Replication timing properties within the mouse distal chromosome 7 imprinting cluster

Genomic imprinting is characterized by allele-specific expression of genes within chromosomal domains. Here we show, using fluorescence in situ hybridization (FISH) analysis, that the large chromosomal domain of the mouse distal chromosome 7 imprinting cluster, approximately 1 Mb in length between p57Kip2 and H19 genes, replicates asynchronously between the two alleles during S-phase. At the telomeric side of this domain, we found a transition from asynchronous replication at the imprinted p57Kip2 gene to synchronous replication at the Nap2 gene. Two-color FISH suggested that the paternal allele of this whole domain replicates earlier than its maternal allele. Treatment of the cells with a histone deacetylase inhibitor abolished this allele-specific feature accompanied with accelerated replication of the later-replicating allele at a domain level. Allele-specific asynchronous replication was observed even in ES cells. These results suggest that this imprinting cluster consists of a large replication domain which is already found at the early stage in development.     

Genome imprinting phenomena on mouse chromosome 7

Heterozygotes for the reciprocal translocation T(7;15)9H were intercrossed, with albino (c) and underwhite (uw) as genetic markers, in order to study genetic complementation in mouse chromosome 7. Chromosome 15 is known to show normal complementation. Neither reciprocal cross in which one parent was c/c and the other wild type yielded albino progeny at birth although about 17% would be expected, but albino foetuses were recovered when the mother was c/c and father wild type. These products of maternal duplication/paternal deficiency for distal 7 were markedly retarded with small placentae. No albino foetuses were found when the father was c/c and mother wild type, which suggested earlier lethality. Equivalent crosses with uw (chromosome 15) as proximal marker gave normal underwhite progeny when the mother was uw/uw but small placentae, retardation and neonatal death of presumptive underwhites in the reciprocal cross. These abnormal newborn would have had a maternal duplication/paternal deficiency for proximal 7. These and other findings indicate that one region of defective complementation probably lies distal to the breakpoint of T(7;18)50H at 7E2-F2, while another is between the centromere and 7B3. Examination of man-mouse homologies suggests that the loci for three pathological human conditions (Beckwith-Weidemann syndrome, dystrophia myotonia and rhabdomyosarcoma) with differential parental transmission may be located in homologous regions to those affected by imprinting phenomena on mouse chromosome 7.     

Growth and the distal tip of mouse chromosome 7

This review concerns the general problem of understanding growth control in the whole organism, starting with a saltatory change in size generated by a chromosome translocation or a mutation in a single gene. In particular, changes in insulin-like growth factor-II levels, by genetic and embryological manipulation, have major effects on wet weight size, but the intermediary events that link these levels to this measure of growth are uncertain. Thus it is currently impossible to eliminate any of the intermediary candidate processes that have been observed in model systems, including changed rates of apoptosis, cell multiplication, protein synthesis, capillary permeability and fluid transport.     

Preferential S-phase pairing of the imprinted region on distal mouse chromosome 7.

Fluorescence in situ hybridization (FISH) has been used to visualize the spatial orientation of homologous chromosome regions in interphase nuclei of exponentially growing mouse fibroblasts. Simultaneous labeling of replicating DNA with the halogenated base analog 5-bromodeoxyuridine (BrdU) shows preferential somatic pairing of the imprinted region on distal mouse chromosome 7 during the S phase of the cell cycle. Trans-interactions between oppositely imprinted chromosome regions may be important for the maintenance of imprinting.     

Mapping of alpha-spectrin on distal mouse chromosome 1

DNAs from different strains of inbred mice and feral Mus spretus were found to exhibit restriction fragment length polymorphisms (RFLP) when hybridized with a probe prepared from a c-DNA clone of the mouse alpha-spectrin (Spna-1) gene. Studies of five recombinant inbred strains and (C57BL/6 X M. spretus) F1 X C57BL/6 backcross mice demonstrated that these RFLPs were allelic and that Spna-1 is closely linked to Ly-9 and Ly-17 on the distal region of chromosome 1.     

Peg1/Mest locates distal to the currently defined imprinting region on mouse proximal chromosome 6 and identifies a new imprinting region affecting growth

Mice with maternal duplication for proximal chromosome 6 (Chr 6) die in utero before 11.5 dpc, an effect that can be attributed to genomic imprinting. Previous studies have defined the region of Chr 6 responsible as lying proximal to the T6Ad translocation breakpoint in G-band 6B3. Evidence presented here with a new Chr 6 translocation T77H has substantially reduced the size of the imprinting region, locating it between G-band 6A3.2 and the centromere. The paternally expressed imprinted gene Mest had been mapped within the original imprinting region and was therefore a candidate for the early embryonic lethality. FISH has shown that Mest locates distal to T77H and therefore outside the redefined imprinting region. This evidence confirms that Mest is not a candidate for the early embryonic lethality found with two maternal copies of proximal Chr 6. Furthermore mice with maternal duplication for Ch 6 distal to T77H (MatDp.dist6) were found to be growth retarded at birth, the weight reduction remaining similar until adulthood. It can be concluded that the growth retardation is established in utero and is maintained at a similar level from birth to adulthood. Therefore Mest locates in a new imprinting region, distal to G-band 6A3.2 which affects growth. A targeted mutation of Mest has been reported that exhibits growth retardation, reduced postnatal survival and abnormal maternal behaviour. Here the phenotype of MatDp.dist6 mice is compared to that of Mest-deficient mutant mice. Unlike the latter, MatDp.dist6 mice have good survival rates and females have normal maternal behaviour. Possible reasons for these differences are discussed.     

Epigenetic and phenotypic consequences of a truncation disrupting the imprinted domain on distal mouse chromosome 7

The distal end of mouse chromosome 7 (Chr 7) contains a large cluster of imprinted genes. In this region two cis-acting imprinting centers, IC1 (H19 DMR) and IC2 (KvDMR1), define proximal and distal subdomains, respectively. To assess the functional independence of IC1 in the context of Chr 7, we developed a recombinase-mediated chromosome truncation strategy in embryonic stem cells and generated a terminal deletion allele, DelTel7, with a breakpoint in between the two subdomains. We obtained germ line transmission of the truncated Chr 7 and viable paternal heterozygotes, confirming the absence of developmentally required paternally expressed genes distal of Ins2. Conversely, maternal transmission of DelTel7 causes a midgestational lethality, consistent with loss of maternally expressed genes in the IC2 subdomain. Expression and DNA methylation analyses on DelTel7 heterozygotes demonstrate the independent imprinting of IC1 in absence of the entire IC2 subdomain. The evolutionarily conserved linkage between the subdomains is therefore not required for IC1 imprinting on Chr 7. Importantly, the developmental phenotype of maternal heterozygotes is rescued fully by a paternally inherited deletion of IC2. Thus, all the imprinted genes located in the region and required for normal development are silenced by an IC2-dependent mechanism on the paternal allele.     

A linkage map of distal mouse chromosome 12

To refine the linkage map of distal mouse Chromosome 12, we have identified DNA restriction fragment variants associated with a creatine kinase gene (Ck-3), the Akt proto-oncogene, an Abelson proviral integration site (D12N1), and the immunoglobulin heavy chain V_H3609 variable region family (Igh-V36). The patterns of inheritance of these markers in backcross progeny and recombinant inbred mouse strains allowed their localization with respect to previously mapped genes to yield the linkage map: Aat-15.8 cM-Ck-3-0.9 cM-(Crip, Akt, Igh-C)-0.3 cM-(D12N1, Igh-V). This map confirms genetically the localization of the Igh-V gene complex distal to Igh-C on the chromosome. It differs from previous maps in placing D12N1 distal to Igh-C, and in suggesting that the Igh-V gene complex spans less than one centiMorgan (cM).Other DNA sequence variants detected with the creatine kinase probe allowed definition of four additional genetic loci: Ck-1 near Lmyc-1 on Chromosome 4; Ck-2 between Upg-1 and Hprt-ps1 (D17Rp10) on distal Chromosome 17; Ck-4 near Mpmv-17 and Mls-3 on Chromosome 16; and Ck-5 near Hba on Chromosome 11.     

Analysis of mouse conceptuses with uniparental duplication/deficiency for distal chromosome 12: comparison with chromosome 12 uniparental disomy and implications for genomic imprinting

Distal mouse chromosome 12 is imprinted. Phenotypic analysis of mouse embryos with maternal or paternal uniparental disomy for the whole of chromosome 12 has characterized the developmental defects associated with the altered dosage of imprinted genes on this chromosome. Here we conduct a characterization of maternal and paternal Dp(dist12) mice using the reciprocal translocation T(4;12)47H. This limits the region analysed to the chromosomal domain distal to the T47H breakpoint in B3 on mouse chromosome 12. Both MatDp(dist12)T47H and PatDp(dist12)T47H conceptuses are non-viable and the frequency of recovery of Dp(dist12) conceptuses by 10.5 days post coitum (dpc) was lower than expected after normal adjacent-1 disjunction. A subset of MatDp(dist12) embryos can survive up to one day post partum. In contrast to paternal uniparental disomy 12 embryos, no live PatDp (dist12) embryos were recovered after 16.5 days of gestation. Other phenotypes observed in maternal and paternal chromosome 12 uniparental disomy mice are recapitulated in the Dp(dist12) mice and include placental, muscle and skeletal defects. Additional defects were also noted in the skin of both MatDp(dist12) and maternal uniparental disomy 12 embryos. This study shows that the developmental abnormalities associated with the altered parent of origin for mouse chromosome 12 can be attributed to the genomic region distal to the T47H breakpoint.     

Phemx, a novel mouse gene expressed in hematopoietic cells maps to the imprinted cluster on distal chromosome 7

Phemx (Pan hematopoietic expression) is a novel murine gene expressed in developmentally regulated sites of hematopoiesis from early in embryogenesis through adulthood. Phemx is expressed in hematopoietic progenitors and mature cells of the three main hematopoietic lineages. Conceptual translation of the murine Phemx cDNA predicts a 25-kDa polypeptide with four hydrophobic regions and several potential phosphorylation sites, suggestive of a transmembrane protein involved in cell signaling. The PHEMX protein is structurally similar to tetraspanin CD81 (TAPA-1), a transmembrane protein involved in leukocyte activation, adhesion, and proliferation. Phemx maps to the distal region of chromosome 7, a segment of the mouse genome that contains a cluster of genes that exhibit genomic imprinting. However, imprinting analysis of Phemx at the whole organ level shows that it is biallelically expressed, suggesting that mechanisms leading to monoallelic expression are not imposed at this locus. The human PHEMX ortholog is specifically expressed in hematopoietic organs and tissues and, in contrast to murine Phemx, undergoes alternative splicing. The unique mode and range of Phemx expression suggest that it plays a role in hematopoietic cell function.     

Large-scale identification and mapping of nuclear matrix-attachment regions in the distal imprinted domain of mouse chromosome 7.

Mammalian imprinted genes, which are expressed from only one of the parental alleles, have a tendency to form clusters and are regulated by long-range mechanisms. Nuclear matrix-attachment regions (MARs), the anchor points of loop domains, are involved in coordination of gene expression and could play a role in regulation of imprinted domains. We have identified and mapped a total of 52 MARs in a 1-Mb imprinted domain on mouse distal chromosome 7 using our cosmid contigs and an in vitro MAR assay. We find two MAR clusters (comprising 20 and 19 MARs), one of which is mapped in the Th-Ins2 intergenic region, coincident with the boundary between the two imprinted subdomains. However, the imprinted/non-imprinted boundaries are not associated with a MAR. Based on the sequence information, we find that many of the MARs are rich in long interspersed nuclear elements. In addition, comparisons of the results obtained with several MAR-prediction software programs reveal good performance of ChrClass in terms of both sensitivity and specificity. This study presents the first large-scale mapping of MARs in an imprinted domain and provides a platform for understanding the roles of MARs in imprinting.     

Identification of a deletion hotspot on distal mouse chromosome 4 by YAC fingerprinting

Using repetitive elements as probes, genomic DNA fingerprints of four randomly selected yeast artificial chromosome (YAC) clones (two human and two mouse-derived YAC) were analyzed to determine the mutation level following X-ray exposure. Because the repetitive probes were derived from the mammalian host DNA, most of the fingerprint bands originated from the artificial chromosomes and not from the yeast genome. For none of the YAC clones was the mutation frequency elevated following X-ray exposure. However, for one mouse-derived YAC, the mutation level was unusually high (7%; 42 mutants of 607 clones analyzed), whereas for the other three YACs, the mutation level was nearly 0%. Surprisingly, 40 of the 42 mutations were deletions occurring only at three of the 20 mouse specific fingerprint bands. One of the frequently deleted fragments was cloned, sequenced and mapped to distal mouse chromosome 4, which has been repeatedly reported to be the most unstable region of the whole mouse genome, associated with various tumors. Deletion mapping of six YAC mutants revealed this fragment to be completely deleted in four YACs. In the other two mutants, recombination occurred within the fragment, in each case initiated at the same LINE-1 element. In conclusion, the presented YAC fingerprint is a useful tool for detecting and characterizing unstable regions in mammalian genomes.     

A 210-kb segment of tandem repeats and retroelements located between imprinted subdomains of mouse distal chromosome 7.

Mammalian genes subject to genomic imprinting often form clusters and are regulated by long-range mechanisms. The distal imprinted domain of mouse chromosome 7 is orthologous to the Beckwith-Wiedemann syndrome domain in human chromosome 11p15.5 and contains at least 13 imprinted genes. This domain consists of two subdomains, which are respectively regulated by an imprinting center. We here report the finished-quality sequence of a 0.6-Mb region encompassing the more centromeric subdomain. The sequence contains four imprinted genes (Ascl2/Mash2, Ins2, Igf2 and H19) and reveals previously unidentified CpG islands and tandem repeats, which may be features of imprinted genes. Most interestingly, a unique 210-kb segment consisting almost exclusively of tandem repeats and retroelements is identified. This segment, located between Th and Ins2, has features of heterochromatin-forming DNA and is highly methylated at CpG sites. The segment exhibits asynchronous replication on the parental chromosomes, a feature of the imprinted domains. We propose that this repeat segment could serve either as a boundary between the two subdomains or as a target for epigenetic chromatin modifications that regulate imprinting.