Glycogen-containing cells in the maternal and embryonic portions of the placenta in the rat and the common vole Microtus subarvalis

Differentiation sequences and further transfiguration of glycogen-rich cells during placenta development were investigated for the rat and field vole Microtus subarvalis (11-20 day gestation). The presence of glycogen is a characteristic feature of decidual cells located in the region of lateral sinusoids, as well as of metrial gland cells, secondary giant trophoblast cells and trophoblast cells in the connective zone of placenta. Glycogen-containing metrial gland cells and trophoblast cells of connective zone of placenta are found to underlie the layer of tertiary giant trophoblast cells that cover the wall of the central arteria. Thus, both maternal and embryo-derived glycogen-containing cells always accompany the tertiary giant trophoblast cells that penetrate deeply into the maternal part of placenta but do not contain glycogen. In the field vole placenta the cells of peripheral trophoblast subpopulation of the connective zone of placenta attaching to the decidua basalis are stained by PAS-reaction more intensely than deeply situated ones. These data, as well as other phenomena revealed here, show that maternal and trophoblastic cells attaching to each other in placenta contain, as a rule glycogen. Glycogen cells in rat placenta and trophoblast cells of peripheral subpopulation of connective zone of placenta are similar in many respects. In this connection, a possible protective role of glycogen-containing cells, that probably favour the co-existence of maternal and embryo-derived cells in placenta, is discussed.     

Ultrastructural features of the nucleus and cytoplasm of rat trophoblast cells of the connective zone of the placenta and labyrinth

Ultrastructural organization of the rat trophoblast cells in the connective zone of placenta and labyrinth was investigated on the 12-14th days of gestation. A clear distinction was revealed in the cytoplasm ultrastructure of two cell subpopulations within the connective zone of placenta, i.e. glycogen and trophospongium cells. The former display a well defined network of long thin channels of granular endoplasmic reticulum situated mainly around the glycogen clusters. On the contrary, the latter are rich in the smooth endoplasmic reticulum but lacking glycogen accumulation. Differences in the nucleolar ultrastructure in these two cell subpopulations are not very considerable. A characteristic feature of glycogen cells is the presence of numerous round or oval small-fibrillar nucleolus-like bodies with the diameter of granules 20 nm. The trophoblast cells of the labyrinth are heavily laden with polysomes, which sometimes attach to short channels of the granular endoplasmic reticulum. Not often there occur short profiles of the agranular endoplasmic reticulum. Nucleolus-like bodies are found in all the cell types examined. This means that the nucleolus-like bodies may arise not only on the lampbrush chromosomes in the oocytes or polytene chromosomes, but also in the somatic cells which are capable of dividing mitotically.     

Characteristics of trophoblast cell reproduction in the connective zone of the rat placenta. I. Determination of the degree of ploidy and the number of Barr bodies in interphase nuclei

The degree of ploidy in the interphase nuclei was determined in the connective zone of the rat's placenta on days 13 and 14 of embryo development. On day 13, the ploidy in the majority of nuclei was 2c or 4c; on day 14, the 4c nuclei were dominating, the share of 8c nuclei increasing. The number of Barr's bodies in each nucleus of the placental connective zone tends to increase with the increase in ploidy level. This is an evidence of a "genuine polyploidy" as a mechanism of the initial polyploidization of the given cell population.     

An electron microscopic study of lamp-brush chromosomes and the products of their activity during rabbit oogenesis]

An ultrastructural study of the rabbit oocyte nucleus was started from the early diplotene and extended to the large growth period to include the bilaminar follicle stage. During the large growth, the rabbit oocytes do not develop to the dictyate or "resting" stage, but remain at the diplotene. At the period preceeding the large growth (the early diplotene) lampbrush chromosomes are revealed made of the central axis 50 nm in diameter wish lateral fibrils. The aggregation of long loosely arranged fibrils makes the chromosome matrix. In the fibrillar zone of the chromosome, numerous roundish granules ca 45 nm in diameter and dense granule accumulations ca 0.15 mkm in diameter were visualized. Large fibrogranular bodies (1--2 mkm in diameter) are seen in association wish chromosomes. All these extra-nuclear bodies that appear on chromosomes differ in their size and pattern. These, likely as the nucleoli, may be considered as morphological expression of the genic activity of lampbrush chromosomes.     

Polyploidization and endomitosis in giant cells of rabbit trophoblast

Morphological and cytophotometric investigations have been performed on giant cells of the rabbit trophoblast to reveal a mechanism of nuclei polyploidization and define the level of polyploidy. The character of endomitotic chromosomes is found to differ and depend largely on the degree of nuclei polyploidy. Small chromosomes were found in nuclei with low levels of polyploidy. For highly polyploid nuclei, two stages are distinguished. In the first case condensed chromosomes join into bundles resembling Riesenchromosomen in plants, whereas in the second, decondensed chromosomal threads separate and disperse in the karyoplasm. The splitting does not involve nuclei-forming chromosomes in the region of the nucleolar organiser. The degree of polyploidy was determined on the 15th day of development. It was found that giant cell nuclei contain DNA in amounts corresponding to 32-512 chromosomal sets. Most of the nuclei have levels of 128c and 256c. Highly-polyploid nuclei disintegrate into small nuclei with the degree of polyploidy varying from 1c to 32c. Di- tri- and tetraploid nuclei predominate.     

Chromosomal aberrations and parameters of oxidative stress in Chernobyl clean-up workers in a remote period after ionizing radiation

This investigation was performed to test a supposition about the influence of disturbances in antioxidative system on cytogenetical parameters in Chernobyl' clean-up workers. It was shown that some cytogenetical parameters straightly correlated with the parameters of oxidative stress, while other cytogenetical parameters show just reverse correlations. Apparently, these relationships are not of cause-and-effect type, but they reflect a complex processes occurring in humans for a long period after radiation exposure.     

Genome multiplication of extravillous trophoblast cells in human placenta in the course of differentiation and invasion into endometrium and myometrium. II. Mechanisms of polyploidization

Peculiarities of the structure of interphase nuclei, mitotic activity, and Ki-67 protein intranuclear immunolocalization were studied to elucidate mechanisms of genome multiplication in proliferative and differentiating invasive extravillous trophoblast cells in the human placenta. The presence of numerous chromocenters was shown to be a characteristic feature of proliferative cell nuclei of both villous and extravillous trophoblast. At the beginning of extravillous trophoblast cell differentiation, i.e. in the proximal part of cell columns, some amount of cells with large nuclei containing enlarged chromocenters were found. DNA content was measured simultaneously with counting the number of chromocenters in similarly looking nuclei of squash preparations of placental villi. The increase in the ploidy level up to 4c-8c, accompanied by a slight increase in the number of chromocenters being not proportional to the ploidy level and not exceeding the diploid number of chromosomes of the human genome, was demonstrated. This suggests that genome multiplication of extravillous trophoblast cells may be accomplished by endoreduplication. In addition, pictures of endomitosis were seen at early steps of differentiation of EVT cells. The lack of polyploid mitotic figures or any obvious polyploidizing or restitutional mitoses suggests that these are not of considerable importance in genome multiplication of human EVT cells. However, the prevalence of metaphases at the boundary of the distal part of cell columns suggests that restitutional mitoses may be involved, even partly, in human trophoblast cell polyploidization. At later steps of differentiation, i.e. in the distal part of cell columns, the nuclear structure obviously changes, with a uniform "network" chromatin arrangement prevailing, whereas numerous chromocenters and features of endomitosis are no longer seen. The pattern of Ki-67 protein immunolocalization is also changing along the invasive pathway. In the proliferating stem cells and trophoblast cells of the proximal part of cell columns, Ki-67 was localized in the karyoplasm, chromocenters and numerous small nucleoli, whereas in the distal part of cell columns this protein was detected predominantly in 1-2 large nucleoli. The comparative analysis of the literature data on Ki-67 localization at different stages of cell cycle provided another evidence that EVT cells in the course of invasion may switch to the endoreduplication cycle. In agreement with the relevant report on rodent placentation, our present data suggest that acquirement of an invasive phenotype of EVT cells is accompanied by switching from mitotic division to endoreduplication cycle.     

Quantitative investigation of reproduction of condensed chromatin of sex chromosomes during trophoblast cell polyploidization and endoreduplication in the East European field vole Microtus rossiaemeridionalis

Simultaneous measurement of DNA content in cell nuclei and condensed chromatin bodies formed by heterochromatized regions of sex chromosomes (gonosomal chromatin bodies, GCB) has been performed in two trophoblast cell populations of the East-european field vole Microtus rossiaemeridionalis, namely in the proliferative population of trophoblast cells of the junctional zone of placenta and in the secondary giant trophoblast cells. One or two gonosomal chromatin bodies have been observed in trophoblast cell nuclei of all embryos studied (perhaps both male and female), In the proliferative trophoblast cell population, characterized by low ploidy levels (2c-16c), and in the highly polyploid population of secondary giant trophoblast cells (16c-256c), the total DNA content in GCB increased proportionally to the ploidy level. In separate bodies, the DNA content rose also in direct proportion with the ploidy level seen in the nuclei with both one and two GCBs in the two trophoblast cell populations. A certain increase in percentage of the nuclei with 2-3 GCBs was shown in the nuclei of the junctional zone of placenta; this may be accounted for by genome multiplication via uncompleted mitoses. In the secondary giant trophoblast cell nuclei (16c-256c), the number of GCBs did not exceed 2, and the share of nuclei with two GCBs did not increase, thus suggesting the polytene nature of sex chromosome in these cells. At different poloidy levels, the ratio of DNA content in the nucleus to the total DNA content in GCB did not change significantly giving evidence of a regular replication of sex chromosomes in each cycle of genome reproduction. In all classes of ploidy, the mean total DNA content in trophoblast cell nuclei with single heterochromatic body was less than in the nuclei with two and more GCBs. This may indicate that a single GCB in many cases does not derive from the fusion of two GCBs. To put it another way, in the nuclei with one GCB and in those with two or more GCBs, different chromosome regions may undergo heterochromatization. The regularities observed here are, most probably, associated with the peculiarities in the structure of X- and Y-chromosomes in a range of species of Microtus (M. agrestis, M. rossiaemeridionalis, M. transcaspicus). As a result, gonosomal chromatin bodies may include large blocks of both constitutive heterochromatin of X- and Y-chromosomes (in male and female embryos) and inactivated euchromatin of "lyonized" X-chromosome in female embryos. Therefore the presence of two or more GCBs in trophoblast cells of M. rossiaemeridionalis may be accounted for by both polyploidy and functional state of the nucleus, in which gonosomal constitutive heterochromatin and inactivated euchromatin form two large chromocenters rather than one. The differences in DNA content in GCBs in the nuclei with one and two GCBs seem to be an indirect indication that the two chromocenters may be formed by two different gonosomes, with the extent of their heterochromatization being higher than that in the nuclei with one GCB. GCBs in the trophoblast cells of M. rossiaemeridionalis are observed not only at the early developmental stages, as it was observed in rat at the first half of pregnancy (Zybina and Mosjan, 1967), but also at the later stages, up to the 17th day of gestation. At these stages, the nuclei with non-classical polytene chromosomes rearrange to those with a great number of endochromosomes, probably because of disintegration of chromosomes into oligotene fibrils. However, it does not seem unlikely that this process may involve heterochromatized gonosomal bodies, since only one or two large GCBs can be seen in the nuclei as before. The presence of prominent blocks of constitutive heterochromatin seems to favor a closer association of sister chromatids in polytene chromosomes, which prevents their dissociation into endochromosomes with the result that polyteny of sex chromosomes in the field vole trophoblast is probably retained during a longer period of embryonic development.