N. S. Zhdanova

The very long telomeres in Sorex granarius (Soricidae, Eulipothyphla) contain ribosomal DNA

Two closely related shrew species, Sorex granarius and Sorex araneus, in which Robertsonian rearrangements have played a primary role in karyotype evolution, present very distinct telomere length patterns. S. granarius displays hyperlong telomeres specifically associated with the short arms of acrocentrics, whereas telomere lengths in S. araneus are rather short and homogenous. Using a combined approach of chromosome and fibre FISH, modified Q-FISH, 3D-FISH, Ag-NOR staining and TRF analysis, we carried out a comparative analysis of telomeric repeats and rDNA distribution on chromosome ends of Sorex granarius. Our results show that rDNA sequences forming active nuclear organizing regions are interspersed with the long telomere tracts of all short arms of acrocentrics. These observations suggest that the major rearrangements that gave rise to today’s karyotype in S. granarius were accompanied by a profound reorganization of chromosome ends, which comprised extensive amplification of telomeric and rDNA repeats on the short arms of acrocentrics and finally contributed to the stabilization of telomeres. This is the first time that such telomeric structures have been observed in any mammalian species.

Derivation, Characterization, and Stable Transfection of Induced Pluripotent Stem Cells from Fischer344 Rats

The rat represents an important animal model that, in many respects, is superior to the mouse for dissecting behavioral, cardiovascular and other physiological pathologies relevant to humans. Derivation of induced pluripotent stem cells from rats (riPS) opens the opportunity for gene targeting in specific rat strains, as well as for the development of new protocols for the treatment of different degenerative diseases. Here, we report an improved lentivirus-based hit-and-run riPS derivation protocol that makes use of small inhibitors of MEK and GSK3. We demonstrate that the excision of proviruses does not affect either the karyotype or the differentiation ability of these cells. We show that the established riPS cells are readily amenable to genetic manipulations such as stable electroporation. Finally, we propose a genetic tool for an improvement of riPS cell quality in culture. These data may prompt iPS cell-based gene targeting in rat as well as the development of iPS cell-based therapies using disease models established in this species.

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.

Identification of all pachytene bivalents in the common shrew using DAPI-staining of synaptonemal complex spreads

A major problem in studies of synaptonemal complexes (SC) is the difficulty in distinguishing individual chromosomes. This problem can be solved combining SC immunostaining with FISH of chromosome-specific sequences. However, this procedure is expensive, time-consuming and applicable only to a very limited number of species. In this paper we show how a combination of SC immunostaining and DAPI staining can allow identification of all chromosome arms in surface-spreads of the SC of the common shrew (Sorex araneus L.). Enhancement of brightness and contrast of the images with photo editing software allowed us to reveal clear DAPI-positive and negative bands with relative sizes and positions similar to DAPI landmarks on mitotic metaphase chromosomes. Using FISH with DNA probes prepared from chromosome arms m and n we demonstrated correct recognition of the chromosomes mp and hn on the basis of their DAPI pattern. We show that the approach we describe here may be applied to other species and can provide an important tool for identification of individual bivalents in pachytene surface-spreads.

[Terminal regions of mammal chromosomes: plasticity and role in evolution].

The review considers data on the composition, organization, and functional significance of terminal regions in mammalian chromosomes, including telomeres and subtelomeric regions. Because of specific structure, features of DNA replication, and characteristic localization in somatic and meiotic cells, these regions are hot spots for many events associated with genome functioning in mammals. Instability of these regions is of special interest. Evidence suggesting that instability of chromosomal regions containing telomeric DNA is a factor of chromosome evolution is discussed. The association of size and structure of telomeric regions with replicative aging and cell immortalization is considered. The review deals in detail with classical and alternative mechanisms of telomere size control, the significance of changes in telomeric region length in ontogeny, oncotransformation, and evolution. The issues related to telomere destabilization and the role of this process in chromosome rearrangement formation and chromosome evolution are discussed. The origin of telomere repeats in interstitial chromosome sites, including regions of evolutionary fusions-fissions is given special consideration. The possible role of ribosomal repeats and mechanisms similar to ALT (alternative lengthening of telomeres) in telomere reorganization in some taxa are discussed.

Characterization of pig-mink cell hybrids: assignment of the TK1 and UMPH2 genes to pig chromosome 12

By fusion of thymidine kinase-deficient mink cells with pig leukocytes, a new type of cell hybrid was produced. It was demonstrated that pig chromosomes segregate in pig-mink hybrids and that hybrid cells contain no cytologically visible rearrangements between the chromosomes of parental species, or chromosome fragmentation. With a set of subclones of two primary hybrid clones, the genes for thymidine kinase-1 (TK1) and uridine 5′-monophosphate hydrolase-2 (UMPH2) were assigned to pig Chromosome (Chr) 12. A cell line with a single pig Chr 8 on the background of mink chromosomes was established. This clone could serve as a source of DNA for building a chromosome-specific library of pig Chr 8. The data obtained suggest that pig-mink cell hybrids can be used for mapping of pig chromosomes.

Regional assignments of eight genes on chromosome 2 in the American mink

Chromosomal rearrangements involving mink chromosome 2 in mink-Chinese hamster and mink-mouse hepatoma somatic hybrids were identified. By means of these rearrangements, we assigned the genes for HK1, GOT1, and PP to 2pter----p22, those for PGD, PGM1 and ENO1 to 2q24.4----qter, and that for NP and ADK to 2pter----p11.1.

Telomeric DNA allocation in chromosomes of common shrew (Sorex araneus, eulipotyphla)

Recently, we displayed an Iberian shrew species (Sorex granarius) with telomere structures unusual for mammals. Long telomeres on the short acrocentric arms contain an average of 213 kb of telomere repeats, whereas the other chromosomal ends have only 3.8 kb (Zhdanova et al., 2005; 2007). However, it is not clear whether these telomeres are typical for all shrew species or only for S. granarius. S. granarius and common shrew Sorex araneus are sibling species. In this study, using modified Q-FISH we demonstrated that telomeres in S. araneus from various chromosomal races distinguished by their number of metacentrics contain 6.8–15.2 kb of telomeric tracts. The S. araneus telomere lengths appear to correspond to telomere lengths in the majority of both shrew species and wild mammals, whereas S. granarius has telomeres with unique or rare structures. Using DNA and RNA high-specific modified probes to telomeric repeats (PNA and LNA), we showed that interstitial telomeric sites in S. araneus chromosomes contain mainly telomeric DNA and that their localization coincide with some evolutionary breakpoints. Interstitial telomeric DNA in S. granarius chromosomes was not revealed. Thus, the distribution of telomeric DNA may be significantly different, even in closely related species whose chromosomes are composed of almost identical chromosomal arms.

The structure of long telomeres in chromosomes of the Iberian shrew

It is shown that the size, localization, and structure of telomeres in the Iberian shrew (Sorex granarius) are not characteristic of mammals. In this species, long telomeres of an average size of 213 kb are localized on the short arms of all 32 acrocentrics; ribosomal blocks and active nucleolus-organizing regions (NORs) were also discovered there. At the remaining chromosome ends the average size of telomeres is 3.8 kb. However, in a closely related species, Sorex araneus, all telomeres have size similar to that of human telomeres, i.e., 6.8–15.2 kb. Despite the fact that some long telomeres contain ribosomal repeats in addition to telomeric ones, the long telomeres have preserved asymmetry of G- and C-rich strands as in functional telomeres. It is probable that long telomeres were formed in meiosis at the stage of chromosome bouquet as a result of global reorganization of the chromosome ends. The provoking factors for such reorganization might be the fission of several metacentrics and the necessity of telomerization of the resulting acrocentrics.

Chromosomal instability of mouse pluripotent cells cultured in vitro

The perspectives of using embryonic stem cells (ESCs) and induced pluripotent stem cells (iPSs) in clinics makes the karyological analysis of these cells an important issue. In the present study, using methods of classical and molecular cytogenetics of chromosome, we carried out a karyological study of two mouse ES and two iPS cell lines derived de novo. We obsererved the X chromosome monosomy in all studied ES and iPS cell lines, which makes the modal number of chromosomes in these cell lines equal to 39. The chromosomal instability (aneuploidy) was revealed in both studied iPS cell lines. Moreover, we have detected chromosomal rearrangements and chromosomal fragments in one of studied iPS. Our findings stress the importance of the careful cytogenetic evaluation of a pluripotent cell line, especially iPS cell lines, which should be carried out prior to any clinical use of these cells.