[Sex inversion and epigenetic regulation in Vertebrates].

This review discusses issues related to the regulation of sex determination and differentiation in various groups of Vertebrates. Special attention was paid to factors of external and internal control for various genetic systems of sex determination, as well as to the epigenetic control of this process. Opportunities for sex inversion in various animals were also discussed.

[Effect of sex inversion in embryos of domestic chicken (Gallu gallus domesticus) by influence of letrozole and tamoxifen].

Realization of program of sex formation in multicellular organisms is a complex multistage process. The role of the inductor in this process is assigned to sex hormones synthesized by cells of the emerging gonads. The action of androgens on the formation of the male is now well understood. However, little is known about the involvement of estrogen the female gonad formation and the formation of a female as a whole. Here we present the results of experimental sex inversion in female chickens produced by aromatase inhibition and by the action of tamoxifen on chicken embryos. We have shown various masculinizing effect depending on the dose of active substance and the number of injections. We have noted that inhibition of aromatase does not block meiotic prophase in oogoniums. We have suggested that there are differences in the mechanisms of action of retinoic acid and estrogens on oogenesis. We have first shown proteins and nucleoproteins that interact with the estrogen receptor 1 and provided maps of their gene localization in human and chicken genomes.

[The effect of retinoic acid on the meiosis in the chick embryo (Gallus gallus domesticus)].

In this study it was shown that the injection of retinoic acid (RA) into incubated eggs on day 9 or 14 induced entry the males germ cells into preleptotene stage of prophase I on day 17, which are absent in the control embryos. At the same time the meiosis marker SCP3 was detected in the germ cells. Which was also absent at control embryos. On day 19 in male embryos the number of male germ cells at the stage preleptoteny increased, but there were no germ cells in the following stages of the prophase of meiosis. In 20-day-old chicks meiotic germ cells were absent. Thus, white it is shown that the influence of RA on the developing chicken embryos induces the entry of germ cells into preleptotene stage of prophase I meiosis. However, further meiotic transformations don't occur. Thus RA is only one of many factors providing meiotic cell division.

[Correlations of sister chromatids cohesion complexes distribution with histones H3 and H4 modifications].

The formulation of "histone code" theory brings active investigations of the role of histone modifications and other supramolecular factors of DNA condensation in transcription regulation. In this work, we have analyzed the localization of methylated histones on 9, 36 and 79 lysines, hyperacetylated H4 histone, and subunits of cohesion complex DRAD21 relatively of Drosophila melanogaster polytene chromosomes chromatin condensation. We propose the hypotheses of a cascade regulation of transcription activity defined by histone modifications and the adaptive role of sister chromatids cohesion in the transcription of high active and extensive genes.

[Microsatellites from the linkage groups E26C13 and E50C23 are located on the Gallus gallus domesticus microchromosomes 20 and 21].

Using the method of dual color fluorescence in situ hybridization and a set of chromosome-specific BAC clones, localization of microsatellites LEI0345 and LEI0336 on chicken (Gallus gallus domesticus) mitotic chromosomes was performed. Microsatellite LEI0345 (TAM 32, BAC clones r49A10 and r55M23) from the linkage group E26C13 was mapped to microchromosome 20, while microsatellite LEI0336 (TAM 32, BAC clones r19E22 and r13C08) from the linkage E50C23 was assigned to microchromosome 21. Using the PCR technique, an attempt to assign the suitable markers to chromosome-specific BAC clones was made. The PCR data confirmed the microsatellite localization performed with the help of FISH technique and showed the presence of the LEI0345 microsatellite sequence on many other chicken microchromosomes, except for microchromosomes 19 and 22. Linkage groups E26C13 and E50C23 were assigned to microchromosomes 20 and 21, respectively.

[Comparative localization of chicken five functional genes and three microsatellites on quail mitotic chromosomes by two-color fish-hybridization].

In order to localize chicken genes and microsatellites we used two-color FISH and chicken chromosome specific BAC-clones. All BAC-clones were verified by PCR. Analysis of the results obtained showed that: maf gene formed one linkage group with mc1r gene (CJA11), aldhlal--with igvps gene (CJA15), pno--with acaca gene (CJA19), fzf--with bmp7 gene (CJA20), cw01--with ubapw2omega gene (CJAW). Microsatellite ADL0254 was localized jointly with insr gene (CJA28), while LE10342 and MCW0330 microsatellites--with hspa5 gene (CJA17). The same work was fulfilled on chicken mitotic chromosomes. We obtained other results. maf gene was localized independently of mc1r (GGA11), aldh1a1 was localized independently of igvps gene (GGA15), and pno gene (GGA19) was localized independently of acaca gene. ADL0254 and LE10342 microsatellites had two sites of localization (GGA28, GGA17 accordingly and other site). Localization for genes cw01 and fzf and for MCW0330 microsatellite was confirmed.

[Problems of sex determination in birds exemplified by Gallus gallus domesticus].

The current views of sex determination in birds are considered mostly with the example of Gallus gallus domesticus, the species best studied in this respect. Data on the appearance of primordial germ cells, their migration to the primordial gonads, the role of hormonal factors in the regulation of sex differentiation, the sex chromosomes, putative genetic mechanisms of sex determination, and a possible contribution of dosage compensation are described. The review discusses the two best-grounded hypotheses on the roles of the Z and W chromosomes in sex determination.

[Localization of the NotI clones from human chromosome 3 on quail microchromosomes].

For the purpose of comparative mapping of quail (Coturnix c. japonica) and human (Homo sapiens) genomes, DNA fragments from human chromosome 3 (HSA3p14-21 and HSA3q13-23) were localized on quail mitotic chromosomes. Using the method of double-color fluorescence DNA-DNA in situ hybridization, these fragments were mapped to two different microchromosomes. Earlier, similar studies were performed using chicken mitotic chromosomes. There it was demonstrated that the clones of interest were distributed among three microchromosomes (GGA12, GGA14, and GGA15). Thus, interspecific difference in the location of human chromosome 3 DNA fragments in the genomes of closely related avian species was discovered. A new confirmation of the hypothesis on the preferable localization of the gene-rich human chromosome regions on avian microchromosomes was obtained. At the same time, a suggestion on the localization of some orthologous genes in the genome of the organism under study was made: ARF4, SCN5A, PHF7, ABHD6, ZDHHC3, MAPKAPK3, ADSYNA (homolog of chicken chromosome 12), DRD2, PP2C-ETA, RAB7, CCKAR, and PKD1 (homolog of chicken chromosome 15). However, localization of the corresponding quail genes needs to be confirmed, as far as the sequences used were only the orthologs of the corresponding chicken genes.

Chromosomal localization of seven HSA3q13-->q23 NotI linking clones on chicken microchromosomes: orthology of GGA14 and GGA15 to a gene-rich region of HSA3.

Double-color fluorescence in situ hybridization was performed on chicken chromosomes using seven unique clones from the human chromosome 3-specific NotI linking libraries. Six of them (NL1-097, NL2-092, NL2-230, NLM-007, NLM-118, and NLM-196) were located on the same chicken microchromosome and NL1-290 on another. Two chicken microchromosome GGA15-specific BAC clones, JE024F14 containing the IGVPS gene and JE020G17 containing the ALDH1A1 gene, were cytogenetically mapped to the same microchromosome that carried the six NotI linking clones, allowing identification of this chromosome as GGA15. Two GGA14-specific clones, JE027C23 and JE014E08 containing the HBA gene cluster, were co-localized on the same microchromosome as NL1-290, suggesting that this chromosome was GGA14. The results indicated that the human chromosomal region HSA3q13-->q23 is likely to be orthologous to GGA15 and GGA14. The breakpoint of evolutionary conservation of human and chicken chromosomes was detected on HSA3q13.3-->q23 between NL1-290, on the one hand, and six other NotI clones, on the other hand. Considering the available chicken-human comparative mapping data, another breakpoint appears to exist between the above NotI loci and four other genes, TFRC, EIF4A2, SKIL and DHX36 located on HSA3q24-->qter and GGA9. Based on human sequences within the NotI clones, localization of the six new chicken coding sequences orthologous to the human/rodent genes was suggested to be on GGA15 and one on GGA14. Microchromosomal location of seven NotI clones from the HSA3q21 T-band region can be considered as evidence in support of our hypothesis about the functional analogy of mammalian T-bands and avian microchromosomes.

[Libraries of large-insert genomic clones as a tool for molecular cytogenetic analysis of avian genome].

Integration of molecular and cytegenetic levels of investigation results in complex understanding of structural and functional genome organization. Gridded libraries of large-insert genomic clones represent a powerful tool of the genome analysis. Their utilization provides coordination of data on molecular organization of nucleic acids with cytogenetic data on the chromosome structure. These libraries played an important role in sequencing of genomes of human, mouse, and other organisms as an instrument linking molecular biological and cytogenetic data via construction of contigs and their localization on the chromosomes. They also enabled analysis of orthology between the mammalian genomes. The existing avian libraries fit molecular cytogenetic analysis of the class Aves genome, and can be successfully used for the isolation and characterization of large genomic fragments. This provides utilization of these libraries not only for the chromosome mapping, but also for positional cloning and search for candidate genes for quantitative traits.

[Localization of cohesin complexes of polytene chromosomes of Drosophila melanogaster located on interbands]. / Lokalizatsiia kompleksov kogezii v politennykh khromosomakh Drosophila melanogaster sviazana s mezhdiskami.

The distribution of cohesin complex in polytene chromosomes of Drosophila melanogaster was studied. Cohesin is a complicated protein complex which is regulated by the DRAD21 subunit. Using immunostaining for DRAD21p, the cohesins were shown to be preferentially located in the interband regions. This specificity was not characteristic for puffs, where uniform staining was observed. The presence of a few brightly fluorescent regions (five to ten per chromosome arm) enriched with cohesin complexes was shown. Some of these regions had permanent location, and the others, variable location. No antibody binding was detected in the chromocenter. Immunostaining of interphase nuclei of neuroblasts revealed large cohesin formations. On the polytene chromosomes of D. melanogaster, the Drad21 gene was mapped to the chromocentric region (81) of the L arm of chromosome 3.

[Comparative compositional mapping of chicken and quail chromosomes]. / Sravnitel'noe kompozitsionnoe kartirovanie khromosom kuritsy i perepela.

The distribution of various isochore families on mitotic chromosomes of domestic chicken and Japanese quail was studied by the method of fluorescence in situ DNA--DNA hybridization (FISH). DNA of various isochore families was shown to be distributed irregularly and similarly on chromosomes of domestic chicken and Japanese quail. The GC-rich isochore families (H2, H3, and H4) hybridized mainly to microchromosomes and a majority of macrochromosome telomeric regions. In chicken, an intense fluorescence was also in a structural heterochromatin region of the Z chromosome long arm. In some regions of the quail macrochromosome arms, hybridization was also with isochore families H3 and H4. On macrochromosomes of both species, the pattern of hybridization with isochores of the H2 and H3 families resembled R-banding. The light isochores (L1 and L2 families) are mostly detected within macrochromosome internal regions corresponding to G bands, whereas microchromosomes lack light isochores. Although mammalian and avian karyotypes differ significantly in organization, the isochore distribution in genomes of these two lineages of the warm-blooded animals is similar in principle. On macrochromosomes of the two avian species studied, a pattern of isochore distribution resembled that of mammalian chromosomes. The main specific feature of the avian genome, a great number of microchromosomes (about 30% of the genome), determines a compositional specialization of the latter. This suggests the existence of not only structural but also functional compartmentalization of the avian genome.

Compositional mapping of chicken chromosomes and identification of the gene-richest regions.

'Compositional chromosomal mapping', namely the assessment of the GC level of chromosomal bands, led to the identification, in the human chromosomes, of the GC-richest H3+ bands and of the GC-poorest L1+ bands, which were so called on the basis of the isochore family predominantly present in the bands. The isochore organization of the avian genome is very similar to those of most mammals, the only difference being the presence of an additional, GC-richest, H4 isochore family. In contrast, the avian karyotypes are very different from those of mammals, being characterized, in most species, by few macrochromosomes and by a large number of microchromosomes. The 'compositional mapping' of chicken mitotic and meiotic chromosomes by in-situ hybridization of isochore families showed that the chicken GC-richest isochores are localized not only on a large number of microchromosomes but also on almost all telomeric bands of macrochromosomes. On the other hand, the GC-poorest isochores are generally localized on the internal regions of macrochromosomes and are almost absent in microchromosomes. Thus, the distinct localization of the GC-richest and the GC-poorest bands observed on human chromosomes appears to be a general feature of chromosomes from warm-blooded vertebrates.

[Destabilizing effect of chicken selection using the functional adrenal reserves criteria]. / Destabiliziruiushchii éffekt otbora kur po funktsional'nym rezervam nadpochechnikov.

Chicken lines produced by divergent selection for the functional adrenal reserves showed significant between-line differences in the content of corticosterone and other hormones (thyroxin, progesterone), as well as in body weight, early maturation, and egg yield. DNA fingerprinting with the pGB725 probe revealed molecular changes in genomic DNA of the chicken lines subjected to plus and minus selection. The genetic distances between the original population and the selected chicken lines, which were estimated from the molecular hybridization patterns, reflected the history of breeding. Analysis of mixed DNA from several individuals of each line revealed specific hybridization bands that could serve as DNA markers during selection for the high and low corticosterone levels in blood.