Changes in the cellular composition of the deciduous membrane in physiologic pregnancy and late toxicosis

Cytochemical characteristics of the decidual membrane at a physiologically normal pregnancy and in cases of late toxicosis are presented. Three main cell types of the decidual membrane are defined: large decidual cells (LDC), small decidual cells (SDC) and granular cells of endometrium, or K-cells. Part of each cell type in the decidual membrane is determined. At physiologically normal pregnancy the part of the LDC makes 50-60% in the membranes and 80-85% in the basal plate of the placenta; SDC--10-18% in the fetal membranes and 1-2% in the basal plate of the placenta; K-cells--0.5-1%. At late toxicosis of pregnancy there is a change in relative and absolute amount of the decidual cells: the part of the LDC decreases up to 26-40% in the fetal membranes and up to 55% in the basal plate of the placenta; part of the K-cells at a slight form of preeclampsia rises up to 3-4%, at a severe form--up to 11-12%. The change in cell composition results in certain disturbances of physiological equilibrium of biologically active substances produced by the decidual cells. This correlates with the severity and clinical manifestations of the late toxicosis of pregnancy. Correlation of the decidual cells disfunction, directed to regulation of their reproduction and functioning, can become one of the elements of pathogenic treatment of the late toxicosis of pregnancy.     

Terminal differentiation in cultured Friend erythroleukemia cells.

Two populations of differentiated, hemoglobin-containing cells have been identified in cultures of Friend murine erythroleukemia cells (Friend cells): terminally differentiated benzidine-positive (B+) cells that are no longer capable of proliferation and are arrested in the G1 phase of the cell cycle, and their precursors, traversing B+ cells which undergo two or three cell divisions before reaching their terminally differentiated state. Thus Friend cells in suspension culture retain a limited capacity to synthesize DNA and divide after commitment to erythroid differentiation. We identified terminally differentiated cells using autoradiography after benzidine staining. We also developed a quantitative flow microfluorometric assay to distinguish cells that are terminally differentiated from those cells committed to differentiation but still capable of proliferation.We developed a purification procedure to isolate terminally differentiated Friend cells. Their DNA content was the same as that of the undifferentiated cells in G1 by both the diphenylamine reaction and a fluorescence assay. No loss of DNA was detected during the differentiation of Friend cells. As many as 72% of the total cells in a culture induced with DMSO (88% B+) were differentiated cells arrested in G1. As a control, a DMSO-resistant line derived from 745A neither differentiated nor arrested in G1 after growth in the presence of DMSO. The results of these studies were obtained using several compounds that induce differentiation and three independently isolated clones of 745A. We also observed arrest of differentiated cells in G1 with the two other well characterized, independently derived erythroleukemia cell lines, F4-1 and T3-C1-2.     

Decreased repair of radiation-induced DNA double-strand breaks with cellular differentiation.

Although the majority of mammalian cells in situ are terminally differentiated, most DNA repair studies have used proliferating cells. In an attempt to understand better the relationship between differentiation and DNA repair, we have used the murine 3T3-T proadipocyte cell line. In this model system, proliferating (stem) cells undergo growth arrest (GD cells) and subsequently terminally differentiate into adipocytes when exposed to media containing platelet-depleted human plasma. Pulsed-field gel electrophoresis was used to evaluate the induction and repair of DNA double-strand breaks (DSBs) after ionizing radiation. The levels of radiation-induced DSBs in GD and terminally differentiated cells were similar, but in both cases greater than those found in stem cells at each radiation dose tested (0 to 40 Gy); these differences appear to be due to growth arrest in G1 phase. DNA DSBs were repaired with biphasic kinetics for each cell type. For terminally differentiated cells 25% of DNA DSBs remained unrejoined compared with < 10% for GD and stem cells after a repair time of 4 h. These data indicate that terminal differentiation of 3T3-T cells is associated with a reduction in the repair of ionizing radiation-induced DNA DSBs.     

Differences in centromere positioning of cycling and postmitotic human cell types

Centromere positioning in human cell nuclei was traced in non-cycling peripheral blood lymphocytes (G0) and in terminally differentiated monocytes, as well as in cycling phytohemagglutinin-stimulated lymphocytes, diploid lymphoblastoid cells, normal fibroblasts, and neuroblastoma SH-EP cells using immunostaining of kinetochores, confocal microscopy and three-dimensional image analysis. Cell cycle stages were identified for each individual cell by a combination of replication labeling with 5-bromo-2-deoxyuridine and immunostaining of pKi67. We demonstrate that the behavior of centromeres is similar in all cell types studied: a large fraction of centromeres are in the nuclear interior during early G1; in late G1 and early S phase, centromeres shift to the nuclear periphery and fuse in clusters. Peripheral location and clustering of centromeres are most pronounced in non-cycling cells (G0) and terminally differentiated monocytes. In late S and G2, centromeres partially decluster and migrate towards the nuclear interior. In the rather flat nuclei of adherently growing fibroblasts and neuroblastoma cells, kinetochores showed asymmetrical distributions with preferential kinetochore location close either to the bottom side of the nucleus (adjacent to the growth surface) or to the nuclear upper side. This asymmetrical distribution of centromeres is considered to be a consequence of chromosome arrangement in anaphase rosettes.     

Cell Cycle Activation in Postmitotic Neurons is Essential for DNA Repair

Increasing evidence indicates that maintenance of neuronal homeostasis involves theactivation of the cell cycle machinery in postmitotic neurons. Our recent findings suggestthat cell cycle activation is essential for DNA damage-induced neuronal apoptosis.However, whether the cell division cycle also participates in DNA repair and survival ofpostmitotic, terminally differentiated neurons, is unknown. Here, we tested thehypothesis that G1 phase components contribute to the repair of DNA and are involved inthe DNA damage response of postmitotic neurons. In cortical terminally differentiatedneurons, treatment with subtoxic concentrations of hydrogen peroxide (H2O2) causedrepairable DNA double-strand breaks (DSBs) and the activation of G1 components of thecell cycle machinery. Importantly, DNA repair was attenuated if cyclin-dependentkinases CDK4 and CDK6, essential elements of G0→G1 transition, were suppressed.Our data suggest that G1 cell cycle components are involved in DNA repair and survivalof postmitotic neurons.     

DNA ligase I mRNA and enzyme levels in human hematopoietic cells under dimethyl sulfoxide-induced growth-arrest and differentiation.

About half the activity level of DNA ligase I in cycling human lymphoblastoid cells (Raji and Akata) remained in the cells arrested at G1 by a 4-day treatment with 1.5% dimethyl sulfoxide (DMSO), and one-third the enzyme activity in actively growing promyelocytic leukemia cells HL-60 was detected in the terminally differentiated cells after DMSO-treatment. In contrast, DNA ligase I mRNA was negligible in the G1-arrested Raji and differentiated HL-60 cells. The steady-state mRNA level was increased 9 h after release from DMSO in the G1-arrested Raji cells and reached a maximum at 18 h. These results indicate that gene expression of human DNA ligase I, but not activity level of the enzyme, is closely correlated with activity of cell proliferation.     

Cyclin C/cdk3 promotes Rb-dependent G0 exit

G0 is a physiological state occupied by resting or terminally differentiated cells that have exited the cell cycle. In contrast to the well-characterized cyclin/cdk-mediated inactivation of pRb that controls the G1/S transition, little is known about regulation of the G0/G1 transition. However, pRb is likely to participate in this process because its acute somatic inactivation is sufficient for G0-arrested cells to re-enter the cell cycle. One physiological regulator of this event may be cyclin C because its highest mRNA levels occur during G0 exit. Here we show that a non-cdk8-associated cellular pool of cyclin C combines with cdk3 to stimulate pRb phosphorylation at S807/811 during the G0/G1 transition, and that this phosphorylation is required for cells to exit G0 efficiently. Thus, G1 entry is regulated in an analogous fashion to S phase entry, but involves a distinct cyclin/cdk combination.     

Changes in ErbB2 (her-2/neu), ErbB3, and ErbB4 during growth, differentiation, and apoptosis of normal rat mammary epithelial cells.

Studies were undertaken to examine the natural role of ErbB2, ErbB3, and ErbB4 during the development of normal rat mammary epithelial cells (MECs) in vivo and in vitro. Immunohistochemical analysis demonstrated that mammary gland terminal end buds expressed abundant ErbB2 and ErbB4 but limited ErbB3 in pubescent rats, whereas luminal epithelial cells in nulliparous rats expressed ErbB2, ErbB3, and/or ErbB4. During pregnancy, ductal epithelial cells and stromal cells expressed abundant ErbB3 but limited ErbB2. Although ErbB2 and ErbB3 were downregulated throughout lactation, both receptors were re-expressed during involution. In contrast, ErbB4 was downregulated throughout pregnancy, lactation, and involution. Immunoblotting and immunoprecipitation studies confirmed the developmental expression of ErbB2 and ErbB3 in the mammary gland and the co-localization of distinct ErbB receptors in the mammary gland of nulliparous rats. In agreement with our in vivo findings, primary culture studies demonstrated that ErbB2 and ErbB3 were expressed in functionally immature, terminally differentiated and apoptotic MECs, and downregulated in functionally differentiated MECs. ErbB receptor signaling was required for epithelial cell growth, functional differentiation, and morphogenesis of immature MECs, and the survival of terminally differentiated MECs. Finally, ErbB4 expression did not interfere with functional differentiation and apoptosis of normal MECs.     

G1 block of the cell cycle during differentiation of F9 cells correlates with accumulation of inhibitors of the activity of cyclin-kinase complexes of proteins p21/Waf1 and p27/Kip

F9 teratocarcinoma cells have a very short duration of the cell cycle with a short G1-period typical for early embryonic cells. The cells are capable of differentiating towards parietal endoderm cells after the treatment with retinoic acid (RA) and dibutyryl-cAMP (db-cAMP). This leads to changes in the cell cycle; in particular, G1-period becomes longer, and then differentiated F9 cells leave the cycle to stay in G0-phase. It was previously reported that undifferentiated F9 cells undergo no G1 arrest of the cell cycle after DNA damage (Malashicheva et al., 2000). In the present work mechanisms of accumulation of G1-phase cells during differentiation induced by retinoic acid and db-cAMP were studied. Kinase activity of cyclin-Cdk complexes regulating the G1/S transition was analyzed. In differentiated F9 cells, the activity of cyclin-Cdk complexes, comprising Cdk4 and Cdk2 kinases and cyclins A and E, was significantly decreased. A decrease of Cdk4 kinase activity correlates with a drop of the cyclin D1 content. The amount of p21/Waf1 and p27/Kip inhibitors of the cyclin-kinase complexes increased in differentiated F9 cells. p21/Waf1 protein, which undergoes proteasomal degradation in undifferentiated F9 cells, was shown to be stable in their differentiated derivatives. Besides, in differentiated F9 cells p21/Waf1 and p27/Kip proteins can be detected with Cdk4/Cdk2-cyclin E complexes, in contrast to undifferentiated cells. Thus, we suggest that a G1/G0 block of the cell cycle taking place upon differentiation of F9 cells is likely to be caused by a decrease in cyclin-kinase activity due to stabilization and accumulation of p21/Waf1 and p27/Kip inhibitors and to their ability to associate with Cdk-cyclin complexes.     

Reduction in DNA repair capacity following differentiation of murine proadipocytes

It has been suggested that terminally differentiated mammalian cells have a decreased DNA repair capacity, compared with proliferating stem cells. To investigate this hypothesis, we have examined gamma-ray-induced DNA strand breaks and their repair in the murine proadipocyte stem cell line 3T3-T. By exposure to human plasma, 3T3-T cells can be induced to undergo nonterminal and then terminal differentiation. DNA strand breaks were evaluated using the technique of alkaline elution. No difference was detected among stem, nonterminally differentiated, and terminally differentiated cells in the initial levels of radiation-induced DNA strand breaks. Each of the strand break dose response increased as a linear function of gamma-ray dose. The strand breaks induced by 4 Gy rejoined following biphasic kinetics for each cell type. At each time point examined after irradiation, however, the percentage of strand breaks that had not rejoined in terminally differentiated cells was three to six times greater than in stem cells. The rate of strand break rejoining in nonterminally differentiated cells was of an intermediate value between that of the stem and of the terminally differentiated cells. These results indicate that, at least for 3T3-T cells, differentiated cells have a reduced capacity for DNA repair.     

Endoplasmic reticulum stress induced by oxidative stress in decidual cells: a possible mechanism of early pregnancy loss

Early pregnancy loss (EPL) is one of the most common complications of human reproduction. Combined with our previous proteomic studies on villous and decidual tissues of EPL, we found that alterations of the proteins involved in oxidative stress (OS), unfolded protein response (UPR) and proteolysis presented a complex and dynamic interaction at the maternal-fetal interface. In the present study, we developed a cell model of OS using normal decidual cells to examine cell viability and expression levels of proteins related to endoplasmic reticulum stress (ER stress) and UPR. We found that glucose regulated protein 78 (GRP 78) and ubiquitinated proteins were significantly up-regulated in hydrogen peroxide (H(2)O(2)) treated decidual cells in a dose-dependent manner. Excessive OS could influence proper function of UPR by decreasing VCP in decidual cells, thereby leading to cell damage as well as inhibition of cell growth and activation of apoptosis. Furthermore, when pretreated with MG 132, a pharmacological inhibition of the proteasome, the H(2)O(2) treated decidual cells became less viable and could not up-regulate the expression level of GRP 78 to resolve the protein-folding defects, which indicating that malfunction of UPR in decidual cells might aggravate the inhibitory effect of OS in decidual cells. The present results reveal that abnormal protein profiles associated with OS induced ER stress and malfunction of UPR might be involved in the development of EPL, and OS and ER stress are potential targets for pregnant care and prognosis in normal pregnancy and its disorders.     

DNA and nuclear protein measurement in columnar epithelial cells of human endometrium

Propidium iodide DNA flow cytometry, Feulgen-DNA, and nuclear light green protein scanning cytometry were performed in columnar epithelial cells of normal, nonmalignant human endometrium and endometrial adenocarcinomas. Columnar cells were identified by immunohistochemical staining for cytokeratin 18, an intermediate filament protein specifically present in columnar cell epithelium. DNA measurements derived from flow and scanning cytometry showed comparable results. The DNA content of the G0/G1 fraction of the adenocarcinomas had a considerable overlap with that of normal endometrium, with that of the carcinomas shifted toward higher values. For the carcinomas, no correlation was found with the histological grade, with the exception of the adenosquamous carcinomas. Most of the clinical stage I tumors showed a DNA content in the normal diploid region. Three of the four carcinomas of clinical stage II and higher had an increased DNA content. For the carcinomas, the percentage of cells in the proliferative fraction, as determined from scanning cytometric derived DNA histograms, was comparable to that of normal endometrium, or higher. No correlation was found with the histological grade. Tumors of clinical stage II and higher had intermediate values compared to carcinomas of lower stages. The nuclear protein/DNA ratio of malignant endometrium completely overlapped that of normal endometrium. Within the tumor population, no correlation was found with the histological grade, with the exception of the adenosquamous carcinomas, and clinical stage. Based on the aforementioned parameters, no discrimination could be obtained between normal and malignant endometrium. However, when the DNA content of the G0/G1 fraction was combined with the coefficient of variation of the nuclear protein/DNA ratio, a clear discrimination could be obtained with only two false-positive cases.     

Hemopoietic origin of certain decidual cell precursors in murine pregnancy

The possible hemopoietic origin of certain precursors of uterine decidual cells appearing during normal murine pregnancy was investigated in semiallogeneic hemopoietic chimeras with retained or regained fertility. Chimeras were produced by three different methods in two donor-host combinations: F1 [BALB/c female x C3H/HeJ male] cells introduced into the parental strain BALB/c female hosts or F1 [CBA/J female x C57BL/6 male] cells introduced into CBA/J female hosts. Prenatal chimeras (PN) were made by reconstituting mouse fetuses (day 13-17) with 10(6)-10(7) adult bone marrow or fetal liver cells through the yolk sac and they were allowed to be delivered naturally. Neonatal chimeras (NN) were made by injecting 1-2 x 10(7) adult bone marrow cells into the anterior facial vein of neonatal mice (less than 24 hr old). In both cases, experimental animals were raised to maturity. Ovary-transplanted chimeras (OT) were made by injecting 10(7) bone marrow cells into lethally irradiated (9.5 Gy) young adult female mice, followed 6 weeks later with bilateral orthotopic transplants of syngeneic ovary grafts to restore fertility. All female chimeras produced by the three different methods were mated with syngeneic male partners to produce normal pregnancy. The extent of chimerism at the cellular level was determined in all cases by a radioautographic identification of the H-2 phenotype of splenic lymphocytes and decidual cells and macrophages in the collagenase-dispersed decidua at day 11-16 of normal pregnancy, following a sandwich labelling with monospecific anti-H-2 antibodies and 125I-protein A. Morphological discrimination of typical decidual cells from macrophages in the collagenase-dispersed decidua was carried out on the basis of several distinctive markers: presence of surface Dec-1 and Thy-1 and absence of surface F4/80 or latex phagocytosis for decidual cells, in contrast to macrophages which were phagocytic and expressed F4/80 but not Dec-1 or Thy-1. While the degree of hemopoietic chimerism (judged by the incidence of donor-derived lymphocytes in the spleen) varied from animal to animal, in all three groups (PN, NN, and OT) comprising a total of 26 chimeras, the percentage of typical decidual cells expressing donor H-2 phenotype showed an excellent correlation with that for small lymphocytes in the spleen. These results reveal that at least a subpopulation of typical decidual cells of the pregnant uterus has a hemopoietic genealogy. A possible familial relationship of these cells to granulated metrial gland cells remains unclear.     

Placental changes in toxicoses in the second half of pregnancy]

An investigation of 88 placentas in toxicosis of the second half of pregnancy has detected symptoms of the immune alteration detailed by means of an electron microscopic analysis and immunomorphological investigations with the help of luminescent sera against immunoglobulins A, M. G and C3 fraction of complement. The alterations found are indicative of the participation of immune mechanisms in the formation of placental insufficiency and their important role in pathogenesis of gestational toxicosis.     

Mouse endometrial stromal cells produce basement-membrane components

During mouse pregnancy, uterine stromal cells transform into morphologically distinct decidual cells under the influence of the implanting embryo and a proper hormonal environment. Mechanical stimulation of hormonally primed uterine stromal cells leads to the same morphologic alterations. The decidualization of stromal cells is characterized by the accumulation of pericellular basement-membrane material. Decidualized stromal cells of pregnancy differ in this respect from stromal cells obtained from nonpregnant uteri, which are not associated with any significant amounts of basement-membrane components. Mouse decidual cells isolated from 6- to 7-day pregnant uteri explanted in vitro continue to synthesize basement-membrane-like extracellular matrix. Using immunohistochemistry and metabolic labeling followed by immunoprecipitation, SDS-PAGE, and fluorography, it was shown that the decidual cells synthesize laminin, entactin, fibronectin, type-IV collagen, and heparan sulfate proteoglycan. Stromal cells isolated from nonpregnant uteri and explanted in vitro produced the same basement-membrane components. Apparently, these cells were stimulated by the procedure used during isolation and explanation to undergo pseudodecidualization. We thus showed that stromal cells from pregnant and nonpregnant mouse uteri synthesize significant amounts of basement-membrane components in vitro, and hence could serve as a good model for the study of normal basement-membrane components.     

Establishment of a diploid reference value for DNA ploidy analysis by image cytometry in mouse cells.

OBJECTIVE: To establish a diploid reference value for DNA ploidy analysis of mouse cells (Mus musculus) by image cytometry using the CAS 200, an analysis system suitable for DNA content studies in human cells. STUDY DESIGN: To establish this standard, we used spleen imprints from 26 normal animals. A minimum of 150 lymphocytes present in each imprint was counted. The mean DNA content (pg/cell) of the G0/G1 peak and the DNA index observed in all samples were statistically analyzed. Cytospins with peritoneal cells from the same animals were then analyzed with this reference DNA value to confirm the diploid range. RESULTS: The DNA diploid reference value was determined by the mean DNA content of all spleen samples, which was 6.42 +/- 0.234 pg/cell, and the diploid range, defined as the diploid value +/- 10%, was 5.78-7.06 pg/cell. All the peritoneal samples showed a DNA diploid histogram, with a mean value for the G0/G1 peak DNA content of 6.742 +/- 0.15. CONCLUSION: The diploid reference value found in this study differs from those reported for other species, including the human being, and should be used in further studies of mouse pathology.