Radiosensitivity variation during the cell cycle in pronuclear mouse embryos in vitro

Abstract. The radiosensitivity of pronuclear mouse (B6D2 F1 x ICR) embryos has been measured in vitro as a function of time during the cell cycle. This was done by measuring the dose of X-rays (LD50) required to prevent development of 50% of the pronuclear embryos to the blastocyst stage in 5 days of culture. The LD50 was found to vary from 1 to 2 Gy during the period from G1 to the first cleavage. The cell cycle in the pronuclear embryo was analysed by [³H]thymidine autoradiography. Compared with earlier studies on two-cell mouse embryo radiosensitivity, the pronuclear embryos appear to be more sensitive to radiation than the two-cell embryos. If, however, one considers the radiation sensitivity on a blastomere basis, the pronuclear embryos are not different in their radiation sensitivity from the two-cell embryos. Thus, during the early cleavage stages of mice, radiosensitivity is mainly governed by the content of cells of various cell cycle ages in the embryo.     

Protein synthesis during the cell cycle of L5178Y cells

There are two peaks of ³H-leucine incorporation in the cell cycle of L5178Y cells. The first, during S stage, corresponds to a peak of ³H-leucine incorporation into the nuclear fraction. The second, during S or early G2, corresponds to a peak of ³H-leucine incorporation into the mitochondrial fraction. The rate of protein synthesis is unique for the proteins from each of the four fractions, nuclear, mitochondrial, microsomal, and soluble.The SDS polyacrylamide-gel electrophoretic patterns of ³H-leucine incorporation were different among three subcellular fractions: nuclear, mitochondrial, and microsomal + soluble. However, the incorporation pattern for each fraction remains qualitatively the same throughout the cell cycle.     

Centrioles in the cell cycle of L cells

The structure of centrosome in non-synchronous L-cells culture during the cell cycle has been studied. In mitosis, mother and daughter centrioles, which differ in their ultrastructure, are located perpendicularly in the pole of the spindle. Microtubules, meeting in the pole area terminate mainly in electron-dense clottings of fibrillar matter surrounding the diplosoma. In telophase, disjunction of mother and daughter centrioles begins. At the beginning of G1-period, centrioles move off from each other for several micron, and then draw together again without forming diplosome. Pericentriolar satellites form on mother centriole of some cells at this time, they disappear at the beginning of S-period, replication of centrioles begins; daughter centrioles reach the size of mother centrioles in anaphase. During growth and maturation, centrioles in L-cells undergo structural changes similar to those described for SPEV cells (Vorob'ev, Chentsov, 1982). Several types of meeting points for microtubules exist in L-cells during the whole interphase: surface of centrioles per se, pericentriolar satellites, free foci.     

Changes in mouse MHC expression during the cell cycle of Con A-treated spleen cells

This study was directed at correlating the expression of class I MHC determinants with different segments of the cell cycle by using dual laser flow microfluorometry to measure levels of both DNA and cell surface H-2Kd or H-2Dd determinants for single cells. Con A-treated mouse spleen cells were identified as being in the G2/M or G0/G1 phases of the cell cycle on the basis of propidium iodide or Hoechst 33342 dye bound to DNA. Monoclonal anti-H-2 antibodies, indirectly fluoresceinated with goat anti-mouse IgG, were used to detect MHC determinants. The average level of both Kd and Dd determinants expressed by G2/M cells was about 1.6-fold higher than that expressed by G0/G1 cells. These observations indicate that the average-size G0/G1 and G2/M cells have the same apparent surface density of Kd and Dd determinants, insofar as we estimate that these cells differ in surface area by a factor of about 1.5. We also analyzed the expression of Kd and Dd determinants by measuring how they changed as a function of the intensity of forward light scatter from cells. For both G2/M and G0/G1 cells, changes in light scatter intensity were associated with parallel changes in levels of Dd and Kd determinants, indicating a common mechanism(s) that controls their cell surface expression.     

Changes in protein content per cell during growth of mouse L cells

The relationship between cell density and protein content per cell was examined in monolayer and suspension cultures of mouse L cells. In monolayer cultures, the protein content per cell reached a maximum at 6 h after plating and retained this level for 18 h. Thereafter, the protein content per cell declined gradually during the exponential growth phase and finally returned to the initial level at the stationary phase. The changes were neither due to the effect of trypsinization nor to the exhaustion of the medium. The protein content per cell in a sparse culture was always greater than that in a dense culture for monolayer culture of L cells. In suspension culture the increase of protein content per cell during the lag phase was similar to that found in monolayer cultures. However, the gradual decline of protein content per cell observed during the exponential phase of monolayer cultures was not detected during that of a suspension culture. The results suggest that the decrease of protein content per cell in monolayer cultures may be related to some function of cell plasma membrane which could be inhibited by a cell-to-cell contact.     

Characteristics of the cell cycle of matrix cells in the mouse embryo during histogenesis of telencephalon

The cell cycle of matrix cells in the telencephalon of the mouse embryo at different stages at day 10, 13, and 17 of gestation was investigated by means of ³H-thymidine autoradiography.The cell cycle time of matrix cells in the day 10 group was found to be 7.0 h, and lengthened linearly with embryonic age. The cell cycle times of day 13 and 17 groups were 15.5 and 26.0 h, respectively.The duration of G1 and S phases also lengthened linearly with embryonic age. The durations of G1 phase were 0.1, 6.8, and 13.8 h, for day 10, 13, and 17 groups, respectively, and those of S phase were 5.1, 6.9, and 10.4 h, for day 10, 13, and 17 groups, respectively. On the other hand, the durations of both G2 and M phases remained unchanged and these were 1.0 and 0.8 h, respectively, throughout the embryonic stages.It was a characteristic of the alteration of the cell cycle of the telencephalon during mouse embryonic life that not only G1 but also S phases lengthened linearly with embryonic age and both G2 and M phases remained constant.     

Thymidine block does not synchronize L1210 mouse leukaemic cells: implications for cell cycle control, cell cycle analysis and whole-culture synchronization

Abstract.   It has been predicted that whole-culture methods of synchronization cannot synchronize cells. We have tested whether thymidine block, one type of whole-culture synchronization, can synchronize L1210 cells. We demonstrate experimentally that the thymidine block method cannot produce a synchronized culture. Although thymidine-treated cells are arrested primarily with an S-phase amount of DNA, there is no narrowing of the cell size distribution and there is no synchronized division pattern following release from the thymidine block. In contrast to a whole-culture synchronization method, cells produced by a selective (i.e. non-whole-culture) method not only have a specific DNA content, but also have a narrow size distribution and divide synchronously. Generalizing the results to other cell lines, we suggest that these conclusions call into question experimental measurements of gene expression during the division cycle based on thymidine inhibition synchronization.     

Expression of theta antigen on mouse thymocytes during the cell cycle

Summary Cells from normal mouse thymus were subdivided according to size and analysed for surface antigen expression, protein content and DNA expression and content. It could be shown, that the expression of theta-antigen followed protein accumulation in individual cells. Protein content on the other hand, was correlated with DNA synthesis even if it varied over a greater range.Only one subgroup of small non-DNA-synthesizing cells was calculated to have a higher density indicative of a more condensed state together with an increased surface antigen content. These cells might represent the G₀ state of the remnant proliferating population and most resembled the small cortical cells.     

The use of quantitative immunofluorescence to measure immunoglobulin levels in mouse myleoma cells during the cell cycle

The technique of quantitative immunofluorescence was applied to a study of immunoglobulin levels in mouse myeloma cells in different phases of the cell cycle.