Methylation perturbations in retroelements within the genome of a Mus interspecific hybrid correlate with double minute chromosome formation

A reduction in the DNA modification of cytosine methylation has been linked directly to chromosome rearrangements concomitant with retroelement amplification in several marsupial hybrid genomes. While phenotypes observed for interspecific eutherian hybrids are suggestive of methylation perturbations and retroelement instability, no link between retroelements, DNA methylation, and chromosome instability has yet been identified. Previous studies in eutherian hybrids, however, have been limited to a gross examination of methylation using methylation-sensitive restriction enzyme analysis or focused on single-copy genes and/or have avoided examination of repetitive DNA. Methylation changes and retroelements are proposed as mechanisms for double minute chromosome formation and oncogene amplification, both present in the genome of a Mus hybrid model, thus making it an ideal system to evaluate methylation status more closely. We have used the PCR-based methodologies methylation-sensitive amplicon subtraction (MS-AS) and methylation-sensitive representational difference analysis (MS-RDA) to detect differentially methylated sequences between three complex genomes and to isolate methylation perturbations in a Mus musculusxMus caroli hybrid. This novel application of MS-AS and MS-RDA resulted in the isolation of differentially methylated retroelements surrounding the locus on Chromosome 10 responsible for double minute chromosome formation within this interspecific eutherian hybrid.     

Expression of glucose phosphate isomerase in interspecific hybrid (Mus musculus x Mus caroli) mouse embryos.

Hybrid Mus musculus x Mus caroli embryos were produced by inseminating M. musculus (C57BL/OlaWs) females with M. caroli sperm. Control M. caroli embryos developed more rapidly than did control M. musculus embryos and implanted approximately 1 day earlier. At 1 1/2 days, both the hybrid embryos and those of the maternal species (M. musculus) had cleaved to the 2-cell stage. By 2 1/2 days some of the hybrids were retarded compared to M. musculus, and by 3 1/2 days most were lagging behind. This is consistent with the idea that the rate of development of hybrid embryos declines once it becomes dependent on embryo-coded gene products. We have used this difference in rate of preimplantation development, between hybrid and M. musculus embryos, to try to determine whether the activation of embryonic Gpi-1s genes, that encode glucose phosphate isomerase (GPI-1), is age-related or stage-related. In control M. musculus embryos (both mated and Al groups), the GPI-1AB and GPI-1A allozyme, indicative of paternal gene expression, were detected in 7 of 9 samples of 3 1/2-day compacted morula stage embryos and were seen in all 19 samples of 3 1/2-day blastocysts. In hybrid embryos, these allozymes were detected 1 day later. They were not detected in any 3 1/2-day samples (12 samples of compacted morulae) but were consistently detected at 4 1/2 days (4 samples of blastocysts and 2 samples of uncompacted morulae). Our interpretation of the results is that gene activation in hybrid embryos is stage-specific, rather than age-specific, and probably begins around the 8-cell stage, with detectable levels of enzyme accumulating later. Analysis of GPI-1 electrophoresis indicated that both the paternal (M. caroli) and maternal (M. musculus) Gpi-1s alleles were equally expressed in hybrid embryos and that the paternally derived allele was not activated before the maternally derived allele.     

CENP-B binds a novel centromeric sequence in the Asian mouse Mus caroli.

Minor satellite DNA, found at Mus musculus centromeres, is not present in the genome of the Asian mouse Mus caroli. This repetitive sequence family is speculated to have a role in centromere function by providing an array of binding sites for the centromere-associated protein CENP-B. The apparent absence of CENP-B binding sites in the M. caroli genome poses a major challenge to this hypothesis. Here we describe two abundant satellite DNA sequences present at M. caroli centromeres. These satellites are organized as tandem repeat arrays, over 1 Mb in size, of either 60- or 79-bp monomers. All autosomes carry both satellites and small amounts of a sequence related to the M. musculus major satellite. The Y chromosome contains small amounts of both major satellite and the 60-bp satellite, whereas the X chromosome carries only major satellite sequences. M. caroli chromosomes segregate in M. caroli x M. musculus interspecific hybrid cell lines, indicating that the two sets of chromosomes can interact with the same mitotic spindle. Using a polyclonal CENP-B antiserum, we demonstrate that M. caroli centromeres can bind murine CENP-B in such an interspecific cell line, despite the absence of canonical 17-bp CENP-B binding sites in the M. caroli genome. Sequence analysis of the 79-bp M. caroli satellite reveals a 17-bp motif that contains all nine bases previously shown to be necessary for in vitro binding of CENP-B. This M. caroli motif binds CENP-B from HeLa cell nuclear extract in vitro, as indicated by gel mobility shift analysis. We therefore suggest that this motif also causes CENP-B to associate with M. caroli centromeres in vivo. Despite the sequence differences, M. caroli presents a third, novel mammalian centromeric sequence producing an array of binding sites for CENP-B.     

Molecular cloning and long terminal repeat sequences of intracisternal A-particle genes in Mus caroli

We isolated DNA clones of intracisternal A-particle (IAP) genes from the genome of an Asian wild mouse, Mus caroli. A typical M. caroli IAP gene was 6.5 kilobase pairs in length and had long terminal repeat (LTR) sequences at both ends. The size of the LTR was 345 base pairs in clone L20, and two LTRs at both ends of this clone were linked to directly repeating cellular sequences of 6 base pairs. Each LTR possessed most of the structural features commonly associated with the retrovirus LTR. The restriction map of the M. caroli IAP gene resembled that of Mus musculus, although the M. caroli IAP gene was 0.4 kilobase pairs shorter than the M. musculus IAP gene in two regions. Sequence homology between the M. caroli and M. musculus IAP LTRs was calculated as about 80%, whereas the LTR sequence of the Syrian hamster IAP gene was about 60% homologous to the M. caroli LTR. The reiteration frequency of the M. caroli IAP genes was estimated as 200 to 400 copies per haploid genome, which is at least 10 times the reported value. These results suggest that the IAP genes observed in the genus Mus are present in multiple copies with structures closely resembling the integrated retrovirus gene.     

Morphological demonstration of the failure of Mus caroli trophoblast in the Mus musculus uterus

A histological study of Mus caroli embryos gestating in the Mus musculus uterus was undertaken at Day 8.5 of gestation, 1 day after such embryos are reported to be normal and 1 day before the earliest events associated with death of the xenogeneic embryos. In comparison to control M. caroli embryos recovered from M. caroli and to control M. musculus embryos recovered from M. musculus, the xenogeneically transferred embryos showed intrauterine growth retardation that was associated with trophoblastic insufficiency. Trophoblast cell degeneration was observed, in the absence of lymphocytic infiltration. Therefore, loss of trophoblast cell function rather than lymphocyte-mediated destruction of trophoblast appears to underlie the death of M. caroli embryos in the M. musculus uterus.     

Effects of alterations in the immunocompetent status of Mus musculus females on the survival of transferred Mus caroli embryos

The role of the immune system in promoting the midterm death of Mus caroli embryos transferred to the Mus musculus uterus was studied in vivo by transferring M. caroli blastocysts to recipients with altered immune status. Transfers of embryos to chimaeric mothers (Mus musculus in equilibrium Mus caroli), which were expected to be tolerant of species antigens, resulted in survival of M. musculus embryos but death of M. caroli embryos. The preferential survival of M. musculus embryos was explained by showing that M. musculus embryos can survive in the M. caroli uterus. Transfers to T cell-deficient mice of genotype nu/nu and to NK cell-deficient mice of genotype bg/bg as well as treatment of normal transfer recipients with Cyclosporin A or anti-Ia antiserum failed to prolong survival. However, immunization of recipients with M. caroli lymphocytes promoted more rapid and uniform failure of the interspecies pregnancy. Cytotoxic cells were detected in the resorbing embryos on Day 10.5 in immune pregnancies and on Day 12.5 in non-immune pregnancies and these cells were promiscuous in their pattern of lysis, showing equal reactivity against M. caroli, transfer recipient and 3rd party target cells. These experiments show that failure of M. caroli embryos in the M. musculus uterus is complex, but probably does not involve responses by classical cytotoxic T lymphocyte or natural killer cell pathways. Participation of the immune system in the resorption process, however, is confirmed and is associated with generation of promiscuous cytolytic cells.     

Immune presensitization and local intrauterine defences as determinants of success or failure of murine interspecies pregnancies

Putatively immuno-incompetent Mus musculus females exhibited failure to support pregnancy of Mus caroli embryos. These results for M. musculus females (i.e. treated by cyclosporine A, of the nu/nu genotype, and as an interspecies chimaera) can be explained in immunological terms. Mus musculus females possessed pre-sensitized cytotoxic T cells against Mus caroli antigen. Nu/nu mice possessed activated NK cells and macrophages, and selectively discriminated against Mus caroli embryos early in pregnancy unlike normal +/+ females; the requirement for T cells to activate non-specific cytotoxic effector mechanisms was bypassed in nu/nu mice. Mus caroli are not inbred, and interspecies chimaeras which are tolerant of the antigens on the Mus musculus donor strain were not tolerant of cells from unrelated Mus caroli. Interspecies chimaeras also behaved as if they were pre-sensitized to Mus caroli. Our results show that Mus caroli embryos recruit fewer active suppressor cells even when gestating in Mus caroli decidua as compared to Mus musculus embryos in Mus musculus decidua and that the ability of Mus caroli placental cells to directly inhibit cytotoxic effector cell killing was inherently less than the inhibitory activity of placental cells from Mus musculus. Mus caroli embryos therefore appear to be less well defended against maternal immune attack even when gestating in a uterus possessing compatible Mus caroli decidual tissue.     

DNA methylation in placentas of interspecies mouse hybrids

Interspecific hybridization in the genus Mus results in several hybrid dysgenesis effects, such as male sterility and X-linked placental dysplasia (IHPD). The genetic or molecular basis for the placental phenotypes is at present not clear. However, an extremely complex genetic system that has been hypothesized to be caused by major epigenetic changes on the X chromosome has been shown to be active. We have investigated DNA methylation of several single genes, Atrx, Esx1, Mecp2, Pem, Psx1, Vbp1, Pou3f4, and Cdx2, and, in addition, of LINE-1 and IAP repeat sequences, in placentas and tissues of fetal day 18 mouse interspecific hybrids. Our results show some tendency toward hypomethylation in the late gestation mouse placenta. However, no differential methylation was observed in hyper- and hypoplastic hybrid placentas when compared with normal-sized littermate placentas or intraspecific Mus musculus placentas of the same developmental stage. Thus, our results strongly suggest that generalized changes in methylation patterns do not occur in trophoblast cells of such hybrids.     

Evolution of a 6-200 Mb long-range repeat cluster in the genus Mus

By fluorescence in situ hybridization, we mapped the location of genes associated with the Sp100-rs cluster, a long-range repeat cluster in chromosome 1 of the house mouse, Mus musculus. The cluster comprises between 60 and 2000 repeats and extends over 6-200 Mb of the M. musculus genome, depending on the source of the cluster. The cluster evolved during the last two million years in the genus Mus in the lineage to which M. musculus belongs. The Asiatic mouse species M. caroli is not in this lineage and does not possess the cluster. M. caroli represents the ancestral genomic organization of the cluster source components Sp100, Csprs and Ifi75: they are located close to each other in the same chromosome band (1D). However, Sp100-rs, the principal gene of the cluster, is not present in the M. caroli genome. It is a chimeric M. musculus gene that arose by fusion of Csprs and the 5' part of Sp100. Sp100-rs and Ifi75 are homogeneously distributed throughout the cluster while Sp100 and Csprs in its original sequence context flank the cluster on opposite sides. Our results suggest a model for the origin and evolution of the long-range repeat cluster by duplication, gene fusion and amplification.     

Visible and "cryptic" segregation of parental chromosomes in embryonic stem hybrid cells

Chromosome segregation of the parental chromosomes was studied in 20 interspecific hybrid clones obtained by fusion of Mus musculus embryonic stem cells with Mus caroli splenocytes. FISH analysis with labeled species specific probes and microsatellite markers was used for identification of the parental chromosomes. Cytogenetic analysis has shown significant intra- and interclonal variability in chromosome numbers and ratios of the parental chromosomes in the hybrid cells: six clones contained all M. caroli chromosomes, nine clones showed moderate segregation of M. caroli chromosomes (from 1 to 7), and five clones showed extensive loss of M. caroli chromosomes (from 12 to complete loss of all M. caroli autosomes). Both methods demonstrated "cryptic" segregation of the somatic partner chromosomes. For instance, five clones with near-tetraploid chromosome sets contained only few M. caroli chromosomes (from 1 to 8). The data obtained suggest that the tetraploid chromosome set per se is not a sufficient criterion for conclusion on the absence of chromosome loss in the hybrid cells. Note that "cryptic" chromosome segregation occurred at a high frequency in the examined hybrid clones. Thus, "cryptic" segregation should be borne in mind for assessing pluripotency and genome reprogramming of embryonic stem hybrid cells.     

Insulin secretion and IP levels in two distant lineages of the genus Mus: comparisons with rat islets

Islet responses of two different Mus geni, the laboratory mouse (Mus musculus) and a phylogenetically more ancient species (Mus caroli), were measured and compared with the responses of islets from rats (Rattus norvegicus). A minimal and flat second-phase response to 20 mM glucose was evoked from M. musculus islets, whereas a large rising second-phase response characterized rat islets. M. caroli responses were intermediate between these two extremes; a modest rising second-phase response to 20 mM glucose was observed. Prior, brief stimulation of rat islets with 20 mM glucose results in an amplified insulin secretory response to a subsequent 20 mM glucose challenge. No such potentiation or priming was observed from M. musculus islets. In contrast, M. caroli islets displayed a modest twofold potentiated first-phase response upon subsequent restimulation with 20 mM glucose. Inositol phosphate (IP) accumulation in response to 20 mM glucose stimulation in [(3)H]inositol-prelabeled rat or mouse islets paralleled the insulin secretory responses. The divergence in 20 mM glucose-induced insulin release between these species may be attributable to differences in phospholipase C-mediated IP accumulation in islets.     

An evolutionary switch in tissue-specific gene expression. Abundant expression of alpha 1-antitrypsin in the kidney of a wild mouse species

alpha 1-Antitrypsin (AT), one of the major proteinase inhibitors in mammalian serum, is generally considered to be synthesized exclusively in the liver. We have found that a wild-derived Mus species, Mus caroli, expresses AT mRNA in kidney at levels approaching that in liver; no other mouse, inbred or wild-derived, exhibits this striking property. Liver and kidney mRNAs from M. caroli encode very similar AT polypeptides that are distinct from that encoded by Mus musculus liver mRNA. In vivo, liver AT is secreted into the bloodstream, while kidney AT, which is processed differently from the liver protein, is excreted into the urine. Analysis of RNA from a hybrid between M. musculus and M. caroli indicates that a cis-acting genetic element may be responsible for the difference in AT expression. Restriction enzyme digestion patterns of AT genomic sequences in M. caroli DNA are considerably different from those in M. musculus; in addition, these sequences are undermethylated in liver DNA from M. musculus and in liver and kidney DNA from M. caroli, reflecting the respective patterns of expression. Further studies of the altered tissue specificity of AT expression that is apparent in these two related species should lead to new insights into the nature and evolution of genetic determinants of tissue-specific phenotypes.     

Genome comparison in the genus Mus: a study with B1, MIF (mouse interspersed fragment), centromeric, and Y-chromosomal repetitive sequences

Using four repetitive sequences, we compared DNAs isolated from Mus caroli, M. cookii, M. hortulanus, M. musculus, M. pahari, M. saxicola, and M. spretus. Except for B1, these probes showed species-specific hybridization patterns. Mouse interspersed fragment (MIF) sequences were present in all species examined, but those defined by the 1.3-kb EcoR1 band were fewer in M. pahari and M. saxicola than in the other species. The Y-chromosomal probe showed male-specific accumulation only in M. hortulanus, M. musculus, and M. spretus, which are known to be closely related. The genetic difference between M. spretus and the other two species (M. hortulanus and M. musculus) was clearly demonstrated by a M. musuclus centromeric sequence that hybridized strongly to M. hortulanus and M. musculus DNA but was underrepresented in the genome of M. spretus. These results may suggest the usefulness of these repetitive sequences in the classification of Mus species that display only subtle morphological differences.     

Paternal Transmission of X-Linked Placental Dysplasia in Mouse Interspecific Hybrids

It has previously been shown that abnormal placental development, i.e., hyper- and hypoplasia, occurs in crosses and backcrosses between different mouse (Mus) species. These defects are caused mainly by abnormal growth of the spongiotrophoblast. The precise genetic basis for these placental malformations has not been determined. However, a locus that contributes to the abnormal development (Ihpd: interspecific hybrid placental dysplasia) has been mapped to the X chromosome. The X-chromosomal location of Ihpd and its site of action, that is the spongiotrophoblast, mean that normally only the maternally inherited Ihpd locus is active even in female fetuses. However, by making use of the X-chromosomal inversion In(X)1H, we have produced interspecific hybrid X(p)0, in which the active X chromosome was inherited from Mus macedonicus males. In contrast to XX female and XY male conceptuses from this cross, which have hypoplastic placentas, the X(p)0 female conceptuses have hyperplastic placentas. This finding supports the view that it is expression of the M. macedonicus Ihpd locus in the spongiotrophoblast that leads to hyperplasia due to an abnormal interaction with M. musculus autosomal loci.     

Specificity of androgen resistance inMus caroli kidney

Androgen controls the expression of beta-glucuronidase and several other proteins in the kidney of the standard laboratory mouse, Mus musculus. Other species within the genus Mus exhibit a variety of response patterns for kidney beta-glucuronidase and other markers of androgen action. We have investigated the mechanism of androgen action in M. caroli, a Mus species that does not produce beta-glucuronidase in response to testosterone. The failure of testosterone to induce beta-glucuronidase in M. caroli females cannot be overcome by treatment with dihydrotestosterone, with pharmacological doses of testosterone propionate or dihydrotestosterone propionate, or with a variety of potent androgen analogues. All of these compounds induce kidney beta-glucuronidase in M. musculus females and kidney ornithine decarboxylase, submandibular gland renin, and submandibular gland epidermal growth factor in both M. caroli and M. musculus females. Furthermore, kidney androgen receptor proteins from M. caroli and M. musculus animals have the same sedimentation characteristics on sucrose density gradients. These data indicate that androgen resistance in M. caroli is not due to deficient 5 alpha-reductase or aberrant hormone metabolism producing suboptimal levels of functional androgen and is not caused by a defective androgen receptor. They suggest that the resistance of beta-glucuronidase in M. caroli kidney to induction by androgen occurs at the level of the beta-glucuronidase gene.     

Genetic dissection of X-linked interspecific hybrid placental dysplasia in congenic mouse strains.

Interspecific hybridization in the genus Mus results in male sterility and X-linked placental dysplasia. We have generated several congenic laboratory mouse lines (Mus musculus) in which different parts of the maternal X chromosome were derived from M. spretus. A strict positive correlation between placental weight and length of the M. spretus-derived part of the X chromosome was shown. Detailed analysis was carried out with one congenic strain that retained a M. spretus interval between 12.0 and 30.74 cM. This strain consistently produced hyperplastic placentas that exhibited an average weight increase of 180% over the weight of control placentas. In derived subcongenic strains, however, increased placental weight could no longer be observed. Morphometric analysis of these placentas revealed persistence of abnormal morphology. Fully developed placental hyperplasia could be reconstituted by recombination of proximal and central M. spretus intervals with an intervening M. musculus region. These results may suggest that placental dysplasia of interspecific mouse hybrids is caused by multiple loci clustered on the X chromosome that act synergistically. Alternatively, it is possible that changes in chromatin structure in interspecific hybrids that influence gene expression are dependent on the length of the alien chromosome.     

Survival curves, reproductive life span and age-related pathology of Mus caroli.

Although Mus caroli is being used in a number of laboratories as an experimental animal, basic information concerning its life span, reproductive ability, and age-related pathologies has been unavailable. Here we present this basic information, and discuss the similarities to and differences from the laboratory mouse, Mus musculus domesticus [strains A/StTrWo and (A/StTrWo x C57BL/6NNia)F1] and, from published data, wild-type Mus musculus.     

Cryptosporidium tyzzeri and Cryptosporidium muris originated from wild West-European house mice (Mus musculus domesticus) and East-European house mice (Mus musculus musculus) are non-infectious for pigs

Three and 8 week old pigs were inoculated with Cryptosporidium muris HZ206 (Mus musculus musculus isolate), Cryptosporidium tyzerri CR2090 (M. m. musculus isolate) or C. tyzzeri CR4293 (isolate from a hybrid between Mus musculus domesticus and M. m. musculus) at a dose of 1 × 10(7) oocysts per animal. Inoculated pigs showed no detectable infection and no clinical symptoms of cryptosporidiosis during 30 days post infection (DPI), and no macroscopic changes were detected in the digestive tract following necropsy. Developmental stages were not detected in gastrointestinal tract tissue by histology or PCR throughout the duration of the experiment. The infectivity of isolates was verified on SCID mice, in which oocysts shedding started from 4 to 8 DPI. Based on our findings, it can be concluded that pigs are not susceptible to C. muris or C. tyzzeri infection.