Gametic imprinting and expression of the gene Fused in the house mice

The discovery of the gametic imprinting phenomena in mammals makes it possible to have a new look at some facts concerning the expression and inheritance of genes with variable penetrance. Fused (Fu) is a dominant mutation located on chromosome 17, one of the few examples uses to demonstrate gametic imprinting in mice. This mutation has maternal effect connected with decrease in its penetrance. It was shown that t12 haplotype significantly reduces penetrance of the Fu in the progeny of Fu/t12 females. The results of reciprocal crosses of heterozygotes for t12 haplotypes indicate that penetrance of maternal Fu gene is reduced. Far more strong influence on the fused penetrance have the dominant suppressors, located beyond the chromosome 17. The penetrance of the fused gene decreases in that case up to 8-17%. Results of the experiments show strong influence of gametic pathway on penetrance of the gene by which the gene is transmitted to the next generation. The results also made it possible to describe the regularities of gametic imprinting. This phenomenon clearly indicates the existence of gametic and zygotic ontogenetic phases. According to the hypothesis proposed gametic phase of ontogenesis in mammals starts after initialization, i. e. after a process of chromosome erasing from epigenetic information and preparing to enter the next ontogenetic cycle.     

Gametic imprinting effects on rate and composition of pig growth

Genetic improvement schemes in livestock are based on the assumption that the expression of relevant genes is independent of parent of origin. Until now no evidence has been found to reject this assumption. The present study on three purebred pig populations, however, shows that a significant proportion of the phenotypic variance in backfat thickness (5–7%) can be explained by genes subject to paternal imprinting. The implication is that there are genes affecting backfat that are expressed only when derived from the paternal gamete. Paternal imprinted effects explained 1–4% of the phenotypic variation for growth rate. Maternal imprinted effects were heavily confounded with heritable maternal environmental effects. When modelled separately, these effects explained 2–5% and 3–4% of the phenotypic variance in backfat thickness and growth rate, respectively. Gametic imprinting may have consequences for the optimization of breeding programmes, especially in crossbreeding systems with specialized sire and dam lines. Present address: On leave at AGBU as collaborator via fellowship under OECD project on Biological Resource Management     

Gametic interactions promote inbreeding avoidance in house mice

Reproduction among related individuals is generally maladaptive. Inbreeding imposes significant costs on individual reproductive success, and can decrease population fitness. Theory predicts that polyandrous females can avoid inbreeding by exploiting paternity‐biasing mechanisms that enable differential sperm ‘use’. Evidence of sperm selection is difficult to demonstrate because patterns of non‐random paternity can be generated by a variety of different mechanisms. Here, using in vitro fertilisation in mice, we provide evidence of sperm selection at the gametic level. We mixed the sperm of sibling and non‐sibling males, and observed a fertilisation bias towards the sperm of non‐sibling males. The number of motile sperm and sperm swimming performance did not differ between competitors among the replicate assays. Therefore, our result can only be ascribed to egg‐driven sperm selection against related sperm. We conclude that the expression or secretion of gametic proteins could provide the molecular basis for this mechanism of cryptic female choice.     

Effect of t12 haplotype on the manifestation and inheritance of fused and kinky genes in house mice

The influence of some t-haplotypes on the phenotypic manifestation of fused and kinky genes located on chromosome 17 of the house mouse was studied. It was shown that t12-haplotype decreases the penetrance of these genes to 59-70%. The effect was observed when the Fu gene (or Ki) is transmitted from the females heterozygous for t12-haplotype. This haplotype only affects manifestation of the Fu and Ki genes in the F1.     

Embryos aggregation improves development and imprinting gene expression in mouse parthenogenesis

Mouse parthenogenetic embryonic stem cells (PgESCs) could be applied to study imprinting genes and are used in cell therapy. Our previous study found that stem cells established by aggregation of two parthenogenetic embryos at 8‐cell stage (named as a₂PgESCs) had a higher efficiency than that of PgESCs, and the paternal expressed imprinting genes were observably upregulated. Therefore, we propose that increasing the number of parthenogenetic embryos in aggregation may improve the development of parthenogenetic mouse and imprinting gene expression of PgESCs. To verify this hypothesis, we aggregated four embryos together at the 4‐cell stage and cultured to the blastocyst stage (named as 4aPgB). qPCR detection showed that the expression of imprinting genes Igf2, Mest, Snrpn, Igf2r, H19, Gtl2 in 4aPgB were more similar to that of fertilized blastocyst (named as fB) compared to 2aPgB (derived from two 4‐cell stage parthenogenetic embryos aggregation) or PgB (single parthenogenetic blastocyst). Post‐implantation development of 4aPgB extended to 11 days of gestation. The establishment efficiency of GFP‐a₄PgESCs which derived from GFP‐4aPgB is 62.5%. Moreover, expression of imprinting genes Igf2, Mest, Snrpn, notably downregulated and approached the level of that in fertilized embryonic stem cells (fESCs). In addition, we acquired a 13.5‐day fetus totally derived from GFP‐a₄PgESCs with germline contribution by 8‐cell under zona pellucida (ZP) injection. In conclusion, four embryos aggregation improves parthenogenetic development, and compensates imprinting genes expression in PgESCs. It implied that a₄PgESCs could serve as a better scientific model applied in translational medicine and imprinting gene study.     

A gene affecting liver activities of three glycosidases in the house mouse

A gene locus is described controlling liver activities in the house mouse of three glycosidases, i.e., -galactosidase, -glucuronidase, and N-acetyl--hexosaminidase. An allele conferring low activity is present in the inbred strain LIS/A, and an allele for high activity is present in A/Br Af mice. The three enzyme activities are correlated with each other. The possible linkage between this gene and the Bgs locus on chromosome 9 is discussed.     

Gametic and pleiotropic defects in mouse fetuses with Hertwig''s macrocytic anemia

Pleiotropic effects on germ cell number, hematologic status, and body size are described in 12- to 15-day WBB6F1 normal (+/-) and defective (an/an) mouse fetuses, with special emphasis on gametogenesis. Differences between genotypes were apparent by Day 12. At 12 days, normal testes contained many germ cells and frequent normal mitoses, and the number of germ cells increased rapidly from Day 12 to Day 15. By contrast, 12-day an/an testes contained fewer germ cells, frequently degenerating, and many abnormal mitoses. Their number of germ cells decreased rapidly, so that almost none persisted to Day 15. Normal ovaries contained many germ cells, with much normal mitosis on Day 12 and 13, followed by meioses, but the smaller an/an ovaries contained few germ cells, with little mitosis, some meiosis, and very much degeneration. The erythrocyte counts of both normal and anemic fetuses increased approximately fourfold between 12 and 15 days, but at comparable ages, total counts were always lower in an/an fetuses than in normal littermates. At all ages, Hertwig's anemic (an/an) fetuses were somewhat smaller than their normal littermates. Although both W/Wv and Sl/Sld mice also show macrocytic anemia and germ cell failure, the great difference in etiology of their germ cell defects indicates that an/an gene action must be qualitatively different from that in either W/Wv or Sl/Sld mice.     

Ubiquitous expression and imprinting of Snrpn in the mouse

Snrpn is known to be abundantly expressed in rodent brain and heart, and in two separate studies with neonatal mouse brain it has been shown to be maternally imprinted, that is, the maternal allele is normally repressed. We now provide evidence on the expression profile and imprinting status of Snrpn throughout development. Using RT-PCR, we have established that Snrpn is further expressed at low levels in lung, liver, spleen, kidney, skeletal muscle, and gonads. Moreover, using mice with only maternal copies of Snrpn (maternal duplication for the chromosome region involved and parthenogenotes), we have shown that the gene is imprinted in all of these tissues and, generally, from the time the gene is first expressed at 7.5 days gestation. In contrast to the findings made with the imprinted genes, Igf2, Ins1, and Ins2, there is no evidence of tissue-specific imprinting in the embryo with Snrpn. Nor, as found with Igf2 and Igf2r, is there evidence of a window of biallelic expression between the germ line imprint and the time of gene repression. The absence of Snrpn expression in early embryos contrasts with the findings in ES cells.     

Linkage-dependent gene flow in a house mouse chromosomal hybrid zone

In the alpine valley of Valtellina there are two Robertsonian chromosomal races of house mouse, the Poschiavo (POS: 2n = 24-26) characterized by metacentric 8.12 and acrocentrics 2 and 10 and the Upper Valtellina (UV: 2n = 22-24) characterized by metacentrics 2.8 and 10.12. The races inhabit separate villages in the valley except in Sommacologna and Sondalo, where they both occur together with hybrids. A total of 179 mice from 16 villages were typed at 13 microsatellite loci. Seven of these loci were localized close to the centromeres of chromosomes 10 and 12, with the prediction that these regions on the race-specific chromosomes would be the most likely to experience a barrier to gene flow. The remaining six loci were localized at the telomeres of chromosomes 10 and 12 and at the centromeres of chromosomes that do not differ between the races. Substantial differences in allelic frequencies were found between the villages with POS and UV races at five of the loci at the centromeres of chromosomes 10 and 12 but at none of the other loci. These differences were not found to distinguish the two races in Sommacologna and Sondalo. Therefore, the centromeric regions of race-specific chromosomes do appear to experience a barrier to gene flow, although this can break down under intense interbreeding between the races. These results are considered in the context of Harrison's (1990) concept of the semipermeability of hybrid zones to gene exchange and in relation to parapatric speciation.     

Interactions between imprinting effects in the mouse

Mice with uniparental partial or complete disomies for any one of 11 identified chromosomes show abnormal phenotypes. The abnormalities, or imprinting effects, can be attributable to an incorrect dosage of maternal or paternal copies of imprinted gene(s) located within the regions involved. Here we show that combinations of partial disomies may result in interactions between imprinting effects that seemingly independently affect fetal and/or placental growth in different ways or modify neonatal and postnatal imprinting effects. Candidate genes within the regions have been identified. The findings are generally in accord with the "conflict hypothesis" for the evolution of genomic imprinting but do not clearly demonstrate common growth axes within which imprinted genes may interact. Instead, it would seem that any gene that represses or limits embryonic/fetal growth to the advantage of the mother--by any developmental means--will have been subject to evolutionary selection for paternal allele repression. Likewise, any gene that favors embryonic/fetal development at consequent cost to the mother--by any developmental means--will have faced selection for maternal allele repression. The classical Igf2-Igf2r axis may therefore be unique. The findings involve reinterpretation of older imprinting data and consequently revision of the mouse imprinting map.     

Characterization and imprinting status of OBPH1/Obph1 gene: implications for an extended imprinting domain in human and mouse

Human 11p15.5, as well as its orthologous mouse 7F4/F5, is known as the imprinting domain extending from IPL/Ipl to H19. OBPH1 and Obph1 are located beyond the presumed imprinting boundary on the IPL/Ipl side. We determined full-length cDNAs and complete genomic structures of both orthologues. We also investigated their precise imprinting and methylation status. The orthologues resembled each other in genomic structure and in the position of the 5' CpG island and were expressed ubiquitously. OBPH1 and Obph1 were predominantly expressed from the maternal allele only in placenta, with hypo- and not differentially methylated 5' CpG islands in both species. These results suggested that the imprinting domain would extend beyond the presumed imprinting boundary and that methylation of the 5' CpG island was not associated with the imprinting status in either species. It remains to be elucidated whether the gene is under the control of the KIP2/LIT1 subdomain or is regulated by a specific mechanism. Analysis of the precise genomic sequence around the region should help resolve this question.     

Shiverer gene maps near the distal end of chromosome 18 in the house mouse

Several mouse mutations cause unstable locomotion, tremor, seizures, and a reduced lifespan because of deficient myelin formation in the central nervous system. Mutant alleles at the shiverer (shi) locus are the only ones in this series with a selective molecular defect, namely, in myelin basic proteins (MBPs), which are virtually absent in shi homozygotes and 50% reduced in heterozygotes. In the present study, backcross and intercross matings indicate recombination of 21.2 +/- 3.3% between myelin deficient, shimld, and fused phalanges, syfp, a marker near the middle of chromosome 18. Recombination of shimld with twirler (Tw), a marker near the centromere, is 45.7 +/- 4.9%. Thus, the shi locus maps near the distal end of mouse chromosome 18 and is the first available marker for this region. Given the evidence of other workers that an MBP locus maps to the same mouse chromosome, and that part of this chromosome may be syntenic with an MBP-PEPA region on human chromosome 18, it is likely that shi is in or near an MBP gene.     

Chromosomal variation in the house mouse

Although the standard karyotype of the western house mouse, Mus musculus domesticus , consists entirely of acrocentric chromosomes, there are 97 distinct 'populations' that are characterized by various combinations of metacentric chromosomes that have arisen by Robertsonian (Rb) fusions and whole-arm reciprocal translocations (WARTs). In this review we discuss the processes behind the origin and fixation of these rearrangements and then present a unified list of all known metacentric populations and evaluate their phylogenetic relationships. Eleven independent phylogeographical 'systems', each consisting of 2–25 metacentric populations, were identified in Scotland, Denmark, Northern Europe–Northern Switzerland, Southern Switzerland, Northern Italy, Croatia, Spain, Central–Southern Italy, Peloponnesus, Mainland Greece and Madeira. There are six isolated metacentric populations that do not belong to any of these systems. To generate phylogenies of the metacentric populations within each system, we determined those outcomes with the fewest steps regarding accumulation of metacentrics by Rb fusions, WARTs and zonal raciation and taking into account geographical proximity. These phylogenies should be viewed as working hypotheses that will be refined with further chromosomal and molecular data and improvements in methods of phylogenetic reconstruction. The list of metacentric populations and our phylogenies are also published electronically and can be accessed at http://www.studenec.ivb.cz/Projects/RobertsonianMice/ .  © 2005 The Linnean Society of London, Biological Journal of the Linnean Society , 2005, 84 , 535–563.