Correlation of 24-hour fluctuations in renin granules of juxtaglomerular cells and in renin and angiotensinogen in blood plasma of the rat

Summary Subcellular structures of juxtaglomerular (JG) cells in the rat kidney were morphometrically examined at six evenly spaced times over 24 h. Plasma renin activities and angiotensinogen concentrations were also measured at these times. The cell volumes were larger at 20.00 h and 04.00 h than at 00.00 h, whereas the nuclear volumes peaked at 20.00 h and 08.00 h, decreasing at 00.00 h and 16.00 h. The volume and surface densities of renin granules and their individual volumes and surface areas peaked at 16.00 h and 00.00 h, decreasing at 20.00 h and 08.00 h, whereas their numerical densities peaked at 20.00 h, decreasing at 12.00 h. The surface densities of the rough endoplasmic reticulum (rER) peaked at 20.00 h, decreasing at other times, except at 08.00 h, when rER volume and surface density were relatively high. The plasma renin activity was maximal at 20.00 h, whereas it was minimal at 08.00 h. The variation in plasma angiotensinogen concentrations was inversely correlated with that in plasma renin activities. These results suggest that JG cells actively synthesize and release renin during the dark period, especially at 20.00 h, whereas during the light period they gradually synthesize renin and produce the granules, most of which may be stored in the cells during this period.     

Different epidermal cell kinetic effects of hydroxyurea when injected at two different times of the day

Circadian rhythms in epidermal basal cell-cycle progression in hairless mouse skin have been repeatedly demonstrated. A dose of 10 mg/animal hydroxyurea (HU), given to inhibit DNA synthesis was injected intraperitoneally to two groups of hairless mice. One group was injected at 10.00 hours MET, when the cell-cycle progression and cell division rate are relatively high, and another group was injected at 20.00 hours, when the same variables are at minimum values. Various cell kinetic methods--[3H]TdR autoradiography, DNA flow cytometry and the stathmokinetic method (Colcemid)--were used to study HU-induced alterations in cell kinetics. Hydroxyurea (HU) immediately reduced the labelling index (LI) to less than 10% of controls when injected at both times of the day, and higher then normal values were observed 8 hr later. A subsequent decrease towards normal values was steeper in the 20.00 hours injected group. The proportion of cells with S-phase DNA content was transiently reduced in both series, but the reduction was less pronounced and control values were reached earlier in the series injected at 10.00 hours. The observed alterations in LI and fraction of cells in S phase were followed by comparable alterations in the fraction of cells in G2 and in the mitotic rate. Hence the changes in G2 and mitotic rate are easily explained as consequences of the previous perturbations in the S phase. The time-dependent differences in the cell kinetic perturbations caused by HU in the S phase may be explained by a circadian-phase-dependent action of HU on the influx and efflux of cells to and from the S phase, respectively. At 10.00 hours the efflux of cells from S is most heavily inhibited; at 20.00 hours the influx is predominantly blocked. Hence, when physiological flux is high HU mainly blocks the efflux from S, but when flux normally is low, HU mainly blocks the entrance to S. Within 20 hours after the HU injection, the cell kinetic variables had approached the unperturbed circadian pattern.     

Effects of pulse labelling with tritiated thymidine on the circadian rhythmicity in epidermal cell-cycle distribution in mice

The influence of pulse labelling with 50 microCi tritiated thymidine ( [3H]TdR) (2 microCi/g) on epidermal cell-cycle distribution in mice was investigated. Animals were injected intraperitoneally with the radioactive tracer or with saline at 08.00 hours, and groups of animals were sacrificed at intervals during the following 32 hr. Epidermal basal cells were isolated from the back skin of the animals and prepared for DNA flow cytometry, and the proportions of cells in the S and G2 phases of the cell cycle were estimated from the obtained DNA frequency distributions. The proportions of mitoses among basal cells were determined in histological sections from the same animals, as were the numbers of [3H]TdR-labelled cells per microscopic field by means of autoradiography. The results showed that the [3H]TdR activity did not affect the pattern of circadian rhythms in the proportions of cells in S, G2 and M phase during the first 32 hr after the injection. The number of labelled cells per vision field was approximately doubled between 8 and 12 hr after tracer injection, indicating an unperturbed cell-cycle progression of the labelled cohort. In agreement with previous reports, an increase in the mitotic index was seen during the first 2 hr. These data are in agreement with the assumption that 50 microCi [3H]TdR given as a pulse does not perturb cell-cycle progression in mouse epidermis in a way that invalidates percentage labelled mitosis (PLM) and double-labelling experiments.     

DNA synthesis rate changes during the S phase in mouse epidermis

The in vivo DNA synthesis rate throughout the S phase of mouse epidermal cells was investigated. Epidermal basal cells were isolated at various times of the day from normal animals injected with [3H]TdR 30 min before sacrifice, and from pulse-labelled animals with regenerating and growth-inhibited epidermis. The cells were analysed by DNA flow cytometry combined with cell sorting. Cells from successive fractions of the S phase were sorted on glass slides and subjected to quantitative [3H]TdR autoradiography. The results confirmed the presence of unlabelled (slowly replicating) cells in the S phase, the proportion of which was circadian stage-dependent with minimum values at midnight and in the early morning. The DNA synthesis rate throughout the S phase showed a general trend with high values in the mid-fractions, a pattern which was similar in normal and in growth perturbed epidermis. In the early morning the DNA synthesis rate pattern was bimodal with maxima both in the first and second half of the S phase, with a corresponding trough in mid-S. At this time of day the cell progression rate through S is at its maximum, indicating a relationship between the overall DNA synthesis rate and the rate distribution pattern through S.     

A strong genotoxic effect in mouse skin of a single painting of coal tar in hairless mice and in MutaMouse

The dorsal skin of C3H/Tif/hr hairless mice was painted with coal tar, pharmacological grade. Epidermal cells and hepatocytes were isolated after 4, 24, 48 and 96 h and DNA strand breaks were determined as tail moment by the alkaline comet assay. The tail moment of epidermal cells was significantly greater at the time points 4, 24, 48 and 96 h after exposure compared to the controls, with the most DNA strand breaks at 24 h. The DNA strand breaks in epidermal cells increased linearly with the dose of coal tar. In hepatocytes, no difference in DNA strand breaks was found between exposed animals and controls. DNA adducts were determined by the 32P-postlabeling assay. For epidermal cells, the mean DNA adduct level was 12-fold greater in coal tar painted mice after 24 h than in controls. Again, a linear dose/response relationship was seen 24 h after painting. For liver DNA, the mean DNA adduct level was 3-fold greater than for controls. The mutation frequency in epidermal and liver cells was examined in lambdalacZ transgenic mice (MutaMouse). Thirty-two days after painting, the mutation frequency in epidermal cells was 16-fold greater in coal tar treated mice compared to controls. No effect was detected in hepatocytes. We found that a single painting of coal tar resulted in strong genotoxic effects in the murine epidermis, evidenced by induction of DNA strand breaks and DNA adducts in hairless mice and lambdalacZ mutations in the MutaMouse. This demonstrates that it is possible to detect genotoxic effects of mixtures with high sensitivity in mouse skin by these end-points.     

A relationship between nuclear DNA and RNA synthetic activities and the changes produced by n-methyl-n-nitroso urethane: A study using Amoeba proteus as a single cell model

Changes caused by a carcinogen generally vary from one cell to another even among similar types of cells. The following work investigates the degree to which damage (inhibition of division, lethality, or inherited cellular changes) caused by N-methyl-N-nitroso urethane (MNU) alters at different times during the cell cycle, and relates fluctuations in the sensitivity of cells to changes in their DNA and RNA synthetic activities—possibly in the configuration of their DNA—at the time of treatment.Studies on amoebae exposed to MNU for short periods at 50 different times in their cell cycle led to the following conclusions: amoebae are sensitive to MNU at all ages, but the dose needed to produce lethal damage to young and old cells varies by a factor of 3. Cells are most sensitive at the time of division and during the peak of DNA synthesis. Smaller changes are found during the G₂ phase, some of which occur at times of intensive RNA synthesis. Transfer of nuclei between treated and control cells proved that the changing sensitivity of the cells, as shown by both inherited changes and lethal damage, was dependent on changes in their nuclei. Though the cytoplasm could be affected directly by MNU, i.e. in the absence of a nucleus, supralethal doses 2–6 times whole cell dose were required to either kill the cell or to cause a recognizable change in the offspring of viable cells. Experiments with cells having altered nuclear/cytoplasmic ratios showed that the relative insensitivity of older cells was not due to the increased volume of their cytoplasm. However, a possible involvement of cytoplasm in the repair of nuclear damage is suggested by the ability of control cytoplasm to alleviate some nuclear damage, particularly in S phase cells.     

Mathematical model analysis of mouse epidermal cell kinetics measured by bivariate DNA/anti-bromodeoxyuridine flow cytometry and continuous [3H]-thymidine labelling

In a previous study the epidermal cell kinetics of hairless mice were investigated with bivariate DNA/anti-bromodeoxyuridine (BrdU) flow cytometry of isolated basal cells after BrdU pulse labelling. The results confirmed our previous observations of two kinetically distinct sub-populations in the G2 phase. However, the results also showed that almost all BrdU-positive cells had left S phase 6-12 h after pulse labelling, contradicting our previous assumption of a distinct, slowly cycling, major sub-population in S phase. The latter study was based on an experiment combining continuous tritiated thymidine [( 3H]TdR) labelling and cell sorting. The purpose of the present study was to use a mathematical model to analyse epidermal cell kinetics by simulating bivariate DNA/BrdU data in order to get more details about the kinetic organization and cell cycle parameter values. We also wanted to re-evaluate our assumption of slowly cycling cells in S phase. The mathematical model shows a good fit to the experimental BrdU data initiated either at 08.00 hours or 20.00 hours. Simultaneously, it was also possible to obtain a good fit to our previous continuous labelling data without including a sub-population of slowly cycling cells in S phase. This was achieved by improving the way in which the continuous [3H]TdR labelling was simulated. The presence of two distinct subpopulations in G2 phase was confirmed and a similar kinetic organization with rapidly and slowly cycling cells in G1 phase is suggested. The sizes of the slowly cycling fractions in G1 and G2 showed the same distinct circadian dependency. The model analysis indicates that a small fraction of BrdU labelled cells (3-5%) was arrested in G2 phase due to BrdU toxicity. This is insignificant compared with the total number of labelled cells and has a negligible effect on the average cell cycle data. However, it comprises 1/3 to 1/2 of the BrdU positive G2 cells after the pulse labelled cells have been distributed among the cell cycle compartments.     

Dna Synthesis Rate Changes During the S Phase In Mouse Epidermis

The in vivo DNA synthesis rate throughout the S phase of mouse epidermal cells was investigated. Epidermal basal cells were isolated at various times of the day from normal animals injected with [³H]TdR 30 min before sacrifice, and from pulse-labelled animals with regenerating and growth-inhibited epidermis. the cells were analysed by DNA flow cytometry combined with cell sorting. Cells from successive fractions of the S phase were sorted on glass slides and subjected to quantitative [³H]TdR autoradiography. The results confirmed the presence of unlabelled (slowly replicating) cells in the S phase, the proportion of which was circadian stage-dependent with minimum values at midnight and in the early morning. the DNA synthesis rate throughout the S phase showed a general trend with high values in the mid-fractions, a pattern which was similar in normal and in growth perturbed epidermis. In the early morning the DNA synthesis rate pattern was bimodal with maxima both in the first and second half of the S phase, with a corresponding trough in mid-S. At this time of day the cell progression rate through S is at its maximum, indicating a relationship between the overall DNA synthesis rate and the rate distribution pattern through S.     

Different Epidermal Cell Kinetic Effects of Hydroxyurea When Injected At Two Different Times of the Day

Circadian rhythms in epidermal basal cell-cycle progression in hairless mouse skin have been repeatedly demonstrated. A dose of 10 mg/animal hydroxyurea (HU), given to inhibit DNA synthesis was injected intraperitoneally to two groups of hairless mice. One group was injected at 10.00 hours MET, when the cell-cycle progression and cell division rate are relatively high, and another group was injected at 20.00 hours, when the same variables are at minimum values. Various cell kinetic methods—[³H]TdR autoradiography, DNA flow cytometry and the stathmokinetic method (Colcemid)—were used to study HU-induced alterations in cell kinetics. Hydroxyurea (HU) immediately reduced the labelling index (LI) to less than 10% of controls when injected at both times of the day, and higher then normal values were observed 8 hr later. A subsequent decrease towards normal values was steeper in the 20.00 hours injected group. the proportion of cells with S-phase DNA content was transiently reduced in both series, but the reduction was less pronounced and control values were reached earlier in the series injected at 10.00 hours. the observed alterations in LI and fraction of cells in S phase were followed by comparable alterations in the fraction of cells in G₂ and in the mitotic rate. Hence the changes in G₂ and mitotic rate are easily explained as consequences of the previous perturbations in the S phase. The time-dependent differences in the cell kinetic perturbations caused by HU in the S phase may be explained by a circadian-phase-dependent action of HU on the influx and efflux of cells to and from the S phase, respectively. At 10.00 hours the efflux of cells from S is most heavily inhibited; at 20.00 hours the influx is predominantly blocked. Hence, when physiological flux is high HU mainly blocks the efflux from S, but when flux normally is low, HU mainly blocks the entrance to S. Within 20 hours after the HU injection, the cell kinetic variables had approached the unperturbed circadian pattern.     

High-performance liquid chromatographic separation of corticosteroids in plasma of rats. Its application to the determination of the circadian rhythm of 18-hydroxycorticosterone related to aldosterone and corticosterone

An efficient separation of corticosteroids in plasma of rats was obtained by reversed-phase high-performance liquid chromatography (HPLC). Plasma corticosteroid assays with HPLC separation were used to determine the circadian rhythm of 18-hydroxycorticosterone (18-OHB) and its possible relationship to aldosterone or corticosterone in conscious rats under standard conditions (regular diet; 12-hour light and 12-hour dark cycle). Significant circadian rhythms of plasma corticosterone, 18-OHB and aldosterone were observed with peak values at 20.00 h and nadir values at 08.00 h. The mean ratio of plasma 18-OHB to aldosterone during 24 h was 2.4. The circadian rhythm of 18-OHB was also correlated with that of plasma aldosterone or corticosterone.     

The action of N-methyl-N-nitrosourea on non-established human cell lines in vitro. I. Cell cycle inhibition and aberration induction in diploid and Down's fibroblasts.

The effect of N-methyl-N-nitrosourea (MNU) on the cell cycle, DNA synthesis and chromosomal sensitivity of cultivated diploid fibroblasts and fibroblasts with trisomy 21 was investigated in vitro. With the exception of the inhibition of G2, Down's cells proved to be more sensitive than diploid cells with respect to the decrease of the mitotic and labelling index, the inhibition of the progression of cells through the early and middle S and the frequency of induced chromosomal aberrations. The chromosomal sensitivity was dependent on the position of cells in the cell cycle during treatment with MNU. If treated during late S no differences concerning the S block and aberration frequencies were found between diploid and Down's cells. However, if MNU treatment took place in the middle and early S, Down's cells were more sensitive. The higher aberration frequencies in Down's cells resulted from elevated levels of chromatid breaks, multiple fragmentations and chromatid translocations. Possible reasons for the increased sensitivity of Down's cells are discussed.     

Circadian pattern of plasma melatonin concentrations in the marmoset monkey (Callithrix jacchus)

This study describes the concentrations of melatonin in plasma samples taken from marmoset monkeys (Callithrix jacchus) every 4 h over three 24-h periods. A circadian pattern of secretion was apparent, with higher levels recorded at night (20.00–08.00 h) than during the day (08.00–20.00 h) and a peak concentration at 20.00 h. There was a significant difference in the mean day and night concentrations (32.5 ± 4.5 pg/ml versus 49.0 ± 6.9 pg/ml, respectively) with individual concentrations ranging between<10–60 pg/ml in the day and 15–200 pg/ml at night. Circadian plasma melatonin concentrations were similar over the three 24-h periods, in male (n = 3) and female (n = 3) monkeys, and in dominant (cyclic, n = 5) and subordinate (acyclic, n = 4) females. The results show a less pronounced circadian profile in the marmoset than is seen in the human but a similar profile to that in the seasonally breeding rhesus monkey.     

Double labelling of cells with tritiated thymidine and bromodeoxyuridine reveals a circadian rhythm-dependent variation in duration of DNA synthesis and S phase flux rates in rodent oral epithelium

We describe a double labelling method for estimating the duration of DNA synthesis (Ts) and the flux of cells into and from the S phase of the cell cycle, based on labelling with tritiated thymidine [( 3H]TdR) followed by bromodeoxyuridine (BrdU) and combining immunohistological detection of BrdU with conventional autoradiography. In practice, the change in size of a window of double labelled cells occurs as the time interval between the two labels increases. In mouse tongue epithelium there is a marked circadian variation in the number of cells in DNA synthesis. From 0900 to 1500 h this labelling index (LI) falls, but from 2100 to 0300 h it increases. Our results show that the circadian decrease in LI is associated with a short Ts (5.8 +/- 0.3 h), a high S phase efflux and an initially low influx of cells from G1 into S. Conversely, the rising circadian LI is associated with a longer Ts (9.4 +/- 0.1 h), an initially low efflux and a moderate to high influx. Two time-points exist on the circadian LI curve when influx and efflux rates change abruptly. At 0100 h the efflux rate rises from low (5 cells %/h) to high (15-16 cells %/h) and simultaneously the influx rate changes from high to low. Similarly at 1300-1400 h, efflux rate falls from high (19-20 cells %/h) to low (4-8 cells %/h) values and influx rates change from low to high. This double labelling method has revealed that the duration of DNA synthesis varies across the circadian cycle, as do influx and efflux values which generally fall within a discrete range of high or low values. The timing of the changes in flux suggests the presence of two 'control' points on the circadian LI cycle that were previously unrecognized.     

Epidermis extracts (chalone) inhibit cell flux at the the G1-S, S-G2 and G2-M transitions in mouse epidermis

Epidermal cell flux at the G1-S, S-G2 and G2-M transition was examined during the first 4 hr after injection of epidermis extract. The flux parameters were estimated by a combination of several methods. The G1-S and S-G2 transit rates were calculated on the basis of a double labelling technique with [3H]TdR, the G2-M flux by means of colcemid and the relative proportion of cells in the S or G2 phase by means of flow cytometry. All experiments were performed both in early morning and late evening, corresponding to maximum and minimum rates of epidermal cell proliferation in the hairless mouse. The epidermis extract inhibited the S-G2 and G2-M transit rates to the same degree, while the inhibition of cell flux at the G1-S transit was consistently stronger. In general, the inhibition of cell flux at the different transitions was most pronounced when the rate of cell proliferation was low and vice versa.     

In vivo repair during G1 of DNA lesions eliciting sister chromatid exchanges induced by methylnitrosourea or ethylnitrosourea in BrdU substituted or unsubstituted DNA in murine salivary gland cells

The difference in efficiency of methylnitrosourea (MNU) and ethylnitrosourea (ENU) to induce SCE in early or late G1 was determined in synchronized murine salivary gland cells in vivo, as a measure of the capacity of this tissue to repair the lesions involved in SCE formation during G1. The repair during G1 was determined by treating the cells in early or late G1. Treatment was in the first cycle (G1 before incorporation of 5-bromodeoxyuridine (BrdU)) or in G1 of the second cycle (after a single round of BrdU incorporation). It was observed that 50% of the lesions induced by MNU that elicit SCE are repaired during G1. BrdU incorporation into DNA increases the sensitivity of the cell to SCE induction by MNU nearly 40%; however under this circumstance a slightly lower SCE frequency was observed in the cells exposed to MNU at early G1, indicating that during G1 only few lesions are repaired. The ENU-induced DNA-lesions involved in SCE production are nearly 100% persistent along G1; besides, a slight but significantly higher SCE frequency was observed in cells exposed at early G1, suggesting the formation of SCE-inducing lesions during G1. BrdU incorporation to DNA sensitizes the cell to SCE induction by ENU, increasing the SCE frequency to nearly to a 40%, although these additional lesions involved in SCE induction seem to be susceptible to repair during G1.     

Effects of Pulse Labelling With Tritiated Thymidine On the Circadian Rhythmicity In Epidermal Cell-Cycle Distribution In Mice

The influence of pulse labelling with 50 °Ci tritiated thymidine ([³H]TdR) (2 μCi/g) on epidermal cell-cycle distribution in mice was investigated. Animals were injected intraperitoneally with the radioactive tracer or with saline at 08.00 hours, and groups of animals were sacrificed at intervals during the following 32 hr. Epidermal basal cells were isolated from the back skin of the animals and prepared for DNA flow cytometry, and the proportions of cells in the S and G₂ phases of the cell cycle were estimated from the obtained DNA frequency distributions. the proportions of mitoses among basal cells were determined in histological sections from the same animals, as were the numbers of [³H]TdR-labelled cells per microscopic field by means of autoradiography. The results showed that the [³H]TdR activity did not affect the pattern of circadian rhythms in the proportions of cells in S, G₂ and M phase during the first 32 hr after the injection. the number of labelled cells per vision field was approximately doubled between 8 and 12 hr after tracer injection, indicating an unperturbed cell-cycle progression of the labelled cohort. In agreement with previous reports, an increase in the mitotic index was seen during the first 2 hr. These data are in agreement with the assumption that 50 °Ci [³H]TdR given as a pulse does not perturb cell-cycle progression in mouse epidermis in a way that invalidates percentage labelled mitosis (PLM) and double-labelling experiments.     

Circadian rhythms in mouse epidermal basal cell proliferation. Variations in compartment size, flux and phase duration.

Several kinetic parameters of basal cell proliferation in hairless mouse epidermis were studied, and all parameters clearly showed circadian fluctuations during two successive 24 hr periods. Mitotic indices and the mitotic rate were studied in histological sections; the proportions of cells with S and G2 phase DNA content were measured by flow cytometry of isolated basal cells, and the [3H]TdR labelling indices and grain densities were determined by autoradiography in smears from basal cell suspensions. The influx and efflux of cells from each cell cycle phase were calculated from sinusoidal curves adapted to the cell kinetic findings and the phase durations were determined. A peak of cells in S phase was observed around midnight, and a cohort of partially synchronized cells passed from the S phase to the G2 phase and traversed the G2 phase and mitosis in the early morning. The fluctuations in the influx of cells into the S phase were small compared with the variations in efflux from the S phase and the flux through the subsequent cell cycle phases. The resulting delay in cell cycle traverse through S phase before midnight could well account for the accumulation of cells in S phase and, therefore, also the subsequent partial synchrony of cell cycle traverse through the G2 phase and mitosis. Circadian variations in the duration of the S phase, the G2 phase and mitosis were clearly demonstrated.     

Twenty-four-hour variations in subcellular structures of rat type II alveolar epithelial cells

Summary Subcellular structures of type II alveolar epithelial cells in the rat lung were analyzed at six evenly spaced times over 24 h (light period: 06.00 h–18.00 h), using a morphometric technique. The cell volumes were maximal at 16.00 h and minimal at 08.00 h. The volume and surface densities of rough endoplasmic reticulum and mitochondria were low during the light period, and high during the dark period. Morphometric parameters of multivesicular bodies did not significantly fluctuate over 24 h, but they increased from 04.00 h to 08.00 h. The volume densities of lamellar bodies increased from 16.00 h to 20.00 h, and decreased from 00.00 h to 08.00 h. The change in numerical densities of lamellar bodies was inversely correlated to that in the volume densities. As shown by electron microscopy, small lamellar bodies predominated at 08.00 h, larger lamellar bodies increasing at 16.00h. Composite bodies often appeared at 08.00 h and 12.00 h. Type II cells thus appear to fluctuate, showing three phases over 24 h: formation, accumulation and secretion of lamellar bodies. In particular, it is noteworthy that the accumulation stage occurs during the resting phase of the rat, whereas the secretion stage occurs during its body-active phase.     

Regenerative proliferation of mouse epidermal cells following application of a carcinogenic skin irritant (MCA). Micro-flow fluorometric DNA measurements and 3H-TdR incorporation studies of isolated basal cells.

0.025 ml of a 1% solution of the complete skin carcinogen 20-methylcholanthrene (MCA) dissolved in benzene was applied to the back skin of hairless mice. At different time intervals up to 3 days after the carcinogen application groups of animals were injected i.p. with 30 muCi 3H-TdR 30 min before they were killed. Single cell suspensions of epidermal basal cells were prepared by a combined enzymatic and mechanical separation method, and the DNA frequency distribution pattern from each cell suspension was measured by means of micro-flow fluorometry. Smears for autoradiography were made from each cell suspension and the labeling index and mean grain count assessed. After a short initial delay, MCA induced an increase in the labeling index similar to that observed after non-specific cell injury and cell loss. Thereafter, the cells were considerably delayed in their progression through the S phase, with a low exit from S resulting in a transient emptying of the G2 compartment, without indications of any significant delay of the passage through G2 phase. The cells that had been injured by the MCA application in or just before S phase proceeded into the G2 phase and mitosis more than 24 h after the initiation of DNA synthesis. The cell kinetic reaction of epidermis to a single application of MCA is thus very different from that caused by a nonspecific cell damage, e.g. application of the vesicant agent cantharidin or removal of surface cells by cellophane tape stripping.