A novel transposon-like repeat interrupted by an LTR element occurs in a cluster of B1 repeats in the mouse c-mos locus.

The mouse genomic locus containing the oncogene c-mos was analyzed for repetitive DNA sequences. We found a single B1 repeat 10 kb upstream and three B1 repeats 0.6 kb, 2.7 kb, and 5.4 kb, respectively, downstream from c-mos. The B1 repeat closest to c-mos contains an internal 7-bp duplication and a 18-bp insertion. Localized between the last two B1 repeats is a copy of a novel mouse repeat. Sequence comparison of three copies of this novel repeat family shows that they a) contain a conserved BglII site, b) are approximately 420 bp long, c) possess internal 50-bp polypurine tracts, and d) have structural characteristics of transposable elements. They are present in about 1500 copies per haploid genome in the mouse, but are not detectable in DNA of other mammals. The BglII repeat downstream from c-mos is interrupted by a single 632-bp LTR element. We estimate that approximately 1200 copies of this element are present per haploid genome in BALB/c mice. It shares sequence homology in the R-U5 region with an LTR element found in 129/J mice.     

A cluster of repetitive elements within a 700 base pair region in the mouse genome

Approximately 39% of the clones from a BALB/c mouse genomic library hybridized with polyadenylated cytoplasmic RNA extracted from anemic mouse spleen. The DNA sequence of a portion of one such clone revealed the presence of three repetitive sequence elements within a 700 bp span. All three elements contain putative RNA polymerase III control regions oriented in the same direction and oligo(dA) tracts at their 3' ends. The first element is a member of the murine B1 family. A comparison of this element with other B1 family members indicates that the B1 family can be divided into two subclasses based on commonly held base changes and deletions. The second element within this 700 bp region may be a member of a new murine Alu family. Its structure is analogous to other murine Alu-equivalent sequences with respect to overall length, the presence of a 3' oligo(dA) tract and putative RNA polymerase III control regions. The third element is a murine type 2 Alu-equivalent sequence.     

A CR1 element is embedded in a novel tandem repeat (HinfI repeat) within the chicken genome.

Highly repetitive DNA sequences constitute a significant portion of most eukaryotic genomes, raising questions about their evolutionary origins and amplification dynamics. In this study, a novel chicken repetitive DNA family, the HinfI repeat, was characterized. The basic repeating unit of this family displays a uniform length of 770 bp, which was defined by the recognition site of HinfI. The HinfI repeat was specifically localized in the pericentric region of chromosome 4 by fluorescence in situ hybridization and constitutes 0.51% of the chicken genome. Interestingly, a chicken repeat 1 (CR1) element has been identified within this basic repeating unit. Like other CR1 elements, this CR1 element also displays typical retrotransposition characteristics, including a highly conserved 3' region and a badly truncated 5' end. This direct evidence from sequence analysis, together with our Southern blot results, suggests that the HinfI repeat may originate from a unique region containing a retrotransposed CR1 element.     

Molecular characterization of a mouse genomic element mobilized by advanced glycation endproduct modified-DNA (AGE-DNA).

BACKGROUND: DNA modified by advanced glycation endproducts (AGEs) undergoes a high frequency of insertional mutagenesis. In mouse lymphoid cells, these mutations are due in part to the transposition of host genomic elements that contain a DNA region homologous to the Alu family of repetitive elements. One particular 853 bp insertion, designated INS-1, was identified previously as a DNA element common to plasmids recovered from multiple, independent lymphoid cell transfections. MATERIALS AND METHODS: To characterize the genomic origin of this element, we used a 281-bp region of non-Alu-containing INS-1 sequence, designated. CORE, as a probe in Southern hybridization and for screening a bacteriophage mouse genomic DNA library. The resultant clones were sequenced and localized within the mouse genome. RESULTS: Two distinct genomic clones of 15 kB and 17 kB in size were isolated. A 522-bp unique region common to INS-1 and corresponding to the CORE sequence was identified in each clone. In both cases, CORE was found to be surrounded by repetitive DNA sequences: a 339-bp MT repeat at the 5' end, and a 150-bp B1 repeat at the 3' end. The CORE sequence was localized to mouse chromosome 1. CONCLUSIONS: These studies revealed that the CORE region of INS is present in low copy number but is associated with known repetitive DNA elements. The presence of these repetitive elements may facilitate the transposition of CORE by recombination or other, more complex rearrangement events, and explain in part the origin of AGE-induced insertional mutations.     

Estimating the total mouse DNA methylation according to the B1 repetitive elements

Measuring the degree of methylation of the B1 element in mouse may represent the global DNA methylation status because about 30,000 copies of the B1 element are randomly dispersed in the total mouse genome. Six CpG dinucleotides are located within each 163 bp size of B1 element, and each CpG dinucleotide was partially methylated. We quantitated the DNA methylation of the B1 repetitive elements by performing PCR for the methylation specific PCR (MSP) and also by the pyrosequencing. Each CpG dinucleotide was methylated at an average of 9% in the mouse genome by the pyrosequencing and MSP. Especially, we checked whether CpG methylation of the B1 element could respond to a treatment of the DNA methylation inhibitor, 5-azacytidine (5-AzaC). Consequently, the calibration graph resulting from measuring the relative CpG methylation percentage of the B1 element is linearly decreased with the increasing amount of 5-AzaC (up to 50 ng/ml concentration) in the NIH3T3 cells with a standard deviation of only 1.73% between three independent assays. Our methods can be applied to the routine analysis of the global DNA methylation changes in mouse in vivo and in vitro in pharmaceuticals and basic epigenetic research with efforts being less labor-intensive.     

Genomic characterization of the human and mouse protein tyrosine phosphatase-1B genes

PTP-1B is a ubiquitously expressed intracellular protein tyrosine phosphatase (PTP) that has been implicated in the negative regulation of insulin signaling. Mice deficient in PTP-1B were found to have an enhanced insulin sensitivity and a resistance to diet-induced obesity. Interestingly, the human PTP-1B gene maps to chromosome 20 q13.1 in a region that has been associated with diabetes and obesity. Although there has been a partial characterization of the 3′ end of the human PTP-1B gene, the complete gene organization has not been described. In order to further characterize the PTP-1B gene, we have cloned and determined the genomic organization for both the human and mouse PTP-1B genes including the promoter. The human gene spans >74 kb and features a large first intron of >54 kb; the mouse gene likewise contains a large first intron, although the exact size has not been determined. The organization of the human and mouse PTP-1B genes is identical except for an additional exon at the 3′ end of the human that is absent in the mouse. The mouse PTP-1B gene maps to the distal arm of mouse chromosome 2 in the region H2-H3. This region is associated with a mouse obesity quantitiative trait locus (QTL) and is syntenic with human chromosome 20. The promoter region of both the human and mouse genes contain no TATA box but multiple GC-rich sequences that contain a number of consensus SP-1 binding sites. The basal activity of the human PTP-1B promoter was characterized in Hep G2 cells using up to 8 kb of 5′ flanking sequence. A 432 bp promoter construct immediately upstream of the ATG was able to confer maximal promoter activity. Within this sequence, there are at least three GC-rich sequences and one CCAAT box, and deletion of any of these elements results in decreased promoter activity. In addition, the promoter in a number of mouse strains contains, 3.5 kb upstream of the start codon, an insertion of an intracisternal a particle (IAP) element that possibly could alter the expression of PTP-1B mRNA in these strains.     

The beta globin gene cluster of the prosimian primate Galago crassicaudatus: nucleotide sequence determination of the 41-kb cluster and comparative sequence analyses.

The nucleotide sequence of the beta globin gene cluster of the prosimian Galago crassicaudatus has been determined. A total sequence spanning 41,101 bp contains and links together previously published sequences of the five galago beta-like globin genes (5'-epsilon-gamma-psi eta-delta-beta-3'). A computer-aided search for middle interspersed repetitive sequences identified 10 LINE (L1) elements, including a 5' truncated repeat that is orthologous to the full-length L1 element found in the human epsilon-gamma intergenic region. SINE elements that were identified included one Alu type I repeat, four Alu type II repeats, and two methionine tRNA-derived Monomer (type III) elements. Alu type II and Monomer sequences are unique to the galago genome. Structural analyses of the cluster sequence reveals that it is relatively A+T rich (about 62%) and regions with high G+C content are associated primarily with globin coding regions. Comparative analyses with the beta globin cluster sequences of human, rabbit, and mouse reveal extensive sequence homologies in their genic regions, but only human, galago, and rabbit sequences share extensive intergenic sequence homologies. Divergence analyses of aligned intergenic and flanking sequences from orthologous human, galago, and rabbit sequences show a gradation in the rate of nucleotide sequence evolution along the cluster where sequences 5' of the epsilon globin gene region show the least sequence divergence and sequences just 5' of the beta globin gene region show the greatest sequence divergence.     

Determination of a functional ancestral sequence and definition of the 5' end of A-type mouse L1 elements

The complete nucleotide sequence of L1Md-A13, a 6372 base-pair (bp) member of the L1Md repetitive family isolated from a BALB/c mouse genomic DNA library, is reported. The nucleotide sequence of 4331 bp from the 5' end of L1Md-9, which is located in the beta-globin complex of the C57BL/10 mouse, is also reported. Parsimony analysis of these sequences plus two previously reported L1Md sequences allows the determination of an ancestral L1Md sequence. Analysis of the L1Md population indicates that this ancestral sequence is likely to represent a functional L1 sequence. This ancestral sequence confirms that the length (1137 bp and 3900 bp) and relationship (14 bp overlap) of the two large open reading frames previously reported are conserved features of the L1Md family. It also allows the determination of an ancestral amino acid sequence for these two open reading frames. Full-length L1Md elements have one of two sequences tandemly repeated at the 5' end. These two monomers are called A-type and F-type. Our data define the 5' end of A-type full-length L1Md elements. L1Md elements of the A-type have varying numbers of tandemly repeated 208 bp monomers, but each element ends about 78 bp from the 5' end of the terminal 208 bp monomer.     

Structure and Origin of a Novel Dimeric Retroposon B1-dID

Here we describe a new short retroposon family of rodents. Like the primate Alu element consisting of two similar monomers, it is dimeric, but the left and right monomers are different and descend from B1 and ID short retroposons, respectively. Such elements (B1-dID) were found in the genomes of Gliridae, Sciuridae, Castoridae, Caviidae, and Hystricidae. Nucleotide sequences of this retroposon can be assigned to several structural variants. Phylogenetic analysis of B1-dID and related sequences suggests a possible scenario of B1-dID evolution in the context of rodent evolution. Received: 30 August 1999 / Accepted: 20 March 2000     

Distribution of the short dispersed repetitive sequences B1 and B2 in the mouse genome

The organization of the short dispersed repetitive sequences B1 and B2 in the mouse genome was investigated by hybridization of randomly selected genomic clones with isolated and labelled in vitro B1 and B2. Cloning and restriction mapping experiments indicated that these two DNA sequences were not entirely independently distributed along mouse DNA, but approximately half of them formed heterologous pairs separated by stretches of apparently random DNA.