further, for at least 3 kb, into other repeated sequences contiguous to the R repeats. The long Bam repeats belong, therefore, in at least three superfamilies of repeats, the longest one being over 9 kb in size. Some general properties of these superfamilies are discussed.

Cell lineage-specific undermethylation of mouse repetitive DNA

Several distinct cell lineages are established during mouse embryogenesis. The trophectoderm and primitive endoderm give rise to extraembryonic structures alone, while the primitive ectoderm becomes the fetus proper. Recent studies suggest that the levels of DNA modification are lower in inactive X chromosomes from extraembryonic tissues than in embryonic and adult somatic tissues. Using HpaII/MspI isoschizomers, Southern blots and cloned probes, we show here that repetitive DNA sequences from all derivatives of the two extraembryonic lineages, trophectoderm and primitive endoderm, are substantially undermethylated compared with primitive ectoderm derivatives. This contrasts with the highly methylated state of these repetitive elements observed in adult somatic tissues. Specific demethylation or inhibition of de novo methylation, or a combination of both mechanisms, may be involved. These findings suggest that elements of gene regulation dependent on DNA modification may be different in extraembryonic cell lineages.

Organization of the R family and other interspersed repetitive DNA sequences in the mouse genome

Six R sequences have been described as members of a new family of dispersed repetitive DNA in the mouse genome (Gebhard et al., 1982). Several sequenced regions were extended in the 5' direction (R1, R2 and R6) and two new sequences were determined (R7 and R8). On the basis of our sequence and blot hybridization data it is concluded that the R sequence are adjacent to the so-called small Bam family (Fanning, 1982), which in turn runs into the MIF sequence part (Brown & Piechaczyk, 1983) of the large Bam sequences (Meunier-Rotival et al., 1982). In one of our clones a sequence of 1290 base-pairs comprises MIF, Bam and R sequences in a contiguous arrangement which seems to be characteristic of the long repeat unit of the mouse genome. Several repeat units were found to be truncated within their Bam or R sequence parts. Evidence is also reported for transposition events involving R sequences; for instance of one R sequence (R1) into another (R7). Two R sequences (R1 and R4) have apparently been transposed together with part of the adjacent Bam sequences. Truncation and transposition events may also explain the imbalance of copy numbers within the large repeat unit (25,000 to 50,000 for the small Bam sequences and 100,000 for the R sequences). The spreading of R sequences and other interspersed DNA sequences within the mouse genome may have occurred by transposition events on the DNA level and/or by transcription, retrotranscription and insertion processes.

Size and structure of the highly repetitive BAM HI element in mice

The BAM HI family of long interspersed DNAs in mice represent as much as 0.5% of the mouse genome. Cloned mouse DNA fragments which contain BAM HI/non-BAM HI junction sequences have been analyzed by restriction mapping and DNA sequencing. It has been found that BAM HI elements: (i) are approximately 7 kilobase pairs in size, (ii) are not bracketed by long repeated sequences analogous to the terminal repeats of proviruses and (iii) contain a poly-dA track at one end. The data strongly suggest that BAM HI elements arose by a process involving RNA intermediates. The beginning of the element, opposite the poly-dA track, contains a 22 base pair sequence exhibiting 65% homology to a ubiquitous mammalian sequence which may play a role in DNA replication (1). The poly-dA end of the element contains BAM5 and R sequences, both of which have been described previously (2,3).

Insertion sequences and tandem repetitions as sources of variation in a dispersed repeat family

Sequencing of ten clones from the major dispersed repeat family of mouse (MIF-1) has identified two novel types of sequence variation. Two clones contain small insertion sequences that are flanked by five base-pair duplications of the target site. A third clone, MIFC70, contains a 20 base-pair insertion composed of four direct repeats of a five base-pair sequence. This insertion may have arisen by successive out-of-register pairing and cross-over events at an ancestral target sequence. MIFC70 is also distinguished by its divergence from the standard MIF-1 sequence; whereas for standard clones of the MIF-1 family inter-copy divergence does not exceed 10%, the divergence between MIFC70 and standard clones is of the order of 26%. MIFC70 may represent an aberrant copy which is now isolated from the bulk of the repeat family and is free to diverge.

Novel repetitive sequence families showing size and frequency polymorphism in the genomes of mice

A middle repetitive sequence, PR1, originally found in mouse rDNA appeared as satellite-like bands when EcoRI and BglII digests of genomic DNA were subjected to Southern blot hybridization using PR1 as probe. The copy number and sizes of PR1-related satellite-like bands, designated as PR1 families, differed remarkably among the subspecies and laboratory strains of mice when the EcoRI digests of genomic DNAs were compared. These bands were not detected in rat and human DNAs. A unit of PR1 sequence was determined by examining cloned EcoRI 3.5 kb (kb, 10(3) bases) fragment and 6.6 kb rDNA by cross-hybridization and sequence analysis: 3.5 kb and 6.6 kb DNAs are composed of homologous PR1 regions and the flanking non-homologous sequences. The results indicate that amplification of different sequences containing PR1 has occurred in different subspecies and strains of mice, and that the segments of satellite-like bands are likely to have been created by recombination of the PR1 sequence with other DNA segments before amplification. The chromosomal distribution of the 3.5 kb PR1 family was studied by back-crossing the female F1 between BALB/c and DDD/1 to male DDD/1. The segregation data strongly suggest that most, if not all, of this family are located on a single chromosome. The stability of these PR1 families in the genomes of cultured cells of a given strain was also examined. An extra band homologous to PR1 appeared in their genomes, but was not detected in other tissues, indicating that some PR1 families may change even during cell propagation.

Association of two different repetitive DNA elements near immunoglobulin light chain genes

Sequence studies of repetitive DNA elements approximately 6 kb 3' of the mouse immunoglobulin CK region gene show that the R element located there (Gebhard et al. (1982) J. Mol. Biol. 157, 453-471) is adjacent to a 500 base pair long element which shows 80% homology to the BAM5 element sequenced by Fanning (Nuc. Acids Res. (1982), 10, 5003-5013). Neither the BAM5 element nor the R element itself is surrounded by a direct repeat, but the composite element (BAM5 + R) is surrounded by a 15 base pair direct repeat (with one mismatch). Direct repeats, consisting of target site sequences that surround a repetitive DNA element, are thought to arise during the insertion of the element at that site. It therefore appears that the BAM5 and R elements interacted and inserted as a linked entity. The existence of other BAM5/R composites throughout the mouse lambda chain locus indicates that BAM5-R cooperation is not a rare event.

Relationships among DNA sequences of the 1.3 kb EcoRI family of mouse DNA

The genome of the mouse (Mus musculus) contains a family of repeated DNA sequences defined by a 1.3 kb EcoRI fragment. Restriction maps of ten cloned fragments from this family have been determined. The fragments were of seven different types, based on the patterns of digestion obtained with AvaII, HindIII, and TaqI restriction enzymes. These seven unique sets of sequences fell into two classes, as defined by the position of a single HindIII site. Portions of fragments from each of the two classes were sequenced. Although certain regions of the repeat were highly conserved between classes, there was more intraspecific sequence divergence among the sequenced regions than has been observed for the short interspersed Alu family of repeated sequences in mammals. Sequences of both HindIII classes were found to be present within the mouse X chromosome; we can conclude that both classes must also be present on other mouse chromosomes.

Nonrandom distribution of repeated DNA sequences with respect to supercoiled loops and the nuclear matrix

The DNA in a eukaryotic nucleus is arranged into a series of supercoiled loops that are anchored at their bases to the nuclear matrix. We have analyzed the DNA sequences that are closest to the matrix attachment points for their relative content of specific repeated sequences. Sequences were enriched (mouse satellite, human Alu family) or depleted (mouse EcoRI repeat, monkey alpha component), depending on the specific sequence and species examined. These results can be understood in terms of a nonrandom arrangement of DNA sequences with respect to nuclear DNA loops.

Mouse EcoRI satellite DNA contains a sequence homologous to the long terminal repeat of the intracisternal A particle gene

EcoRI restriction endonuclease fragments from the mouse 1,350-base-pair EcoRI satellite sequence were cloned in pBR322 plasmid. One of these fragments, SAT-1, was hybridized to various restriction fragments from cloned mouse intracisternal type A particle (IAP) genes and to mouse total genomic DNA. Hybridization occurred between the SAT-1 sequence and each of the IAP clones. The common region of hybridization in each of the clones was the long terminal repeat region of the IAP genes.

Characterization of a highly repetitive family of DNA sequences in the mouse

A large proportion (0.5-1%) of total mouse DNA is cleaved by Bam HI into fragments whose size is about 500 base pairs. A cloned member of this repetitive family of DNA sequences (BAM5 family) was sequenced by the dideoxy chain termination procedure and shown to contain 507 base pairs. The sequence exhibited no unusual or remarkable features. Repetitive sequences complementary to the cloned BAM5 fragment were found in rat DNA, but not in feline or human DNA. Restriction mapping suggested that many BAM5 sequences were components of much larger repetitive DNAs which were scattered throughout the mouse genome. The BAM5 sequences within the larger repetitive DNAs did not appear to be arranged tandemly or as members of scrambled tandem repeats. RNA homologous to the cloned BAM5 sequence was detected in cultured mouse cells, but not in cultured rat cells.

The effect of 5-azadeoxycytidine on cell growth and DNA methylation

By growing cells in the presence of 3 mM thymidine and 5-azadeoxycytidine up to 20% of DNA cytosines have been substituted with azacytosine. No substitution was obtained on incubating with 5-methyldeoxycytidine. Azacytosine-substituted DNA has a very low level of 5-methylcytosine and cells, which survive azadeoxycytidine treatments maintain this low level of methylation in the absence of the drug. The DNA of such cells is undermethylated fairly evenly in all classes of DNA e.g., satellite and unique DNA. Incubation of cells in azadeoxycytidine leads to high cell mortality which is not related to the lack of DNA methylation but may be linked to the altered interactions of proteins with the substituted DNA. This effect, rather than reduced DNA methylation, may be the cause of differentiative changes observed on treatment of cells with 5-azacytidine.

Sequence organization and genomic distribution of the major family of interspersed repeats of mouse DNA

We have investigated that organization and the distribution of a family of interspersed DNA repeats in the mouse genome. The repeats are at least 5600 base pairs (bp) in size and contain two contiguous BamHI endonuclease fragments, 4000 and 540 bp in size, the larger of which includes a 1350-bp EcoRI fragment studied by previous authors. The repeats are polymorphic in their restriction maps, and represent the major family of interspersed repeats in the mouse genome. The repeats are present almost exclusively in the two light major components of mouse DNA, and the base composition of their large BamHI fragments matches that of those components. The genomic distribution of the repeats is different from that of structural genes, which are present not only in the two light components but also in the two heavy components of mouse DNA. This distribution indicates that the repeats are not involved, at least in any simple way, in the regulation of gene expression.

A member of a new repeated sequence family which is conserved throughout eucaryotic evolution is found between the human delta and beta globin genes

A new class of human interspersed repeated sequences distinct from the AluI family was found by screening a human gene library with a mouse ribosomal gene non-transcribed spacer probe (rDNA NTS). A member of this sequence family was localized to a 251 bp segment between the human delta and beta globin genes: a region previously judged to be devoid of repeated DNA. The complete nucleotide sequence of this segment revealed a tandem block of 17 TG dinucleotides, a feature hypothesized by others to be a recombination hot spot responsible for gene conversion in the gamma globin locus region. When the genomes of Xenopus, pigeon, slime mold and yeast were examined, reiterated sequences homologous to both the mouse rDNA NTS and human globin repeat were found in every case. The discovery of this extraordinarily conserved repeated sequence family appears to have depended upon not using salmon sperm DNA during hybridization. The use of eucaryotic carrier DNA may bias the search for repeated sequences against any which may be highly conserved during eucaryotic evolution.

A chicken middle-repetitive DNA sequence which shares homology with mammalian ubiquitous repeats

We have identified and sequenced two members of a chicken middle repetitive DNA sequence family. By reassociation kinetics, members of this family (termed CRl) are estimated to be present in 1500-7000 copies per chicken haploid genome. The first family member sequenced (CRlUla) is located approximately 2 kb upstream from the previously cloned chicken Ul RNA gene. The second CRl sequence (CRl)Va) is located approximately 12 kb downstream from the 3' end of the chicken ovalbumin gene. The region of homology between these two sequences extends over a region of approximately 160 base pairs. In each case, the 160 base pair region is flanked by imperfect, but homologous, short direct repeats 10-15 base pairs in length. When the CRl sequences are compared with mammalian ubiquitous interspersed repetitive DNA sequences (human Alu and Mouse Bl families), several regions of extensive homology are evident. In addition, the short nucleotide sequence CAGCCTGG which is completely conserved in ubiquitous repetitive sequence families from several mammalian species is also conserved at a homologous position in the chicken sequences. These data imply that at least certain aspects of the sequence and structure of these interspersed repeats must predate the avian-mammalian divergence. It seems that the CRl family may possibly represent an avian counterpart of the mammalian ubiquitous repeats.