兵豆萌发过程中初生根皮层细胞的细胞周期活动的动态分析

观察了兵豆 (LensculinarisMedic.)初生根原皮层组织的细胞周期在其种子萌发过程中时间和空间上的动态变化。免疫组织化学和细胞学证据表明 ,原皮层细胞分别在种子吸胀大约 13h和 17h开始DNA复制和细胞分裂。最早进行DNA复制和细胞分裂的细胞位于远基端 1mm附近 ,但这些分裂细胞的DNA复制是在种子成熟过程中完成的 ,而不是在萌发后。第一个细胞周期的激活样式表明 ,这些细胞并不同步激活 ,而是依次进入细胞周期 ,且进入的次序与自身在根尖中的相对位置有关。在兵豆初生根原皮层组织中 ,邻近位置上的细胞的细胞周期同步化程度较高。     

Effect of microgravity on the cell cycle in the lentil root

Characteristics of the cell cycle in cortical regions (0–0.6 mm from the root-cap junction) of the primary root of lentil (Lens culinaris L.) during germination in the vertical position on earth were determined by iododeoxyuridine labelling and image analysis. All cells were in the G1 phase at the beginning of germination and the duration of the first cell cycle was about 25 h. At 29 h, around 14% of the cortical nuclei were still in the G2 or M phases of the first cell cycle, whereas 53 and 33% of the nuclei were respectively in the G1 or S phase of the second cell cycle. In parallel, the cell cycle was analysed in root tips of lentil seedlings grown in space during the IML 2 mission (1994), (1) on the 1-g centrifuge for 29 h, (2) on the 1-g centrifuge for 25 h and placed in microgravity for 4 h, (3) in microgravity for 29 h, (4) in microgravity for 25 h and placed on the 1-g centrifuge for 4 h. The densitometric analysis of nuclear DNA content showed that in microgravity there were less cells in DNA synthesis and more cells in G1 than in the controls on the 1-g centrifuge (flight and ground). The comparison of the sample grown continuously on the 1-g centrifuge in space and of the sample grown first in 1-g and then in microgravity indicated that 4 h of microgravity modified cell cycle, increasing the percentage of cells in the G1 phase. On the contrary, the transfer from microgravity to the 1-g centrifuge (for 4 h) did not provoke any significant change in the distribution of the nuclear DNA content. Thus the effect of microgravity could not be reversed by a 4 h centrifugation. As the duration of the first cell cycle in the lentil root meristem is about 25 h, the results obtained are in agreement with the hypothesis that the first cell cycle and/or the second G1 phase was lengthened in absence of gravity. The difference observed in the distribution of the nuclear DNA content in the two controls could be due to the fact that the 1g control on board was subjected to a period of 15 min of microgravity for photography 25 h after the hydration of the seeds, which indicated an effect of short exposure to weightlessness. The mitotic index of cortical cells was greater on the 1-g centrifuge in space than in any other sample (flight and ground) which could show an effect of the centrifugation on the mitosis.     

Nitric oxide restrain root growth by DNA damage induced cell cycle arrest in Arabidopsis thaliana

Nitric oxide (NO) participates in the regulation of diverse functions in plant cells. However, different NO concentrations may trigger different pathways during the plant development. At basal levels of NO, plants utilize the NO signaling transduction pathway to facilitate plant growth and development, whereas higher concentrations trigger programmed cell death (PCD). Our results show that NO lower than the levels causing PCD, but higher than the basal levels induce DNA damage in root cells in Arabidopsis as witnessed by a reduction in root growth, rather than cell death, since cells retain the capacity to differentiate root hairs. The decrease in meristematic cells and increase in DNA damage signals in roots in responses to NO are in a dose dependent manner. The restraint of root growth is due to cell cycle arrest at G1 phase which is caused by NO induced DNA damage, besides a second arrest at G2/M existed in NO supersensitive mutant cue1. The results indicate that NO restrain root growth via DNA damage induced cell cycle arrest.     

Fibronectin promotes cell cycle entry in smooth muscle cells in primary culture

Smooth muscle cell proliferation after arterial injury is regulated by growth factors and components of the extracellular matrix. We have previously demonstrated that fibronectin promotes a phenotypic modulation of freshly isolated rat smooth muscle cells from a contractile to a synthetic phenotype in primary culture and supports the ability of the cells to respond to growth factors. Here, we analyzed if fibronectin promotes cell cycle entry in freshly isolated rat aortic smooth muscle cells during primary culture. Cell cycle analysis showed that cells seeded on fibronectin remained in the G(0)/G(1) phase of the cell cycle during the first 6 days of culture. During this period, there was an increased expression of cyclin D1 and p27(KIP1) in the absence of exogenous growth factors. Addition of serum was followed by enhanced cyclin D1 expression, decreased p27(KIP1) levels, hyperphosphorylation of Rb protein, induction of cyclin A and cyclin D3 expression, and cell cycle progression into S phase. The results indicate that fibronectin initiates cell cycle entry in freshly isolated smooth muscle cells by promoting the induction of cyclin D1 and thereby facilitates further cell cycle progression together with growth factors.     

Immunodetection of four mitotic cyclins and the Cdc2a protein kinase in the maize root: Their distribution in cell development and dedifferentiation

Summary Cyclin proteins and cyclin-dependent kinases play a key role in the regulation of cell division. We have therefore studied the relationship of the level of four mitotic cyclin proteins and the Cdc2a kinase protein to cell division in maize root tissue with respect to cessation of division as cells leave the primary meristem region, resumption of division in formation of lateral-root primordia, and induced division following wounding. All four mitotic cyclins and Cdc2a were most abundant in dividing cells. The only examined cell cycle protein which was restricted to dividing tissue was cyclin ZmCycB1;2 (previously ZmIb) and may thus be a limiting factor for cell division. All other cyclin proteins, i.e., ZmCycB1;1 (previously ZmIa), ZmCycA1;1 (previously ZmII), and ZmCycB2;1 (previously ZmIII), and the Cdc2a kinase declined shortly after cells had ceased division. The distance from the root tip at which cells ceased division was tissue-specific and reflected the distance at which decrease of cell cycle proteins was detected. Whereas cyclin ZmCycB1;2 rapidly declined to a hardly detectable level in either nucleus or cytoplasm, in the nuclei of nondividing cells there was persistence of Cdc2a and of cyclins ZmCycB1;1, ZmCycCA1;1, and ZmCycB2;1, indicating that there are plant cyclins which are tightly linked to cell division and others that persist, especially in the nuclei, in nondividing cells. The transition from division to differentiation may thus partly be triggered and enforced by the decrease of the cell cycle proteins and especially the decline of cyclins in the cytoplasm. In the resumption of cell division, both in lateral-root formation and in wound response, high nuclear and low cytoplasmic accumulation of cyclin ZmCycB2;1 was the first visible sign of cell dedifferentiation, implying a role for cyclin ZmCycB2;1 in the G₀–G₁ phase transition. Next, cytoplasmic accumulation of cyclin ZmCycA1;1, followed by a rearrangement of cortical microtubules, was observed and since both the cyclins ZmCycA1;1 and ZmCycB2;1 were found at places of high tubulin concentration, they may function in the microtubule rearrangement for cell division. When the nuclei of dedifferentiating cells had visibly enlarged, all cyclins and Cdc2a accumulated there, possibly contributing to DNA replication and preparation for mitosis. Later, presumably during G₂ phase, cytoplasmic accumulation was observed for Cdc2a at low levels, as observed in G₂ phase cells of the primary meristem, and for cyclins ZmCycB1;1 and ZmCycB1;2 accumulation was observed above the levels found in undisturbed meristems, suggesting special contributions to late dedifferentiation processes in both wound-induced and lateral meristems.Abbreviations CDK cyclin-dependent kinase - LRP lateral-root primordium - Mt microtubule - FITC fluorescein isothiocyanate - TRITC tetramethylrhodamine isothiocyanate Dedicated to Professor Walter Gustav Url on the occasion of his 70th birthday     

Cell cycle perturbation of cultured C6 glioma cells following short-term contact with a low dose of ACNU

The purpose of this study was to investigate the cell cycle perturbation of cultured C6 rat glioma cells induced by 1-(4-amino-2-methyl-5-pyrimidyl)methyl-3-(2-chloroethyl)3-nitrosourea hydrochloride (ACNU) using simultaneous flow cytometric measurements of DNA and bromodeoxyuridine (BrdU) content. A new graphic computer program permitted the quantification of cell density in hexagonal subareas and allowed the fraction of BrdU-labeled cells with mid-S phase DNA content (FLS) to be defined in a narrow window. The cell kinetic parameters such as cell cycle time (Tc) and S phase time (Ts) were estimated from a manually plotted FLS curve at 18 and 6 hr, respectively. The major effect of ACNU on the cell cycle was an accumulation of the cells in the G2M phase 12 to 24 hr posttreatment when compared to G2M traverse of untreated cells. For the two-dimensional analysis, cells were labeled with BrdU and then treated with ACNU, or treated with ACNU and then labeled with BrdU. It was concluded that the cells in the S and G2M phases at the time of ACNU administration progressed to mitosis but that the G1 phase cells accumulated in the subsequent G2M phase. Two-dimensional FCM analysis using BrdU provided a useful tool in studying cell cycle perturbation.     

Rhizobium nod factors reactivate the cell cycle during infection and nodule primordium formation, but the cycle is only completed in primordium formation.

Rhizobia induce the formation of root nodules on the roots of leguminous plants. In temperate legumes, nodule organogenesis starts with the induction of cell divisions in regions of the root inner cortex opposite protoxylem poles, resulting in the formation of nodule primordia. It has been postulated that the susceptibility of these inner cortical cells to Rhizobium nodulation (Nod) factors is conferred by an arrest at a specific stage of the cell cycle. Concomitantly with the formation of nodule primordia, cytoplasmic rearrangement occurs in the outer cortex. Radially aligned cytoplasmic strands form bridges, and these have been called preinfection threads. It has been proposed that the cytoplasmic bridges are related to phragmosomes. By studying the in situ expression of the cell cycle genes cyc2, H4, and cdc2 in pea and alfalfa root cortical cells after inoculation with Rhizobium or purified Nod factors, we show that the susceptibility of inner cortical cells to Rhizobium is not conferred by an arrest at the G2 phase and that the majority of the dividing cells are arrested at the G0/G1 phase. Furthermore, the outer cortical cells forming a preinfection thread enter the cell cycle although they do not divide.     

Water-relation parameters of epidermal and cortical cells in the primary root ofTriticum aestivum L.

Water-relation parameters of root hair cells, hairless epidermal cells, and cortical cells in the primary root of wheat have been measured using the pressure-probe technique. Under well-watered conditions the mean cell turgor of cortical cells was 6.8±1.9 (30) bar (mean±SD; the number of observations in brackets). In hairless epidermal and root hair cells the mean cell turgor was 5.5±1.9 (22) and 4.4±1.5 (15) bar, respectively. Despite the large variability, turgor pressure was significantly lower (confidence interval=0.95) in epidermal cells relative to cortical cells. This may be a consequence of the ultrafiltration of ions by the external cell wall and-or plasmalemma of epidermal cells. The volumetric elastic modulus of the cells ranged from 10 to 150 bar. This parameter was dependent on cell volume, but within experimental accuracy, was independent of cell type. No pressure dependence of the volumetric elastic modulus was observed in these cells. The half-times for water exchange ranged from 1.8 to 48.8 s. The mean value increased in the order root hair < hairless epidermal < cortical cells and was directly related to volume to surface area ratio. Thus the hydraulic conductivities of the three cell types were similar and averaged 1.2±0.9·10^-6 (170) cm s^-1 bar^-1. No polarity was observed between inwardly and outwardly directed water flow. The similarity of the hydraulic conductivities of root hairs to those of other cells indicates that the membranes of root hairs are not particularly specialized for water transport. The overall hydraulic conductivity for radial water flow across the root was estimated from the pressure-probe data using a simple model and was compared with that measured directly on whole roots using an osmotic backflow technique. It was tentatively concluded that upon sudden osmotic perturbation, the major pathway for water transfer across the root may be through the symplasm and involve net flow from vacuole to vacuole.     

Inhibition of growth of ASL-1w murine leukemia cells by anti-thymus leukemia antigen (TL) serum in the absence of complement.

Previous studies have shown that the cell surface expression of thymus leukemia antigen (TL) on ASL-1w leukemia cells varies with the progression of the cells through the growth cycle. Expression of TL is maximal in S phase, and its quantitative expression varies directly with DNA synthesis. In the present study, the effect of anti-TL serum on the growth of ASL-1w cells was examined. The antiserum, tested in the absence of complement, affected the growth of these cells in biphasic manner. When the antiserum concentration was 0.1% or greater, there was a rapid decline in the rate of DNA synthesis, and after 5 to 7 hr, cell death. When the antiserum concentration was 0.067% or less, the decline in the rate of synthesis of DNA did not become apparent until 5 to 6 hr after treatment. Under these conditions, there was approximately a 20% increase in cell number after 24 hr of culture. The hypothesis that treatment of ASL-1w cells with the lesser concentration of anti-TL serum blocks the cells in G2 phase of the cell cycle is discussed.     

A METHOD FOR COMPARING EFFECTS OF DIFFERENT SYNCHRONIZING PROTOCOLS ON MAMMALIAN CELL CYCLE TRAVERSE : The Traverse Perturbation Index

After treatment of Chinese hamster cells (line CHO) with various protocols for synchrony induction, the subsequent ability of cells to traverse the cell cycle (i e., to perform, an essential cell cycle process) has been determined by measurement of the DNA distribution pattern among cells in large populations with the Los Alamos flow microfluorometer In the cultures prepared by the various synchronizing techniques the vast majority of cells traversed the cell cycle in a normal fashion; however, in all cultures examined there remained small subpopulations which, though remaining viable for several days, could not carry out normal traverse. After reversible inhibition of DNA synthesis by means of a double-thymidine blockade, approximately 17% of the cells were unable to complete genome replication. After reversal of G₁ arrest resulting from cultivation of cells in isoleucine-deficient medium, 12 4% of the cells commenced synthesis of DNA but were unable to complete the S phase. Cells prepared by mitotic selection yielded a subpopulation (5 5% of the total cells) with a G₁ DNA content which remained viable but noncycling for at least 5 days. We propose a term "traverse perturbation index" which is defined as the fraction of cells converted to a noncycle-traversing state as the result of experimental manipulation. A knowledge of the perturbation index will allow direct comparison of effects on cell cycle traverse of various synchrony-induction protocols     

In vivo growth kinetics of P388 and L1210 leukemias

The P388 lymphocytic leukemia and the L1210 lymphoid leukemia are used as test systems for putative cytotoxic drugs. These leukemias are also used to investigate the perturbation of cell cycle progression of various chemical compounds in more detail. There is little information on the normal growth kinetics in vivo of these leukemias. In the present report we therefore present the results from growth kinetic studies of P388 and L1210 leukemic cells growing in ascites form in mice. We used 3H-TdR autoradiography, DNA flow cytometry and the stathmokinetic method. During exponential growth both leukemias showed a growth fraction of unity. Whereas no significant cell loss was observed during the early growth phase of P388 cells, cell loss was indicated by a discrepancy between potential and actual doubling times during exponential growth of L1210 cells. During the phase of growth retardation, the proportion of G1 and G2 cells increased at the expence of a reduced S phase fraction in the P388 leukemia, whereas only small changes in cell cycle distributions were seen with time after inoculation of L1210 cells. An increasing discrepancy in the reduction of the S phase fraction and the 3H-TdRLI was seen in the P388 cells with time after inoculation. Thus, a majority of P388 cells with S phase DNA content were unlabelled during the late phase of growth restriction, indicating resting cells in S phase. A good correlation was found between the 3H-TdR LI and S phase fraction throughout the life history of L1210 cells, revealing considerable differences in in vivo growth kinetics between the two leukemias. Such differences should be considered when evaluating test results.     

Isolation of mutants showing temperature-sensitive cell growth from embryonal carcinoma cells: control of stem cell differentiation by incubation temperatures

Embryonal carcinoma(EC) cells, the undifferentiated stem cells of teratocarcinomas, have many properties in common with pluripotent embryonic cells, and thus provide an excellent system for studying the early events involved in embryonic development and stem cell differentiation. We have isolated three novel mutants with temperature-sensitive(ts) cell growth that were able to differentiate at a non-permissive temperature for cell growth. These mutations affect the progression of the cell cycle, leading to the transient accumulation of cells in a specific phase, the S phase, of the cell cycle, which is likely to be the primary cause of stem cell differentiation of EC cells at non-permissive temperature. Isolation of these mutants strongly supports the notion that there is a close association between the inhibition of DNA synthesis and EC cell differentiation.     

Tetraploid cycle in ageing solid tumours

When the mouse mammary adenocarcinoma 755 (Ca-755) reaches the plateau phase of growth, non-cycling cells with a G2-DNA content can be observed. They may belong to the diploid cell cycle but they could also be blocked in G0 or G1 of a tetraploid cycle. This hypothesis was tested in three ways: (1) non-cycling G2 nuclei were stained with a combination of Feulgen and naphthol yellow which revealed two populations, one with a low protein content and the other with a high protein content--the latter may represent nuclei ready to begin a new phase of DNA synthesis; (2) Feulgen staining and autoradiography were performed after tritiated thymidine had been administered to mice continuously: this showed that there were cells synthesizing DNA with a DNA index above 2; and (3) cells having 80 chromosomes, corresponding to the tetraploid cycle, were found almost exclusively in the plateau phase tumours. On the other hand, the use of texture and DNA parameters of the Feulgen stained nuclei showed that they were concentrated in a diploid cycle for tumours in the exponential phase of growth and were divided between a diploid and tetraploid cycle for 'plateau' cells. Neither the cause for, nor the role played by, polyploid cells is known.     

Variation in growth rate between Arabidopsis ecotypes is correlated with cell division and A-type cyclin-dependent kinase activity

We used a kinematic analysis to investigate the growth processes responsible for variation in primary root growth between 18 ecotypes of Arabidopsis. Root elongation rate differed 4-fold between the slowest (Landsberg erecta, 71 microm h(-1)) and fastest growing line (Wassilewskija [Ws]; 338 microm h(-1)). This difference was contributed almost equally by variations in mature cortical cell length (84 microm [Landsberg erecta] to 237 microm [Ws]) and rate of cell production (0.63 cell h(-1) [NW108] to 1.83 cell h(-1) [Ws]). Cell production, in turn, was determined by variation in cell cycle duration (19 h [Tsu] to 48 h [NW108]) and, to a lesser extent, by differences in the number of dividing cells (32 [Weiningen] to 61 [Ws]). We found no correlation between mature cell size and endoreduplication, refuting the hypothesis that the two are linked. However, there was a strong correlation between cell production rates and the activity of the cyclin-dependent kinase (CDKA). The level of the protein could explain 32% of the variation in CDKA. Therefore, it is likely that regulators of CDKA, such as cyclins and inhibitors, are also involved. These data provide a functional link between cell cycle regulation and whole-plant growth rate as affected by genetic differences.     

Cell density downregulates DNA synthesis and proliferation during osteogenesis in vitro

Abstract. The classical models of in vitro cell culture comprise fibroblasts and epithelial cells. Osteogenic cells represent another interesting cell model; however, it is not known whether during osteogenesis cell density regulates cell growth as seen in cultures of fibroblasts and epithelial cells. We selected MC3T3-E1 cells for study because they are an osteogenic cell line that, when subcultured, grow to confluence and form multilayers of cells in conventional cultures by continued proliferation, as do fibroblasts. Once maximum cell density is obtained, proliferation is down regulated resulting in a mixed population of quiescent and dividing cells. We used this model to determine whether downregulation of proliferation as expressed by cell number and DNA synthesis is cell density-dependent. MC3T3-E1 cells were cultured over a period of 34 days to determine their kinetics, viability, ability to synthesize DNA, distribution within phases of the cell cycle and cell number-response relationships. Our results show that (1) viability ranged between 92% and 96% and the cell number 2.5 x 10⁵ per cm² once cultures reached steady state, (2) most cells entered the G₀/G₁ phase of the cell cycle on day 7, (3) there was no correlation between the proportion of cells in S phase and downregulation of DNA synthesis, (4) a direct relationship exists between cell density and downregulation of DNA synthesis on day 8, (5) the minimum time for cells to be cultured before downregulation of DNA synthesis begins is independent of cell number, and (6) downregulation of DNA synthesis is reversible. These results suggest that density-dependent downregulation of DNA synthesis may be a mechanism of growth control for osteogenic cells in vitro that operates more like density-dependent growth control in cultures of fibroblasts rather than epithelial cells.     

Tetraploid cycle in ageing solid tumours

Abstract. When the mouse mammary adenocarcinoma 755 (Ca-755) reaches the plateau phase of growth, non-cycling cells with a G₂-DNA content can be observed. They may belong to the diploid cell cycle but they could also be blocked in G₀ or G₁ of a tetraploid cycle. This hypothesis was tested in three ways: (1) non-cycling G₂ nuclei were stained with a combination of Feulgen and naphthol yellow which revealed two populations, one with a low protein content and the other with a high protein content– the latter may represent nuclei ready to begin a new phase of DNA synthesis; (2) Feulgen staining and autoradiography were performed after tritiated thymidine had been administered to mice continuously: this showed that there were cells synthesizing DNA with a DNA index above 2; and (3) cells having 80 chromosomes, corresponding to the tetraploid cycle, were found almost exclusively in the plateau phase tumours.
On the other hand, the use of texture and DNA parameters of the Feulgen stained nuclei showed that they were concentrated in a diploid cycle for tumours in the exponential phase of growth and were divided between a diploid and tetraploid cycle for 'plateau' cells. Neither the cause for, nor the role played by, polyploid cells is known.     

Dynamics of growth,proliferation and differentiation of wheat root cells exposed to a high nickel concentration

The dynamics of root growth, proliferation of initial cells of the root cap, rhizodermis, and central metaxylem, as well as structural changes in the cells induced by a 72-h exposure to a high (0.1 mM) concentration of NiSO₄ were studied in 3-day-old wheat (Triticum aestivum L.) seedlings. In the roots of control plants, we observed a 12-h rhythm of changes in the length of the cells that completed elongating. Upon the treatment with nickel, this effect was negated, and a considerable reduction in the root length increment was observed in 12 h. In 24 h, root growth essentially ceased. Cell elongation was suppressed acropetally, and the cells, whose elongation was over, became shorter. In the meristem and apical part of the elongation zone, slow cell growth continued during the second and even third days. Autoradiography showed that the earliest effect of nickel on the processes of root morphogenesis observed in 6 h was a suppression of cell transition to DNA synthesis. The cells, where DNA synthesis has already started or which were in other stages of the cycle, continued to pass slowly through the cycle and completed it. Sister cells formed as a result of division subsequently left the cycle in the phase G1 and transited to dormancy. It was found that the main mechanism of cell proliferation cessation was the suppression of cell transition to DNA synthesis. In the cells elongating when exposed to nickel, tissue-specific changes in the nucleus structure were observed (chromatolysis in the rhizodermis and cortex, pycnosis in the endodermis, a disturbance of the nucleus structure in the central metaxylem). These disorders were only observed after cessation of elongation. Root incubation in 0.1 mM nickel solution did not affect the onset of cell differentiation in the xylem and metaphloem and shifted its beginning to the root tip. However, in 24 h the initiation and growth of root hairs were suppressed. It was concluded that tissue-specific nickel-induced changes in the nucleus structure in the elongating cells do not cause the cessation of root growth, although point to nickel toxic effect on the cells in the course of elongation.     

Spontaneous mutation of leu2 in Saccharomyces cerevisiae

The data obtained indicate that spontaneous mutations in Saccharomyces cerevisiae are formed during DNA replication. With no DNA replication in the lag-period, in the stationary growth phase, spontaneous mutations are not formed in cell culture during the G1 phase of cell cycle. Experimental data show the absence of primary spontaneously occurring DNA lesion accumulation in the cell G1 phase. Spontaneous mutations of yeasts are formed in the S phase of cell cycle, apparently as DNA replication errors. It is established that the frequency of spontaneous reversions of the leu2 gene in Saccharomyces cerevisiae strain NA3-24 increases when the cells are cultivated on the culture medium with different concentrations of leucine.     

Cadmium cytotoxicity and variation in nuclear content of DNA in Euglena gracilis

Cultures of Euglena gracilis (strain Z from French CNRS collection) can be made cadmium resistant if grown in a medium with 5x10^-4M cadmium chloride. This resistance is reflected by the appearance of a second exponential growth phase. The development of this resistance was studied at the cellular level by determining the relative content of DNA at different stages of the cell cycle in an asynchronously grown culture. The culture was followed until the second, cadmium resistant, growth phase had reached its stationary state. During the first exponential growth phase, cells were mostly in the late period of DNA synthesis (stage S of the cell cycle), or in the gap preceding mitosis (stage G₂ of the cell cycle). In addition, some cells contained high multiples of the normal amount of DNA. In the beginning of the second exponential growth phase, a few cells were again in G₁ (the post mitotic stage of the cell cycle preceding DNA synthesis). These G₁ cells were predominant at the end of the second growth period. During the second stationary phase the DNA content of the cadmium treated cells was similar to the stationary phase of the control culture. Cells had stopped growing in G₁ with an unreplicated genome. The implications of these data are discussed.