O. L. Serov

The X-autosome translocation in the common shrew (Sorex araneus L.): late replication in female somatic cells and pairing in male meiosis

Common shrews have an XX/XY1Y2 sex chromosome system, with the “X” chromosome being a translocation (tandem fusion) between the “original” X and an autosome; in males this autosome is represented by the Y2 chromosome. From G-banded chromosomes, the Y2 is homologous to the long arm and centromeric part of the short arm of the X. The region of the X that is homologous to the Y2 and also the telomeric region of the short arm of the X were found to be early replicating in somatic cells from a female shrew after 5-bromo-2′-deoxyuridine (BrdU) treatment in vitro. The remainder of the short arm of the X was shown to be late replicating. Electron microscopic examination of synaptonemal complexes in males at pachytene revealed pairing of the Y2 axis with the long arm of the X, and Y1 with the short arm. At early stages of pachytene, there is apparently extensive nonhomologous pairing between the X and Y1. In essence, the short arm of the shrew X chromosome behaves like a typical eutherian X chromosome (it is inactivated in female somatic cells and is paried with the Y1 during male meiosis) while the long arm behaves like an autosome (escapes the inactivation and pairs with the Y2).

Comparison of the three-dimensional organization of sperm and fibroblast genomes using the Hi-C approach

BackgroundThe three-dimensional organization of the genome is tightly connected to its biological function. The Hi-C approach was recently introduced as a method that can be used to identify higher-order chromatin interactions genome-wide. The aim of this study was to determine genome-wide chromatin interaction frequencies using the Hi-C approach in mouse sperm cells and embryonic fibroblasts.ResultsThe obtained data demonstrate that the three-dimensional genome organizations of sperm and fibroblast cells show a high degree of similarity both with each other and with the previously described mouse embryonic stem cells. Both A- and B-compartments and topologically associated domains are present in spermatozoa and fibroblasts. Nevertheless, sperm cells and fibroblasts exhibit statistically significant differences between each other in the contact probabilities of defined loci. Tight packaging of the sperm genome results in an enrichment of long-range contacts compared with the fibroblasts. However, only 30% of the differences in the number of contacts are based on differences in the densities of their genome packages; the main source of the differences is the gain or loss of contacts that are specific for defined genome regions. We find that the dependence of the contact probability on genomic distance for sperm is close to the dependence predicted for the fractal globular folding of chromatin.ConclusionsOverall, we can conclude that the three-dimensional structure of the genome is passed through generations without being dramatically changed in sperm cells.

Scheduled perturbation in DNA during in vitro differentiation of mouse embryo‐derived cells

Studies of sister chromatid exchanges (SCE) and recombination rate of certain mini‐satellite DNAs have demonstrated that their levels are considerably higher during the preimplantation stage than in latest developmental stages of embryos. It appeared likely that single‐strand DNA breaks (SSB) may be relevant to both events during early development. With this in mind, we estimated SSB during in vitro retinoic acid (RA)‐induced and spontaneous differentiation of mouse teratocarcinoma (EC) and embryonic stem (ES) cells. Using the method of nucleoid sedimentation and single‐cell DNA electrophoresis, we have observed a dramatic increase in the SSB during the first 2–4 mitoses after beginning of differentiation of EC cells, followed by a gradual return to the basal level characteristic of undifferentiated cells. The increase in the SSB was manifested as the appearance of mass nucleoids with slow sedimentation rates, as well as the low‐weight mass fragments in DNA patterns of most cells. We concluded that not less then half of genomic DNA has been nicked at the early steps of differentiation. The decrease in SSB level was observed in spite of continuing differentiation, as judged by embryonic antigens and morphological criteria. Also, the increase in the SCE level coincided with that of SSB, possibly being its consequence. The scheduled “surge” of SSB may be the earliest event in commencing differentiation at steps without a phenotypic manifestation. Mol. Reprod. Dev. 47:1–10, 1997.

Characterization of a new hybrid mink-mouse clone panel: chromosomal and regional assignments of the GLO, ACY, NP, CKBB, ADH2, and ME1 loci in mink (Mustela vison)

To expand the mink map, we established a new panel consisting of 23 mink-mouse clones. On the basis of statistical criteria (Wijnen et al. 1977; Burgerhout 1978), we developed a computer program for choice of clones of the panel. Assignments of the following mink genes were achieved with the use of the hybrid panel: glyoxalase (GLO), Chromosome (Chr) 1; acetyl acylase (ACY), Chr 5; creatine phosphokinase B (CKBB), Chr 10; alcohol dehydrogenase-2 (subunit B) (ADH2), Chr 8. Using a series of clones carrying rearrangements involving mink Chr 1 and 8, we assigned the gene for ME1 to the short arm of Chr 1 and that for ADH2 to Chr 8, in the region 8p12-p24. Mapping results confirm the ones we previously obtained with a mink-Chinese hamster panel. However, by means of an improved electrophoretic technique, we revised the localization of the gene for purine nucleoside phosphorylase (NP), which has been thought to be on mink Chr 2. It is reassigned to mink Chr 10.

Gene mapping in the common shrew (Sorex araneus; Insectivora) by shrew-rodent cell hybrids: chromosome localization of the loci for HPRT, TK, LDHA, MDH1, G6PD, PGD, and ADA.

We selected the common shrew (Sorex araneus) to generate the first insectivore gene map. Shrew-Chinese hamster and shrew-mouse somatic cell hybrid cells were constructed. When the 119 shrew-rodent clones were characterized, only shrew chromosomes were found to have segregated. A panel of hybrid clones was selected for gene assignment. The genes for hypoxanthine phosphoribosyl transferase (HPRT), glucose-6-phosphate dehydrogenase (G6PD), and malate dehydrogenase 1 (MDH1) were assigned to shrew Chromosome (Chr) de [which is the product of a tandem fusion between the ‘original’ mammalian X Chromosome (Chr) and an autosome], the genes for adenosine deaminase (ADA) and 6-phosphogluconate dehydrogenase (PGD) to Chromosome jl, the gene for thymidine kinase (TK) to Chromosome hn, and the gene for lactate dehydrogenase (LDHA) to chromosome ik. Further studies are in progress.

Secretion of Biologically Active Human Granulocyte Colony-Stimulating Factor (G-CSF) in Milk of Transgenic Mice

Two constructs were devised, containing the full-length gene of the human granulocyte colony-stimulating factor (G-CSF) fused with the 5′ and 3′ flanking promoter sequences of bovine alpha-S1-casein gene (CSN1S1). Both constructs contained a 1518-bp fragment that included exons 18 and 19 and 320 bp of the 3′ flanking region of bovine gene CSN1S1, but differed in size of the 5′ flanking sequences, which were of 721 bp, and exon 1 in construct pGCm1 and 2001 bp and exon 1 and intron 1 in construct pGCm2. With both constructs, transgenic mice were produced. The transgene expression was assessed using RT-PCR and immunochemically from the production of human G-CSF in milk of lactating females. Secretion of human G-CSF into the milk varied in a wide range, from 0.8 µg/ml to over 1 mg/ml, in mice with construct pGCm1 and was low (up to 60 µg/ml) or absent in mice with construct pGCm2. G-CSF glycosylation was incomplete in mice with transgene pGCm1 and complete in mice with pGCm2. G-CSF of transgenic mouse milk was shown to stimulate the formation and growth of granulocyte-containing colonies in human umbilical blood cell culture and be close or identical in physiological activity to the natural human G-CSF.

Reprogramming somatic cells by fusion with embryonic stem cells does not cause silencing of the Dlk1-Dio3 region in mice

AIM To examine the imprinted Dlk1-Dio3 locus in pluripotent embryonic stem (ES) cell/fibroblast hybrid cells. METHODS Gtl2, Rian, and Mirg mRNA expression in mouse pluripotent ES cell/fibroblast hybrid cells was examined by real-time reverse transcription-polymerase chain reaction. Pyrosequencing and bisulfate sequencing were used to determine the DNA methylation level of the Dlk1-Dio3 locus imprinting control region. RESULTS The selected hybrid clones had a near-tetraploid karyotype and were highly pluripotent judging from their capacity to generate chimeric embryos and adult chimeras. Our data clearly demonstrate that Gtl2, Rian, and Mirg, which are imprinted genes within the Dlk1-Dio3 locus, are active in all examined ES cell/fibroblast hybrid clones. In spite of interclonal variability, the expression of the imprinted genes is comparable to that of ES cells and fibroblasts. Quantitative analysis of the DNA methylation status of the intergenic differentially methylated region (IG DMR) within the Dlk1-Dio3 locus by pyrosequencing and bisulfite sequencing clearly showed that the DNA methylation status of the imprinted region in the tested hybrid clones was comparable to that of both ES cells and fibroblasts. CONCLUSION Reprogramming process in a hybrid cell system is achieved without marked alteration of the imprinted Dlk1-Dio3 locus.

Dominance of parental genomes in embryonic stem cell/fibroblast hybrid cells depends on the ploidy of the somatic partner

Two dozen hybrid clones were produced by fusion of diploid embryonic stem (ES) cells positive for green fluorescent protein (GFP) with tetraploid fibroblasts derived from DD/c and C57BL-I(I)1RK mice. Cytogenetic analysis demonstrated that most cells from these hybrid clones contained near-hexaploid chromosome sets. Additionally, the presence of chromosomes derived from both parental cells was confirmed by polymerase chain reaction (PCR) analysis of polymorphic microsatellites. All hybrid cells were positive for GFP and demonstrated growth characteristics and fibroblast-like morphology. In addition, most hybrid cells were positive for collagen type I, fibronectin, and lamin A/C but were negative for Oct4 and Nanog proteins. Methylation status of the Oct4 and Nanog gene promoters was evaluated by bisulfite genomic sequencing analysis. The methylation sites (CpG-sites) of the Oct4 and Nanog gene promoters were highly methylated in hybrid cells, whereas the CpG-sites were unmethylated in the parental ES cells. Thus, the fibroblast genome dominated the ES genome in the diploid ES cell/tetraploid fibroblast hybrid cells. Immunofluorescent analysis of the pluripotent and fibroblast markers demonstrated that establishment of the fibroblast phenotype occurred shortly after fusion and that the fibroblast phenotype was further maintained in the hybrid cells. Fusion of karyoplasts and cytoplast derived from tetraploid fibroblasts with whole ES cells demonstrated that karyoplasts were able to establish the fibroblast phenotype of the reconstructed cells but not fibroblast cytoplasts. Thus, these data suggest that the dominance of parental genomes in hybrid cells of ES cell/somatic cell type depends on the ploidy of the somatic partner.

“Chromosome Memory” of Parental Genomes in Embryonic Hybrid Cells

In the hybrid cells obtained by fusion of embryonic stem cells with adult differentiated cells, homologous chromosomes are in two ontogenetic configurations: pluripotent and differentiated. In order to assess the role of cis- and trans-regulation in the maintenance of these states, we studied a set of clones of hybrid cells of the type embryonic stem cells–splenocytes and used two approaches: segregation of parental chromosomes and comparison of pluripotency of the past hybrid cells and embryonic stem cells. The segregation test showed that the hybrid cells lost only the homologs of the somatic partner and this process was sharply accelerated when the cells were cultivated in nonselective conditions, thus suggesting the full or partial preservation of the initial differences in the organization of parental homologs. The descendants of the former hybrid cells, which had the karyotype similar to that of embryonic stem cells, demonstrated the level of pluripotency, comparable with that of embryonic stem cells despite the long-term effect of trans-acting factors from the somatic partner in the genome of hybrid cells. The data obtained are interpreted in the framework of the concept of “chromosome memory,” in the maintenance of which the key role is played bycis-regulatory factors.

B2-like repetitive sequence from the X Chromosome of the American mink (Mustela vison)

In analysis of the repeats from the mink X Chromosome (Chr), we have identified a B2-like repetitive sequence of 195 base pairs (bp) flanked by short direct repeats of 14 bp. It contains regions homologous to the split intragenic RNA polymerase III promoter and a 3′ A-rich region followed by an oligo(dA) sequence. A feature of the repeat is the presence of a perfect polypyrimidine tract 22 bp in length absent from the known Alu- and Alu-like sequences. Alignment of the mink B2-like sequence and mouse B2-consensus sequence allowed us to estimate their similarity as 55%. The repeat is present in 1–2×105 copies per mink genome and 2–4×103 copies per X Chr. In situ hybridization analysis demonstrated a similar distribution pattern of the B2-like repeat along the length of all the mink chromosomes including the X. We also observed the presence of mink B2-like hybridizable sequence in the genomes of other Carnivora species.