Factors affecting the cryosurvival of mouse two-cell embryos

A series of 4 experiments was conducted to examine factors affecting the survival of frozen-thawed 2-cell mouse embryos. Rapid addition of 1.5 M-DMSO (20 min equilibration at 25 degrees C) and immediate, rapid removal using 0.5 M-sucrose did not alter the frequency (mean +/- s.e.m.) of blastocyst development in vitro when compared to untreated controls (90.5 +/- 2.7% vs 95.3 +/- 2.8%). There was an interaction between the temperature at which slow cooling was terminated and thawing rate. Termination of slow cooling (-0.3 degrees C/min) at -40 degrees C with subsequent rapid thawing (approximately 1500 degrees C/min) resulted in a lower frequency of blastocyst development than did termination of slow cooling at -80 degrees C with subsequent slow thawing (+8 degrees C/min) (36.8 +/- 5.6% vs 63.9 +/- 5.7%). When slow cooling was terminated between -40 and -60 degrees C, higher survival rates were achieved with rapid thawing. When slow cooling was terminated below -60 degrees C, higher survival rates were obtained with slow thawing rates. In these comparisons absolute survival rates were highest among embryos cooled below -60 degrees C and thawed slowly. However, when slow cooling was terminated at -32 degrees C, with subsequent rapid warming, survival rates were not different from those obtained when embryos were cooled to -80 degrees C and thawed slowly (52.4 +/- 9.5%, 59.5 +/- 8.6%). These results suggest that optimal cryosurvival rates may be obtained from 2-cell mouse embryos by a rapid or slow thawing procedure, as has been found for mouse preimplantation embryos at later stages.(ABSTRACT TRUNCATED AT 250 WORDS)     

Viability of nuclei of two-cell mouse embryos stored at 4 degrees C and fused with blastomeres of fresh two-cell embryos.

This study compares the resistance of the nuclei and the cytoplasm of two-cell mouse embryos to short-term storage at low temperature above 0 degrees C. Two-cell embryos were stored at 4 degrees C for 24-96 h in PB1 containing 0.25, 0.5, 0.75, and 1.0 M sucrose. The development to blastocysts in culture was highest in the presence of 0.5 M sucrose. However, only 3% of the embryos developed into blastocysts after 96 h of storage. On the other hand, the viability of the nuclei of two-cell embryos stored at 4 degrees C was significantly prolonged when they were transplanted into a blastomere of enucleated fresh F1 (C57BL/6JXCBA) two-cell embryos. The proportions of chimeric embryos that developed to blastocysts were 88, 67, 76, 71, 64, 45, 32, and 20% following storage for 0, 48, 72, 96, 120, 144, 168, and 192 h, respectively. In addition, there was no difference in the coat color of the young derived from nuclei stored at 4 degrees C or fresh nuclei, although the proportions of chimeric embryos that developed into live young after transfer tended to decrease with increased storage time. Moreover, the viability of nuclei stored at 4 degrees C for 192 h was confirmed in the germ cell population of chimeric mice mated with albino mice. These results demonstrated that the nuclei in the two-cell mouse embryos were more resistant to storage at low temperature than the cytoplasm.     

Kinetics of chromosomal aberrations and first mitosis division in human lymphocytes exposed to mitomycin C

In order to understand the relationship between the chromosomal damage detectable at the first mitosis after mutagen treatment and the induced mitotic delay we studied the time pattern of both mitotic indices and chromosomal aberration frequencies in human lymphocytes treated in G1 with mitomycin C (2.5 microM) and cultured in vitro in the presence of 5-bromo-2'-deoxyuridine. Mitotic delay was observed in treated cells cultured for 81 h. At this point an increase in the frequency of chromosomal aberrations is evident and a higher proportion of abnormal cells enters mitosis, the long delay being due to the extensiveness of DNA damage. The importance of cell cycle progression for the detection of the maximal amount of induced chromosomal damage is discussed.     

Use of unstable chromosome aberrations for biological dosimetry after the first postirradiation mitosis

The loss of unstable chromosome aberrations after the first postirradiation mitosis makes their use difficult in radiation dosimetry. We describe here a method which, in a cell population observed at this stage, allows retrospective estimation of the frequencies of the unstable aberrations induced at the time of irradiation, and their use as a dosimeter. The laws controlling the behavior of unstable aberrations during mitosis were defined from a large-scale experiment on irradiated human lymphocytes. For cells undergoing the first, second, or third mitosis after irradiation, relationships were determined between the frequency, at irradiation time, of acentric fragments not arising from formation of dicentrics or rings, and the ratio of dicentrics and centric rings appearing without acentric fragments to the total number of dicentrics plus rings. On the basis of this ratio, the method described here provides an assessment of the postirradiation mitotic activity in a cell population. This assessment permitted estimation of the cell distribution and frequency of dicentrics plus centric rings, and of the frequency of acentric fragments at the time of irradiation. The use of this method for retrospective dosimetry after whole-body irradiation under various conditions of exposure is illustrated.     

Changes in the distribution of mitochondria in mouse embryos blocked at the two-cell stage

Changes in the distribution of mitochondria in the two-cell mouse embryos preceding the developmental arrest in vitro, caused by a genetically determined "two-cell block in vitro" or genisteine treatment, were examined vitally using the mitochondrial-specific probe rhodamine 123 and conventional fluorescence microscopy. In the former case, serious disturbances in the localization of mitochondria appeared already from the middle of two-cell stage, long before the time corresponding to the 2nd cleavage division. Comparison of the behavior of mitochondria in the embryos successfully developing between the one- and two-cell stages and that in the embryos that ceased to cleave suggests that the developmental arrest was accompanied by aggregation of the mitochondria into clusters. There are many such clusters unlike in the cytoplasm of normally developing embryos. Intracellular localization of clusters observed in the genisteine-treated embryos differed radically from that observed in the embryos blocked in vitro at the two-cell stage.     

Changes in the distribution of mitochondria in mouse embryos blocked at the two-cell stage

Changes in the distribution of mitochondria in the two-cell mouse embryos preceding the developmental arrest in vitro, caused by a genetically determined two-cell block in vitro or genisteine treatment, were examined vitally using the mitochondrial-specific probe rhodamine 123 and conventional fluorescence microscopy. In the former case, serious disturbances in the localization of mitochondria appeared already from the middle of two-cell stage, long before the time corresponding to the 2nd cleavage division. Comparison of the behavior of mitochondria in the embryos successfully developing between the one- and two-cell stages and that in the embryos that ceased to cleave suggests that the developmental arrest was accompanied by aggregation of the mitochondria into clusters. There are many such clusters unlike in the cytoplasm of normally developing embryos. Intracellular localization of clusters observed in the genisteine-treated embryos differed radically from that observed in the embryos blocked in vitro at the two-cell stage.Translated from Ontogenez, Vol. 36, No. 1, 2005, pp. 51–60.Original Russian Text Copyright © 2005 by Bogolyubova.     

Characteristic of structural and functional organization of two-cell mouse embryos exposed to inhibitors of cell proliferation

Within the framework of studying the "2-cell block in vitro" phenomenon, two variants of inhibitory-induced stoppage of development at a two-cell stage were produced and analysed. Mimosine arrested the cleavage on the G1/S interface, and genistein at G2 stage of the second cell cycle. In the experimentally blocked embryos a detailed study was made of the ultrastructural organization of blastomeres and intracellular localization of mitochondria vitally stained with rhodamine 123. The light and electron microscope observations testify to the viability of the embryos within a 22-24 hour exposure to inhibitors. Adhesive contacts between blastomeres were seen to slack after the treatment with both the inhibitors, resp., but in particular after genistein treatment. At the ultrastructural level no significant destructive modifications in blastomere organization were noticed. The cytoplasm of the control and treated embryo cells displayed diffusely distributed sheets of intermediate filaments, morphologically looking immature mitochondria and numerous aggregated lipid inclusions. The nuclear morphology was similar in both cases. Mitochondria of the treated embryo cells kept their ability to accumulate rhodamine 123, which testifies to their functional activity. However, the character of mitochondrial intracellular distribution was seen to change from diffuse to clustered. Numerous mitochondria clusters were concentrated mainly in the perinuclear area of blastomeres. As in the control ones, in the treated embryos the position of the nuclei was visualized by ring-like concentrations of mitochondria in the central part of blastomeres; in mimosine-treated cells the "rings" were thickened and contained mitochondria clusters. In genistein-treated embryos, mitochondria form numerous tiny clusters uniformly distributed in the cytoplasm; the perinuclear "rings" are still present, though less distinct than in the control embryos. Thus, it may be concluded that although the inhibitory treatment of two-cell embryos truly modified the mitochondrial distribution in these, the eventual pattern of such changes differed considerably from that characteristic of embryos in the state of "2-cell block in vitro". These results support the view on the unique character of morphofunctional modifications that occur in the latter embryos.     

Activity of steroid sulfatase in fibroblasts with numerical and structural X chromosome aberrations

Summary In cultured fibroblasts of patients with numerical and structural X chromosome aberrations the activity of steroid sulfatase (STS) is correlated with the number of functional STS gene copies. While normally, this X-linked gene is not inactivated, our data suggest that it may be subject to inactivation when carried on a structurally altered X-chromosome. Similar inactivation patterns have been reported earlier for the Xg locus which, like STS, is located on the distal protion of Xp.     

Sister-chromatid exchanges and chromosomal aberrations in chick embryos after treatment with the fungicide maneb

The genotoxic potential of a commercial formulation of the fungicide maneb (Maneb 80, containing 80% manganese ethylenebisdithiocarbamate as active ingredient) in chick embryos was evaluated, using as genetic end-points the frequency of sister-chromatid exchanges (SCE) and of chromosomal aberrations. Unincubated eggs were dipped in 0, 0.5, 1.5, 4.5, 13.5 or 27 g/l maneb aqueous solutions for 30 sec. Eggs were then incubated for 4 days. Maneb significantly increased SCE values at 13.5 g/l and at 27 g/l (means 1.33 and 1.74) over the control value (mean 0.87). The concentration of 27 g/l, which corresponds to 10.8 times the recommended maximum application level for use in the field, also resulted in a high mortality rate. No clastogenic effects following exposure to maneb were observed.     

Two-step freezing of two-cell rabbit embryos after partial dehydration at room temperature

The effect of rapid freezing and thawing on the survival of 2-cell rabbit embryos was examined. When embryos in 2.2 M-propanediol were directly plunged from room temperature to liquid nitrogen some of them survived after thawing (8%) but only if they had been pretreated by exposure to an impermeable solute, sucrose, that makes the blastomeres shrink osmotically before cooling. High survival (77-88%) in vitro was obtained when pretreated embryos were first held at -30 degrees C for 30-240 min before immersion into liquid nitrogen. Transfer of such frozen-thawed embryos gave a survival rate to live young similar to that obtained with controls (26% and 32% respectively). DMSO was less effective than propanediol; only 2 out of 38 sucrose-pretreated frozen-thawed embryos developed in vitro. The present work shows that a combination of partial dehydration of blastomeres at room temperature with their permeation by a cryoprotective agent offers a simple method for successful rapid freezing and thawing of rabbit embryos.     

Characterization of glutamine uptake in mouse two-cell embryos and blastocysts.

Mouse two-cell embryos and blastocysts take up [3H]glutamine in vitro at a constant rate for at least 15 min, depending on the concentration of glutamine and developmental stage of the embryo. Uptake by two-cell embryos can be resolved into two saturable components. The major contributing system is Na+ independent, inhibited by alanine, methionine, 2-amino-2-norbornanecarboxylic acid (BCH) or leucine and has a Km of 3856 +/- 672 mumols l-1 and Vmax of 436 +/- 58 fmol per embryo per 10 min. These features are characteristics of the ubiquitous system L transporter. The second component is Na+ dependent with Km of 1064 +/- 914 mumols l-1 and Vmax 107 +/- 47 fmol per embryo per 10 min. Similar Vmax and inhibition of this component by glycine suggest a low reactivity with the gly-system. Blastocyst uptake of glutamine is mainly by a Na(+)-dependent saturable mechanism with Km of 524 +/- 75 mumols l-1 and Vmax of 1264 +/- 101 fmol per embryo per 10 min which is inhibited by alanine, isoleucine, leucine and BCH, features characteristic of the system B0,+. The increase in uptake capacity as a consequence of the appearance of the system B0,+ may be related to increased metabolic requirements for glutamine, in the rapidly expanding blastocyst.     

Insulin-related peptides and the two-cell block to development in pre-implantation mouse embryos

Abstract. In many mammalian embryos development in vitro is arrested after the first zygotic division, a phenomenon known as the two-cell block. In the mouse several strains exhibit a two-cell block to further development and it was the purpose of this investigation to determine whether the inability of embryos to progress through the block was due to lack of insulin or insulin-like growth factors (IGFs) in the medium. Several factors have been implicated in the two-cell block, amongst which oxidative stress, glucose and missing maternal factors have been examined to date. Because of their anabolic and anti-apoptotic properties, IGFs are good candidates for such missing maternal factors. Using MF1 strain mice and M16 medium we have examined the effects of IGF-I, II and insulin on the two-cell block. No effects were discernable at concentrations known to support development of non-blocking embryos and we conclude that the IGFs and insulin may be excluded as critical factors in the two-cell block under the culture conditions used.     

1-Methyl-2-pyrrolidinone (NMP) does not induce structural and numerical chromosomal aberrations in vivo

1-Methyl-2-pyrrolidinone induces aneuploidy in yeast, but only under special treatment conditions. Other genotoxic effects have not been found in vitro, and in vivo no data are available in the literature. Therefore, NMP was investigated in the mouse micronucleus test and the Chinese hamster bone marrow test for structural and numerical chromosomal aberrations. These tests can detect both types of alterations as demonstrated by appropriate positive control substances (cyclophosphamide, vincristine sulfate and benomyl). NMP at single oral doses up to 3800 mg/kg body weight (∼ 80% of the LD₅₀) did not lead to an increase either in micronucleated erythrocytes or in structural or numerical chromosomal aberrations when bone marrow was sampled 16, 24 and 48 h after treatment in the micronucleus test or after 24 and 48 h for karyotype analysis.     

Checkpoint for DNA integrity at the first mitosis after oocyte activation

Activation of oocytes, arrested at the meiosis II (MII) in mammals, initiates meiotic release, mitotic divisions, and development. Unlike most somatic cell types, MII arrested female germ cells lack an efficient DNA integrity checkpoint control. Here we present evidence showing a unique checkpoint for DNA integrity at first mitosis after oocyte activation. Mouse oocytes carrying intact DNA cleaved normally after meiotic release, whereas 50% of oocytes harboring damaged DNA manifested cytofragmentation, a morphological hallmark of apoptosis. If not activated, DNA-damaged MII oocytes did not show apoptotic fragmentation. Further, activated, enucleated oocytes or enucleated fertilized oocytes also underwent cytofragmentation, implicating cytoplasmic coordination of the fragmentation process, independent of the nucleus. Depolymerization of either actin filaments or microtubules induced no cytofragmentation, but inhibited fragmentation upon oocyte activation. During the process of fragmentation, microtubule networks formed, then microtubule asters congregated at discrete locations, around which fragmented cellular bodies formed. Mitotic spindles, however, were not formed inactivated oocytes with damaged or absent DNA; in contrast, normal mitotic spindles were formed in activated oocytes with intact DNA. These results demonstrate that damaged DNA or absence of DNA leads to cytofragmentation after oocyte activation. Further, we found a mechanism of cytoskeletal involvement in the process of cytofragmentation. In addition, possible implication of the present findings in somatic cell cloning and human clinical embryology is discussed.