SOME EFFECTS OF BLEOMYCIN ON THE PROLIFERATION, MATURATION TIME and PROTEIN SYNTHESIS OF HAIRLESS MOUSE EPIDERMIS

Hairless mice were given 2 mg Bleomycin i.p. in 1-0 ml saline on two successive days. By a stathmokinetic method, by micro-flow fluorometry and by autoradiography certain kinetic parameters were measured during 10 days after the last injection. Cell counts were made and the turnover time of the differentiating cells estimated. Protein synthesis was estimated by the uptake of radioactive histidine, and dry cell mass measured by weighing. Bleomycin affected cell proliferation in the epidermis by depressing biphasically both the number of cells in, and the passage of cells through, the cell cycle phases: S, G₂ and M, most probably by directly affecting late Gj cells and cells in mitosis. The time between the two minima of depressed DNA synthesis corresponded to the mean generation time of the basal cells. Histidine uptake and dry cell mass were slightly affected, but the turnover time of the differentiating cells was prolonged. Bleomycin thus had a strong long-lasting inhibitory effect on epidermal cell proliferation and a marked inhibitory effect on epidermal cell maturation in mice.     

Effects of bleomycin on the epidermal content of growth-regulatory substances (chalones).

Hairless male mice were given 2 mg Bleomycin i.p. on two successive days. At different time intervals from 1 to 10 days after the last Bleomycin injection, groups of animals were killed and water extracts of hemogenized skin were made. These extracts, supposed to contain the epidermal G1 and G2 chalones, were injected into female hairless mice, and their growth inhibitory potency determined by two methods. 5 mg of lyophilized crude skin extract were injected i.p. together with Colcemid, and the animals killed 4 hr later. The number of Colcemid-arrested mitoses was determined, and was considered to be a measure of the G2 inhibitor present in the skin extracts. 10 mg of the same extracts were injected i.p., and these animals also got 3H-TdR i.p. 12 hr later, and were killed after a subsequent 30 min. The epidermal LI was determined, and was considered to be a measure of the epidermal G1 factor in the skin extracts. The results obtained were compared to the effect of Bleomycin alone and to the effects of skin extracts from non-Bleomycin-treated animals. The results show that Bleomycin provoked slight alterations in the growth-inhibitory potency of the G1 chalone, whereas significant effects were seen in the G2 chalone, There was an increased amount of growth-inhibiting factors on days 2 and 3, and on days 8-10. The results are discussed and it is concluded that the most probable hypothesis is that Bleomycin, in addition to its known inhibition by accumulation of cells with high growth inhibitory potency. An initial, additional direct effect of Bleomycin on the chalone system cammot be excluded.     

Growth regulation in X-irradiated mouse skin; the possible role of chalones.

Extracts of hairless mouse skin were tested for their content of epidermal G1 inhibitor and G2 inhibitor at daily intervals after X-irradiation with 4 500 or 2 250 rad. After either dose the skin extracts lacked G1 inhibitory activity on days 5 and 6 respectively after irradiation. This coincided with the time when the epidermal mitotic rate again became normal and started a period of over-shoot. The time interval of 5-6 days corresponds to the turnover time of the differentiating cells in hairless mouse back epidermis. The findings indicate that the proliferating cells in epidermis can respond to changes in local chalone concentration, even after X-irradiation at the tested doses, and that the irradiated epidermal cell population still retains some important properties inherent in a cybernetically regulated system. The local G2-inhibitory activity also varied after irradiation, but these variations could not be directly related to the corresponding mitotic rates.     

EFFECTS OF BLEOMYCIN ON THE EPIDERMAL CONTENT OF GROWTH-REGULATORY SUBSTANCES (CHALONES)

Hairless male mice were given 2 mg Bleomycin i.p. on two successive days. At different time intervals from 1 to 10 days after the last Bleomycin injection, groups of animals were killed and water extracts of homogenized skin were made. These extracts, supposed to contain the epidermal G₁ and G₂ chalones, were injected into female hairless mice, and their growth inhibitory potency determined by two methods. 5 mg of lyophilized crude skin extract were injected i.p. together with Colcemid, and the animals killed 4 hr later. The number of Colcemid-arrested mitoses was determined, and was considered to be a measure of the G₂ inhibitor present in the skin extracts. 10 mg of the same extracts were injected i.p., and these animals also got ³H-TdR i.p. 12 hr later, and were killed after a subsequent 30 min. The epidermal LI was determined, and was considered to be a measure of the epidermal G₁ factor in the skin extracts. The results obtained were compared to the effect of Bleomycin alone and to the effects of skin extracts from non-Bleomycin-treated animals. The results show that Bleomycin provoked slight alterations in the growth-inhibitory potency of the G₁ chalone, whereas significant effects were seen in the G₂ chalone. There was an increased amount of growth-inhibiting factors on days 2 and 3, and on days 8–10. The results are discussed and it is concluded that the most probable hypothesis is that Bleomycin, in addition to its known inhibitory effect on epidermal cell proliferation, exerts growth inhibition by accumulation of cells with high growth inhibitory potency. An initial, additional direct effect of Bleomycin on the chalone system cannot be excluded.     

A system for the study of epidermal G1-chalone in cell culture. The rat tongue epithelial cell line RTE2

A pig-skin preparation enriched in epidermal G1-chalone when administered to cells of the rat tongue epithelial line RTE2 at concentrations of 3-300 micrograms/ml (dry mass) caused a 60% reduction in cell number. Three other cell lines showed essentially no growth inhibition during chalone treatment. The kinetics of chalone inhibition were similar to those observed in mouse epidermis in vivo. Five hours after the addition of chalone preparation in fresh medium a decrease in the rate of DNA synthesis was observed. Maximum inhibition at 12 h was followed by a subsequent increase in DNA synthesis, reaching control values again after 30 h. The inhibitory effect was dose-dependent up to 3 micrograms/ml. At higher concentrations the degree of inhibition remained constant at about 50% of the control up to 300 micrograms/ml. Removal of added chalone by changing the medium at the time of maximum inhibition gave rise to a complete recovery within 9 h. These results indicate a cell-line specific, non-toxic and reversible inhibitory effect of the chalone preparation which resembles that observed in the living animal. The RTE2 cell line may thus be considered to provide a highly sensitive experimental system suitable for more detailed studies on the mechanism of action of epidermal G1-chalone.     

INFLUENCE OF HAIR PLUCKING ON THE TURNOVER TIME OF THE EPIDERMAL BASAL LAYER

The epidermal cell kinetics of male DBA-2 mice have been studied using tritiated thymidine. Liquid scintillation data from skin punches, taken after stimulation of hair growth by plucking, agree well with similar data from DBA-1 mice. A technique has been devised for obtaining sheets of epidermal cells from haired mice. Labelling index values from these sheets show that epidermal proliferation increases after plucking and they agree well with values obtained from sections. Counts of cells per unit area of epidermis show that cells are removed by plucking.
Using an estimated value for the length of S, the turnover time of the basal layer was calculated. The growth fraction and proliferative cell cycle time have also been estimated.     

Growth kinetics in newborn mouse epidermis: response to epidermal chalone.

Epidermal DNA synthesis, the epidermal mitotic rate, and the responsiveness to the epidermal G1 and G2 inhibitors were examined in newborn mice at different times after birth. The rate of epidermal cell renewal was in general low during the first two weeks of life. Later the two growth parameters increased and reached very high values at 32-33 days after birth. The rate of epidermal cell proliferation then decreased to a level comparable with that found in adult hairless mouse epidermis at 40-45 days. A single i.p. injection of skin extract containing the two epidermal growth inhibitors induced varying types of responses. The epidermal G2 inhibitor stimulated the mitotic rate on day 2 and day 10, but inhibited it on all other days. The epidermal G1 inhibitor brought about an increase in epidermal DNA synthesis on day 6 and possibly on the following days. No response at all seen at 2, 4, 17, and 32 days after birth. At the other examined times the inhibition was similar to that found in adult mice. These findings differed from those made in vitro on separated newborn mouse epidermal cells (our own unpublished data), and we suggest that the variability of newborn mouse epidermis could be an expression of the immaturity of the skin as a whole, and that dermis in some way modifies the response of epidermis to exogenous epidermal chalone. Our study did not support the theory that the nonresponsiveness of newborn mouse epidermal at certain times could be due to the presence of nonresponsive stem cells in epidermis.     

Ethylene stimulates endoreduplication but inhibits cytokinesis in cucumber hypocotyl epidermis

The effects of ethylene on cell division are generally considered inhibitory. In this study, we demonstrate that transient ethylene exposure, while suppressing cytokinesis, stimulates DNA synthesis. We monitored DNA synthesis and cytokinesis in the epidermis of cucumber (Cucumis sativus) hypocotyls, an organ whose post-germination development involves strictly limited cell division. During exposure to ethylene, DNA synthesis, assessed by the incorporation of the thymidine homolog 5-bromo-2'-deoxyuridine, was detected in 20% of the epidermal cells, whereas DNA synthesis was nearly undetectable in normal air. Cytofluorometric analysis of nuclei in affected cells showed an up to 8-fold increase in DNA content. During this time, new cell plate formation was not detected. However, shortly after ethylene was removed, DNA content was rapidly restored to 2C (diploid) levels in all cells, and new cell plate formation dramatically increased. These results demonstrate that ethylene promotes DNA synthesis and its endoreduplication but inhibits cytokinesis, thereby maintaining some cells in G2 phase.     

The effect of bleomycin on rapidly proliferating epidermis. A comparative investigation using micro-flow fluorometry, H3Tdr incorporation and a stathmokinetic method (colcemid).

At different time intervals after injection of Bleomycin (BLM) th effect on several kinetic parameters of the hairless mouse epidermis stimulated to proliferate by previous adhesive tape stripping was measured. Micro-flow fluorometry was used to determine the relative number of cells in the various phases of the cell cycle (G1, S and G2). Tritiated thymidine was used to determine labelling indices and grain counts. Colcemid was used to observe the mitotic rate. An initial decrease followed by a subsequent significant increase compared to the non-BLM-treated controls was observed in all parameters studied except the mitotic rate, which remained lower than in the control animals during all 48 hours. The transit time of the cells through the S-phase was initially slightly prolonged, but thereafter it seemed to be shorter than that of the controls. BLM seems to provoke a partial blocking of cells in the G1 phase. When the block is released, a greater number of cells pass through the S phase in partial synchrony at a higher than normal speed. BLM induced a low mitotic rate which remained below the level of that of the normal animals after stripping, even though there obviously was a considerably higher influx of cells from the S phase to the G2 phase. This resulted in a subsequent accumulation of cells in the G2-phase. Thus, BLM has also a blocking effect on the G2-M boundary of the cell cycle. This inhibitory effect of BLM on the mitotic rate was shown to be independent of the effect of BLM on the DNA synthesis. BLM therefore seems to have complex influence on epidermal cell kinetics in vivo. Cells in G1-phase are partially and transiently blocked, but this block is soon released. These cells thereafter pass through the S-phase and pile up in the G2-phase, because BLM also blocks the passage of cells from the G2-phase to mitosis. The overall reduction in cell proliferation seen after BLM in vivo seems mainly to be due to the effect on the G2-M boundray of the cell cycle.     

Cell cycle specificity and reversibility of the inhibitory effect of epidermal G1-chalone on DNA synthesis in partially synchronized RTE-2 keratinocytes in vitro

The specific action of a pig skin fraction enriched in epidermal G1-chalone, a tissue-specific inhibitor of epidermal DNA synthesis, was investigated by means of flow cytofluorometry. The results indicate that G1-chalone inhibits progression of partially synchronized rat tongue epithelial cells (line RTE-2) through the cell cycle at a point 2 h prior to the beginning of the S-phase. Approximately 8 h after chalone addition, the cells can overcome the inhibition and begin to enter the S-phase. The duration of this delay is concentration-independent, but the fraction of cells affected is proportional to the chalone concentration. The progression of cells which already have entered S-phase is not affected. In contrast to the G1-chalone preparation, aphidicolin, a potent inhibitor of DNA polymerase alpha, clearly shows S-phase-specific inhibition. These results indicate that the epidermal G1-chalone inhibits epidermal cell proliferation in a fully reversible manner by a highly specific effect on cell cycle traverse.     

The effect of chalone on the cell cycle in the epidermis during wound healing

A cut was made on the ear conch of mouse and an extract containing epidermal chalone was injected subcutaneously 2 days later. The time changes after the chalone administration in the number of cells labeled with ³H-thymidine, in the number of grains on labeled cells and in the number of mitoses within the regenerating epidermis surrounding the wound were investigated by means of autoradiography (ARG). Grain counts decreased temporarily in early phase (0–2 h) after chalone injection. This decrease in grain count resulted in a decrease in the number of labeled cells on the ARG of a short exposure but not in that on the ARG of a long exposure. A decrease in the number of labeled cells on the ARG of a long exposure was evident at 6 h when the grain counts reverted to a level similar to the control without chalone. The number of mitoses reached a minimum at 2 h and then recovered quickly, indicating a rapid disappearance of the inhibition of cells in G 2 from entering M phase. Mitoses decreased again thereafter, presumably as a result caused by inhibition of cells in the preceding S phase from completing DNA synthesis. The extract made similarly from liver or kidney affected neither the mitotic nor the DNA synthetic activities.These results indicate that the epidermal chalone or chalones inhibit the epidermal cell proliferation in, at least, 3 different processes of the cell cycle; the DNA synthesis in S phase, the transition from G 1 to S phase and the transition from G 2 to M phase.     

Cholesterol biosynthesis by the cornea. Comparison of rates of sterol synthesis with accumulation during early development

The origin of the cholesterol needed by the cornea for growth and cell turnover was addressed by comparing absolute rates of sterol synthesis with rates of sterol accumulation during early development of the rabbit. Linearity of incorporation of 3H2O and [14C]mevalonate into digitonin-precipitable sterols with time of incubation in vitro and a lack of accumulation of 14C in intermediates of sterol biosynthesis indicated that tritiated water can validly be used to measure rates of sterol synthesis by the cornea. The rate of sterol synthesis per unit weight of rabbit cornea was constant between 14 and 60 days of age at an average 1.03 nmol of 3H of 3H2O incorporated/mg dry cornea per 8 h. Essentially all of the synthesized cholesterol and most of the cholesterol mass was present in corneal epithelium. The cumulative sterol synthesized over the 46-day period studied exceeded the observed rate of cholesterol accumulation by sixfold. Cholesterol synthesized in excess of the growth requirement was likely used to support turnover of the epithelium which was estimated at 9 days. Removal of cholesterol from the cornea by excretion into tear fluid and clearance by high density lipoproteins are also considered.     

Cell kinetics in mouse epidermis studied by bivariate DNA/bromodeoxyuridine and DNA/keratin flow cytometry.

Hairless mice were injected intraperitoneally with bromodeoxyuridine (Brd-Urd). Basal cells were isolated from epidermis, fixed in 70% ethanol, and prepared for bivariate BrdUrd/DNA flow cytometric (FCM) analysis. Optimum detection of incorporated BrdUrd in DNA was obtained by combining pepsin digestion and acid denaturation. The cell loss was reduced to a minimum by using phosphate-buffered saline containing Ca2+ and Mg2+ to neutralize the acid. The percentage of cells in S phase and the average uptake of BrdUrd per labelled cell in eight consecutive windows throughout the S phase were measured after pulse labelling at intervals during a 24 h period. Furthermore, the cell cycle progression of a pulse-labelled cohort of cells was followed up to 96 h after BrdUrd injection. In general the results from both experiments were in good agreement with previous data from 3H-thymidine labelling studies. The percentage of cells in S phase was highest at night and lowest in the afternoon, whereas the average uptake of BrdUrd per labelled cell showed only minor circadian variations. There were no indications that BrdUrd significantly perturbed normal epidermal growth kinetics. A cell cycle time of about 36 h was observed for the labelled cohort. Indications of heterogeneity in traverse through G1 phase were found, and the existence of slowly cycling or temporarily resting cells in G2 phase was confirmed. There was, however, no evidence of a significant population of temporarily resting cells in the S phase. Bivariate DNA/keratin FCM analysis revealed a high purity of basal cells in the suspensions and indicated that the synthesis of the differentiation-keratin K10 was turned on only in G1 phase and after the last division.     

Kinetic studies of the murine foetal thymus using vincristine sulphate

The turnover time of the foetal thymus has been evaluated in CD1 mice using the metaphase arrest drug vincristine sulphate and also by direct cell counting and found to be 18 h (range 12--26) and 11.9 h (range 10.9--13.1) respectively. Vincristine sulphate can be used for cell kinetic studies on foetal thymus provided an appropriate dose (5 mgm per kgm body weight given intravenously) and time scale (less than 1 hour after injection) are used for these measurements. These conditions are different from those used for adult tissues. Using 125I-iododeoxyuridine uptake measurements, it was found that vincristine sulphate suppressed DNA synthesis in the foetal thymus but not in the maternal thymus at this dose. Only the G2 cohort of cells in the thymus entered mitosis.     

In vivo and in vitro synthesis, release, and uptake of [3-H]-dopamine in mouse striatal slices after in vivo exposure to chlordecone

Effects of treatment of mice with chlordecone (25 mg/kg/d) on striatal dopaminergic activities such as synthesis, turnover, uptake, and release were investigated in vivo and in vitro. In mice receiving chlordecone for five days, there were no significant changes in in vivo dopamine (DA) synthesis and turnover in striatum and in vitro [3-H]-dopamine uptake and K+-stimulated [3-H]-dopamine release in striatal slices. In mice receiving chlordecone for eight days, the in vivo synthesis of [3-H]-dopamine from [3-H]-tyrosine in striatum was slightly inhibited and the in vitro [3-H]-dopamine synthesis in striatal slices was significantly decreased. Furthermore, both uptake and K+-stimulated release of [3-H]-dopamine from striatal slices were significantly reduced. The turnover rate of newly synthesized [3-H]-dopamine from [3-H]-tyrosine in striatal slices was unchanged after eight consecutive days of chlordecone administration. These results suggest that chlordecone may cause impairments in pre- and/or postsynaptic membranes of dopaminergic neurons which modulate motor function.     

Flow cytometric measurement of cell cycle kinetics in rat Walker-256 carcinoma following in vivo and in vitro pulse labelling with bromodeoxyuridine.

Flow cytometric measurements of total DNA content, cell cycle distribution, and bromodeoxyuridine (BrdUrd) uptake were made in rat Walker-256 carcinoma cells. After both in vivo and in vitro pulse labelling with BrdUrd, Walker-256 tumor cells were stained with propidium iodide (PI) to estimate the total DNA content and a monoclonal antibody against BrdUrd to estimate the relative amount of cells in S phase. BrdUrd-labelled single cell suspensions were harvested at different time intervals to determine the movement of these cells within the cell cycle. To increase BrdUrd uptake, fluorodeoxyuridine (FDU), a thymidine antagonist, was also applied in vivo and in vitro. The results indicated exponential growth characteristics for this tumor between days 5 and 8 after implantation. Tumor doubling times, derived from changes in tumor volume in vivo and from the increase in cell number in vitro were similar. The mean time for DNA synthesis was estimated from the relative movement of BrdUrd-labelled cells towards G2. The percent of cells labelled with BrdUrd and the DNA synthesis time were similar regardless of the mode of BrdUrd administration. This study demonstrates that BrdUrd labelling of rat Walker-256 carcinoma cells in vitro yields kinetic estimates of tumor proliferation during exponential growth similar to those with the administration of BrdUrd in the intact tumor-bearing rat.     

Turnover and maturation kinetics in the hairless mouse epidermis. Continuous [3H]TdR labelling and mathematical model analyses

Hairless mice were continuously labelled with 10 microCi of tritiated thymidine ([3H]TdR) every 4 h for 8 d, and the proportions of labelled basal and differentiating cells were recorded separately. The mitotic rate was measured by the stathmokinetic method and the cell cycle distributions were measured by flow cytometry of isolated basal cells at intervals during the labelling period. The mitotic rate of the [3H]TdR-injected animals did not deviate from control values during the first 5 d. Computer simulations of the data based on various mathematical models were made, and three main conclusions were obtained: (1) a large spread in transit times through the G1 phase was found, together with a very narrow distribution in maturation time of differentiating cells; (2) about 20% of the differentiating cells were estimated to leave the basal cell layer directly after mitosis. This is consistent with results obtained from different sets of data; and (3) during continuous labelling more than 90% of the cells are labelled during each passage through the S phase.     

N-methylformamide effects on cell proliferation and antigenic pattern in HT-29 colon carcinoma cell line

The effects of the differentiating agent N-methylformamide (NMF) on cell proliferation and antigenic pattern of HT-29 colon carcinoma cells have been investigated. The cell line was cultured in the presence, or absence, of 1% NMF and tested for the above mentioned characteristics, both in vitro and after injection into nude mice. The percentage of cells in the various cell cycle compartments was estimated by flow cytometry. The presentation on the cell surface of molecules such as tumour associated antigens (TAAs), HLA class I molecules and epidermal growth factor receptor (EGF-R) was analysed by ELISA, flow cytometry and immunohistochemistry. Results demonstrate that NMF impairs HT-29 cell proliferation with a remarkable accumulation in the G0/G1 phases, as well as inducing a modification of the membrane antigenic pattern. The presence of NMF in the culture medium decreases the TAAs and EGF-R whereas HLA antigen maintains the same level of positivity in the two cell lines. These alterations are consistent with a different behaviour in vivo of the tumours originated from NMF treated and untreated cells. Tumours derived from NMF treated cells show a delay in the appearance and low levels of immunodetectable carcinoembryonic antigen (CEA) molecules.     

Magnesium and phosphate enrichment of culture medium stimulates the proliferation of epidermal cells from newborn and adult mice

The proliferation and differentiation of mouse epidermal cells can be sequentially analyzed by modification of extracellular calcium. Newborn cells cultured in low calcium medium (less than 0.1 mM) proliferate as a monolayer and maintain a typical basal cell phenotype in culture but have a limited proliferative capacity and short lifespan. Elevation of the magnesium content of the culture medium from 1 to 5 mM stimulated the proliferation of newborn mouse (1-3 days old) keratinocytes. Maximal DNA synthesis rates, as determined on day 5 of culture, were up to 2-3-fold higher in the magnesium-enriched cultures. Exposure to high magnesium caused 3-4-fold increases in the DNA content of newborn keratinocyte cultures, and extended the confluent phase of epidermal cell growth to over 10 days. Other divalent cations (strontium, copper, zinc, nickel, beryllium, and barium) did not improve keratinocyte growth in culture. Keratinocytes from the tail skin of adult (3 months old) mice displayed an absolute requirement for high phosphate in the culture medium. The medium containing an optimal (10 mM) phosphate concentration prevented the cell detachment caused by the standard low (1 mM) phosphate medium, and in combination with an elevated magnesium content (10-15 mM) it markedly increased both DNA synthesis rates and DNA content of the adult cell cultures. Optimally growing, newborn or adult cultures contained less cells in the G1 phase of the cell cycle and more cells in S and G2 +M. The addition of phosphate and magnesium per se did not induce keratinocyte differentiation and did not interfere with the high calcium (1 mM)-induced differentiation.     

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.