Analysis of the fifth cell cycle of mouse development

The 5th cell cycle of mouse development was analyzed to determine the lengths of each cell cycle phase. The DNA content of Feulgen-stained blastomere nuclei was measured at various times throughout the cell cycle by microdensitometry. To achieve precise timing of the start of the 5th cell cycle, experiments utilized isolated 16-cell blastomeres and cell pairs obtained by in-vitro division of isolated 8-cell blastomeres. The following estimates were made for a mixed population of polar and apolar 16-cell blastomeres: G1, less than or equal to 2 h; S, 8-9 h; G2 + M, 2 h. No significant difference was found in the timing of DNA synthesis between polar and apolar cells or between cell pairs and whole embryos.     

Midblastula transition (MBT) of the cell cycles in the yolk and pigment granule-free translucent blastomeres obtained from centrifuged Xenopus embryos

We obtained translucent blastomeres free of yolk and pigment granules from Xenopus embryos which had been centrifuged at the beginning of the 8-cell stage with cellular integrity. They divided synchronously regardless of their cell size until they had decreased to 37.5 microm in radius; those smaller than this critical size, however, divided asynchronously with cell cycle times inversely proportional to the square of the cell radius after midblastula transition (MBT). The length of the S phase was determined as the time during which nuclear DNA fluorescence increased in Hoechst-stained blastomeres. When the cell cycle time exceeded 45 min, S and M phases were lengthened; when the cell cycle times exceeded 70 min, the G2 phase appeared; and after cell cycle times became longer than 150 min, the G1 phase appeared. Lengths of G1, S and M phases increased linearly with increasing cell cycle time. Enhanced green fluorescent protein (EGFP)-tagged proliferating cell nuclear antigen (PCNA) expressed in the blastomeres appeared in the S phase nucleus, but suddenly dispersed into the cytoplasm at the M phase. The system developed in this study is useful for examining the cell cycle behavior of the cell cycle-regulating molecules in living Xenopus blastomeres by fluorescence microscopy in real time.     

DNA synthesis in the second and third cell cycles of mouse preimplantation development. A cytophotometric study

Female Swiss mice were sacrificed at 2 h intervals between 16–30 and 40–56 h after insemination. One-, 2- and 4-cell embryos were stained by the Feulgen method and cytophotometric measurement of their nuclear DNA content was carried out. The cells with 2C and 4C DNA content were assumed to be in G1 and G2 phase and those with intermediate DNA content in S phase of the cell cycle. The fractions of cells which had passed a given phase of the cell cycle were calculated for various times after insemination and utilized for measurements of the second and third cell cycle timing. Results of measurements for the second cell cycle: G1 phase 1.3 h, S phase 6.1 h, G2 phase 15.4 h, whereas for the third cell cycle: G1 phase 1.6 h, S phase 7.4 h, G2 phase 0.5 h. The first cleavage division was calculated as 1.6 h, the second as 1.3 h and the third as 1.2 h. Complete intra-embryonic synchronization of the DNA-synthesizing nuclei was preserved during the entire synthesis phase of 2-cell embryos, while in 4-cell embryos they were slightly asynchronized. Among mitotic cells of the first cleavage division and G1 cells of 2-cell embryos a slight interembryonic asynchronization was found which deepened during subsequent cell cycle phases.     

Determination and synchronisation of G1-phase of the cell cycle in 2- and 4-cell mouse embryos

Incorporation of [3H]thymidine at different concentrations into mouse embryos at early developmental stages was determined by autoradiography. Methods to synchronise the G1-phase of mouse 2- and 4-cell embryos were also investigated. The results showed that the ability of embryos to incorporate [3H]thymidine increased with development. Embryos at the 4-cell stage were not labelled when the concentration of [3H]thymidine was lower than 5 microCi/ml, whereas the nuclei of embryos at morula and blastocyst stages began to show silver grains at a concentration of 0.1 microCi/ml of [3H]thymidine. After 2- and 4-cell mouse embryos were synchronised at the onset of G1-phase by treatment with low temperature or nocodazole, and DNA synthesis was detected by autoradiography, the duration of G1-phase was estimated. The result showed that 43% of the 2-cell embryos had a G1-phase of < or = 1 h, 22% had a G1-phase of < or = 2 h, 22% had a G1-phase of < or = 3 h and 13% had a G1-phase of < or = 4 h. The G1-phase in 85% of the 4-cell embryos was < or = 3 h, that in 8% of embryos was < or = 4 h and that in 7% of embryos was < or = 5 h. The toxicity of nocodazole on mouse embryo development was assessed based on both blastocyst formation and the number of blastomeres, and the results indicated that the effect of nocodazole on embryo development and cell cycle block was dose-dependent. The minimum concentration of nocodazole for metaphase block of mouse late 2-cell embryos was 0.05 microM, and the appropriate concentrations which did not impair development were 0.05-0.5 microM.     

Reproductive cell specification during Volvox obversus development

Asexual spheroids of the genus Volvox contain only two cell types: flagellated somatic cells and immotile asexual reproductive cells known as gonidia. During each round of embryogenesis in Volvox obversus, eight large gonidial precursors are produced at the anterior extremity of the embryo. These cells arise as a consequence of polarized, asymmetric divisions of the anteriormost blastomeres at the fourth through nine cleavage cycles, while all other blastomeres cleave symmetrically to yield somatic cell precursors. Blastomeres isolated from embryos at any point between the 2-cell and the 32-cell stage cleaved in the normal pattern and produced the same complement and spatial distribution of cell types as they would have in an intact embryo. This result indicates that intrinsic features control the cleavage patterns and developmental potentials of blastomeres, and rules out any significant role for cell-cell interactions in gonidial specification. When substantial quantities of anterolateral cytoplasm were deleted from uncleaved gonidia or 4-cell stage blastomeres, the cell fragments frequently regulated and embryos were produced with the expected number of asymmetrically cleaving cells and gonidial precursors at their anterior ends. However, when anterior cytoplasm was deleted from 8-cell stage blastomeres, the depleted cells frequently failed to cleave asymmetrically and produced no gonidial precursors. Furthermore, when compression was used to reorient cleavage planes at the fourth division cycle, so that anterior cytoplasm was transmitted to more than the normal number of cells, those cells receiving a significant amount of such cytoplasm cleaved asymmetrically to produce supernumerary gonidial precursors. Together, these last two experiments indicate that blastomeres in the V. obversus embryo acquire (at least by the end of the third cleavage cycle) a polarized organization in which anterior cytoplasm plays a causal role in the process of reproductive-cell specification.     

Lineage-specific alteration in cell cycle structure in early Tubifex embryos

Embryos of the freshwater oligochaete Tubifex exhibit asynchrony in division timing as early as the second cleavage; this cleavage asynchrony becomes pronounced as development proceeds. The present study was undertaken to elucidate the composition and duration of the cell cycles of early Tubifex embryos, with special reference to their cell lineages. No significant variations in lengths of cleavage cycles were found among early embryos. In all blastomeres up to the eighth cleavage cycle, the M phase was followed directly by a 30 min S phase, which suggested that early embryos lack G1 phase. The durations of the M phase did not change during this period of development, but did differ between cell lines. The M phase in the A and B cell lines lasted for about 130 min, while the M phase in the C and D cell lines lasted for about 95 min. An examination of chromosome cycles showed that this difference in M phase durations resulted from a longer stay by the A/B cell lines in prometaphase. Only G2 phase lengthened during early development. After several rounds of G2 phase extension, three classes of G2 phase duration were established: the most extended G2 phase (∼6 h) in the first quartette of micromeres (cells 1 a–1 d), the shortest G2 phase (∼1.58 h) in teloblasts, and an intermediate G2 phase (∼2.4 h) in the progeny of macromeres (i.e. endodermal cells). Experiments with syncytial blastomeres showed that the timing of entry into the M phase, hence the duration of the G2 phase, was affected by cytoplasmic compositions. The shortest G2 phase correlated closely with the presence of yolk-free cytoplasm called pole plasm.     

The maternal‐to‐zygotic transition: An asynchronous split

The early cell cycles of preimplantation embryo development are unique in the scheme of mitotic cell proliferation as cell division is not coupled to cell growth, leading to a halving of blastomere volume with each cleavage event. Among the early mouse embryonic divisions, the fi rst two are particularly different, lasting almost twice as long as subsequent divisions. The third cell cycle is marked by the transition of a four‐cell embryo into an eight‐cell embryo, and represents the fi rst complete cell cycle occurring after activation of the zygotic genome. The G2/M phase of the third cell cycle is highly variable, lasting between 2–5 hours, and heterogeneity between blastomeres within the same embryo may occur as a part of normal development. The embryo in this image is actively undergoing cleavage from the four‐ to the eight‐cell stage, and blastomeres are captured in multiple phases of the cell cycle, as visualized by chromatin structure (DNA, blue) and microtubule staining (α‐tubulin, green). Two blastomeres sit in interphase with decondensed chromatin masses and a mesh‐like microtubule network, while the remaining blastomeres are actively undergoing mitosis. Of the latter, one is in metaphase, one in early anaphase, and the last in late anaphase. All together, the diversity in cell cycle stages reveals the inherit asynchrony existent within individual blastomeres of a cleavage stage embryo. Mol. Reprod. Dev. 80: 1–1, 2012. © 2012 Wiley Periodicals, Inc.     

Patterns of expression of cyclins A, B1, D, E and cdk 2 in preimplantation mouse embryos

Cell cycle regulatory proteins have been characterized in somatic cells and exhibit phase-specific expression patterns. Changes in expression of these regulatory proteins have not been clearly characterized in early preimplantation mouse embryos. This study utilized indirect immunofluorescence to determine the expression pattern of G1/S phase cyclins D and E; S, G2/M phase cyclins A and B1, and cdk 2 during the first three cell cycles of mouse embryo development. Cyclin D demonstrated low expression throughout the first cell cycle but had a somatic-like pattern of expression in cycles 2 and 3 with peak expression at G1 declining through S phase to a low during G2. Cyclin E was present at peak levels in G1 declining through S to a low in G2 during both the first and third cell cycles, but remained at moderate levels during the entire second cell cycle. Cyclin A was maintained at moderate levels throughout the first two cell cycles but showed a somatic-like pattern with a low level in G1 increasing during S phase with peak levels during G2 of the third cell cycle. Cyclin B consistently demonstrated a pattern opposite to a somatic G2/M cyclin, with peak levels in G1 declining through S phase to a low in G2 during each of the three cell cycles examined. Cdk 2 was present at consistent levels during G1 and S phases of all three cell cycles declining slightly in G2.     

The effect of cell cycle on GFPuv gene expression in the baculovirus expression system.

The effects of cell cycle on recombinant protein production and infection yield in the baculovirus-insect cell expression system (BES) were investigated. When, at any cell cycle phase, the host cell was infected by baculovirus, the cell cycle was finally arrested at the S or G(2)/M phase with 4n DNA. In the case of G(1) or S phase-infection, cell cycle of virus-infected cells began to be arrested at S phase from 8 h post-infection or at G(2)/M phase from 4 h post-infection, respectively; while, in the case of M phase-infection, cell cycle was arrested at S phase after 12 h post-infection. When the host cell was infected at the G(1) phase, average intracellular GFPuv fluorescence intensity was 1.3-fold higher than that at G(2)/M phase at 24 h post-infection. The GFPuv expression corresponded to the profile of the G(1) cell cycle in the BES. Infection yield was measured by detection of intracellular DNA binding protein using immunohistochemical method within 7 h post-infection. The infection yield at G(1) or S phase-infection was 1.5-1.8-fold higher than that at G(2)/M phase-infection.     

The durations and compositions of cell cycles in embryos of the leech, Helobdella triserialis

When tritiated thymidine triphosphate ([(3)H]TTP) or its immunohistochemically detectable analogue, bromodeoxyuridine triphosphate (BrdUTP), is injected into blastomeres of leech embryos it passes throughout the entire embryo and is rapidly incorporated (within 2 min after injection) into nuclei of cells synthesizing DNA (S phase). In the same embryos a DNA-specific stain can be used to identify cells in mitosis (M phase) or nonreplicative interphase (G(1) or G(2) phase) on the basis of nuclear or chromosomal morphology. Using this procedure, we have determined the lengths and compositions of the mitotic cell cycles of identifiable cells in early embryos of the leech, Helobdella triserialis, and have analysed how the cell cycles change during the first seven stages of development. The relatively short cell cycles of the early blastomeres comprise not only phases of M and S, but also postreplicative gap (G(2)) phases. The lengthening of the cell cycles that occurs as development progresses is primarily accomplished by an increase in the length of G(2) and secondarily by an increase in the length of S and,in some instances, the addition of a prereplicative gap(G(1)) phase; M phase remains relatively constant. These data suggest that the durations of the cell cycles of embryonic cells are regulated by a variety of mechanisms.     

Cell kinetics in the mouse esophageal epithelium in relation to the time of day

The kinetics of mouse esophageal epithelial cells was investigated throughout 90 h after a single injection of 3H-thymidine at 01 or at 13 h--the times of the peak and minimal magnitudes of the radioisotope index in the circadian rhythm of proliferation. The mitotic cycle parameters in the cells varied but insignificantly. For cells treated with 3H-thymidine at 01 h, T = 24.3 h, ts = 6 h, tG2 min = 1.5 h, tG2+ 1/2 M = 2.9 h and tG1+/2 M = 15.4 h; for those treated with 3H-thymidine at 13 h, T = 25.6 h, ts = 8.4 h, tG2 min = 1 h, tG2+ 1/2 M = 2.2 h, tG1+ 1/2 M = 15 h. Cells labeled at 01 h proliferated more actively for a long period of time as compared to those labeled at 13 h. The synchronism in undergoing several successive mitotic cycles was greater for cells labeled at the peak radioisotope index. The data obtained also suggest that the majority of cells enter the G0 phase after the completion of the first cycle. The duration of the G0 phase varies in different cell populations.     

The lack of correlation between the rate of rRNA transport from nucleoli into cytoplasm and the duration of G1 and G2 phases in root meristem cells

In root meristems of 3 species (Secale cereale L., Vicia faba L. subsp. minor, Allium cepa L.) the durations of cell cycles and their phases were calculated using 3H-thymidine labelling. In the above species and in Helianthus annuus L. (parameters of the cell cycle determined earlier) the G1 and G2 phase durations were different: G1 + 1/2 M from 3 h to 6.1 h, G2 + 1/2 M from 1.1. h to 8.3 h, depending on the species. The rate of rRNA transport from nucleoli into cytoplasm during recovery after cold treatment was calculated from our data presented earlier. The results indicate that in 4 species studied there is no correlation (at P = 0.05) between the rate of rRNA transport and the duration of G1 and G2 phases.     

Effects of 1,25-dihydroxyvitamin D3 on cell-cycle kinetics of T 47D human breast cancer cells

The replication of several human and animal cancer cell lines is regulated in vitro and in vivo by 1,25-dihydroxyvitamin D3 [1,25-(OH)2D3], the hormonally active form of vitamin D3. We have examined the effects of concentrations of 1,25-(OH)2D3, which inhibit cellular replication, on the cell-cycle kinetics of a 1,25-(OH)2D3-responsive human breast cancer cell line, T 47D. After 6 or 7 days of treatment, a time period representing approximately five cell population doublings of control cultures, concentrations of 1,25-(OH)2D3 in the range 10(-9) M to 10(-6) M caused a time- and concentration-dependent decrease in cell numbers. Treatment of cells growing in charcoal-treated fetal calf serum with 10(-8) M 1,25-(OH)2D3 for 6 days reduced cell numbers to 49% +/- 9% (n = 9) of control, and this was associated with a marked increase in the proportion of cells in the G2 + M phase of the cell cycle from 9.7% +/- 0.5% (n = 11) to 19.6% +/- 2.3% (n = 9), significant by paired analysis (P less than 0.002). At higher concentrations of 1,25-(OH)2D3 (10(-7)-10(-6) M), there was a concentration-dependent decline in S phase and increases in both G0/G1 and G2 + M phase cells. Detailed analysis of the temporal changes in cell-cycle phase distribution following treatment with 2.5 X 10(-8) and 10(-7) M 1,25-(OH)2D3 showed an initial accumulation of cells in G0/G1 and depletion of S phase cells during the first 24 hr of treatment. This decline in S phase cells was not accompanied by a decline in % G2 + M indicating a transition delay in G2 or mitosis. At the lower dose these changes returned to control values at 48 hr and at later times were associated with a slight but consistent decline in G0/G1 phase and an increase in G2 + M. In contrast cells treated with 10(-7) M 1,25-(OH)2D3 had significantly elevated % G0/G1 cells at days 2 and 3, consistent with a transition delay through G1 phase. This was confirmed in stathmokinetic experiments which demonstrated an approximate sevenfold decrease in the rate of exit of cells from G0/G1 following 4 days of exposure to 10(-7) M 1,25-(OH)2D3. This accumulation of cells in G0/G1 was accompanied by a fall in % S phase cells.(ABSTRACT TRUNCATED AT 400 WORDS)     

Cell-stage dependence of mutagen-induced sister-chromatid exchanges in human lymphocyte cultures

The induction of sister-chromatid exchanges (SCEs) was studied in phytohemagglutinin (PHA)-stimulated human lymphocytes exposed for 1 h to mitomycin C (MMC, 3 X 10(-6) M), ethyl methanesulphonate (EMS, 2 X 10(-2) M), or 4-nitroquinoline-1-oxide (4NQO, 3 X 10(-5) M) at various cell-cycle stages of 72-h cultures. The doses of the chemical were chosen to give about 20 SCEs per cell when treated at Go. The SCE frequency increased almost linearly with MMC or EMS treatments at later times after PHA stimulation, peaking with those at 36 h (at around the first G1/S boundary in the 2 consecutive cell cycles, which was revealed by concomitant experiments), and then decreased with subsequent treatment times. Cell-cycle kinetics and the cell stages at which the cells were treated were measured by autoradiography and sister-chromatid differential staining. The data show that MMC and EMS produce larger numbers of SCEs when treated at stages closer to the beginning of S, and that the most efficient time of treatment is the G1/S boundary in the first cell cycle of the two consecutive cycles before sampling. Pulse treatment with EMS caused about 3 times larger inductions of SCEs when done at late G1/early S(G1/S boundary) in the first cell cycle compared to that at G0/early G1, whereas identical exposure to MMC at the first G1/S boundary produced only 1.5 times larger numbers of SCEs than that at G0/early G1. EMS and MMC both, however, induced 30-40% larger numbers of SCEs when treated at the G1/S boundary in the first cell cycle than when treated at the second cell cycle before sampling. On the contrary, treatment with 4NQO led to the induction of about the same numbers of SCEs even when treated at different cell-cycle stages before the second G1/S boundary. The SCE frequency in 4NQO-treated cells then decreased with subsequent treatment times.     

Functional gap junctions in the early sea urchin embryo are localized to the vegetal pole.

Using the whole-cell voltage-clamp technique we have studied electrical coupling and dye coupling between pairs of blastomeres in 16- to 128-cell-stage sea urchin embryos. Electrical coupling was established between macromeres and micromeres at the 16-cell stage with a junctional conductance (G(j)) of 26 nS that decreased to 12 nS before the next cleavage division. G(j) between descendants of macromeres and micromeres was 12 nS falling to 8 nS in the latter half of the cell cycle. Intercellular current intensity was independent of transjunctional voltage, nondirectional, and sensitive to 1-octanol and therefore appears to be gated through gap junction channels. There was no significant coupling between other pairs of blastomeres. Lucifer yellow did not spread between these electrically coupled cell pairs and in fact significant dye coupling between nonsister cells was observed only at the 128-cell stage. Since 1-octanol inhibited electrical communication between blastomeres at the 16- to 64-cell stage and also induced defects in formation of the archenteron, it is possible that gap junctions play a role in embryonic induction.     

Effect of embryonic cell cycle of nuclear donor embryos on the efficiency of nuclear transfer in Japanese black cattle

In the present study, the development in vitro and in vivo of nuclear transfer (NT) embryos reconstructed with embryonic cells (blastomeres) at the 32- to 63-cell (sixth cell cycle) and 64- to 127-cell (seventh cell cycle) stages was investigated to determine the optimum range of embryonic cell cycles for yielding the highest number of identical calves in Japanese black cattle. Rates of development to the blastocyst stage (overall efficiency) were higher in the sixth cell-cycle stage (45%) than in the seventh cell-cycle stage (12%). After the transfer of the blastocysts reconstructed with blastomeres of the sixth and seventh cell cycle-stage embryos to recipient heifers, there were no differences in the pregnancy (14/35: 40% versus 3/13: 23%, respectively) or calving rates (11/39: 28% versus 3/13: 23%, respectively). These results indicate that the highest number of identical calves would be obtained by using sixth cell cycle (32- to 63-cell)-stage embryos as nuclear donors.