G2 Sub-Population In Mouse Liver Induced Into Mitosis By Lead Acetate

A single intracardiac dose of lead acetate (40 μ lead/g body weight) induced a 25-fold increase in mitosis of mouse hepatocytes 5 hr after injection, as determined by autoradiography. the prompt appearance of a mitotic wave and the relatively large number of mitoses suggest that the mitotic cells were derived from a hepatocyte sub-population arrested in the G₂ phase. the injection of lead also stimulated a small increase in labeled hepatocytes within 6 hr. Analysis of grain counts gave no evidence for unscheduled DNA synthesis. the incremental labeled cells may have originated from a small fraction of the G₁ population that was ready to enter the S phase without the usual pre-synthetic delay.     

Mutagenicity of pyrrolizidine alkaloids in the Salmonella/mammalian-microsome test.

The mutagenicities of 7 pyrrolizidine alkaloids to Salmonella typhimurium TA100 were demonstrated by a modified Ames's method. The pyrrolizidine alkaloids found to be mutagenic were clivorine, fukinotoxin, heliotrine, lasiocarpine, ligularidine, LX201 and senkirkine. Pre-incubation of these alkaloids with S9 mix and bacteria in a liquid medium was essential for demonstration of their mutagenicities.     

Effect of thioacetamide on the incorporation of [3H]-thymidine into DNA of 13 tissues and on the mitotic index of the corneal epithelium of BD2F1 in male mice while taking into consideration circadian variation

An investigation was done to assess the effect of a single intraperitoneal (ip) injection of thioacetamide on the incorporation of [3H]TdR into DNA of 13 different tissues and on the mitotic index of the corneal epithelium of mice. Seven-week-old CD2F1 mice, who had been standardized to 12 hours (hr) of light alternating with 12 hr of darkness, and fed ad libitum were used. The experimental design took into consideration the circadian variation that characterizes cell proliferation in all of the tissues studied. This was done by killing subgroups of seven animals every 6 hr for 96 hr. Thirty minutes prior to killing all mice were injected ip with 25 mu Ci of [3H]-thymidine and its incorporation into DNA was determined. The tissues of all thioacetamide and saline treated mice showed marked circadian variation in DNA synthesis. Thioacetamide treatment brought about significant (P less than 0.05) stimulation of DNA synthesis in the liver and kidney thus confirming, but extending an earlier finding. Moreover, the data showed for the first time that DNA synthesis in the bone marrow and spleen and colon were markedly statistically significantly stimulated at specific times after treatment. Synthesis of DNA in the thymus, lung, testes, tongue, esophagus, duodenum, rectum and the mitotic index in the corneal epithelium were not statistically significantly altered by thioacetamide treatment. A preliminary study also was carried out to explore what effect multiple treatment with epidermal growth factor (EGF) had on DNA synthesis in thioacetamide treated mice. Mice were killed 36 hr after thioacetamide treatment, but were treated with EGF which began 15 hr after the thioacetamide was administered and this was repeated at 18, 21 and 24 hr (50 micrograms/mouse/treatment). Under the conditions of this study EGF significantly (P less than 0.05) depressed DNA synthesis 76% in the liver, 64% in the thymus, 22% in the spleen, 30% in the duodenum and 24% in the esophagus. A histological analysis of the livers of four EGF treated and four non-EGF treated mice was done, but no consistent differences in terms of necrosis, inflammation or regeneration were observed between the two groups.     

Differential effects of 4-hydroxyaminoquinoline-1-oxide on pancreatic and liver DNA synthesis in rats.

The effect of 4-hydroxyaminoquinoline-1-oxide (4-HAQO) on DNA synthesis in the pancreas and liver, target and non-target organs for 4-HAQO carcinogenesis, respectively, were compared. Pancreatic and liver DNA synthesis were simultaneously induced in rats fed a protein deficient diet containing 0.5% DL-ethionine for 18 days, and DNA synthesis in both tissues was inhibited by hydroxyurea. A single i.v. injection of 4-HAQO at a dose of 7 mg/kg body weight also inhibited DNA synthesis in both tissues within 4 h. In the pancreas the inhibition was maximum at a dose of 7 mg/kg, and DNA synthesis was less than in the pancreas of rats fed a control grain diet. This inhibition continued for the subsequent 5 days which were tested. In the liver, the degree of inhibition was less than in pancreas but the value remained higher than in rats fed control diet. The inhibition of liver DNA synthesis at a dose of 7 mg/kg completely recovered within 1 day. These results suggest that the lesions of DNA induced by 4-HAQO and its repair might be different between the pancreas and the liver. A pancreatic chemical carcinogen, 4-HAQO, might thus have the same cytotoxic effect that liver carcinogens have toward the liver resulting in failure to respond to mitotic stimuli. This might be causally related to the organotropism of 4-HAQO toward the pancreas.     

12-O-tetradecanoylphorbol-13-acetate induces an immediate, but transient increase in mitotic activity uncoupled from DNA synthesis in the monolayer cultures of rat keratinocyte

A single wave of mitotic activity was observed in a monolayer culture of rat keratinocytes immediately after exposure to 12-O-tetradecanoylphorbol-13-acetate. A peak for cells in prophase, observed at 10 min after the exposure, was followed by a peak for metaphase at 20 min, for anaphase at 25 min and telophase at 30 min after the exposure. Thereafter, the mitotic activity began to subside. This transient stimulation of mitotic activity resulted in an increase of population density in the monolayer culture. There was neither a stimulation of DNA synthesis during this period nor a change of the DNA content after the mitotic activity was completed. This single burst of synchronous mitotic activity which did not require a substantial stimulation of DNA synthesis suggests that the effect was on the initiation process of mitosis among a subpopulation of cells, presumably cells delayed in the G2 phase of the cell cycle.     

G2 sub-population in mouse liver induced into mitosis by lead acetate

A single intracardiac dose of lead acetate (40 microgram lead/g body weight) induced a 25-fold increase in mitosis of mouse hepatocytes 5 hr after injection, as determined by autoradiography. The prompt appearance of a mitotic wave and the relatively large number of mitoses suggest that the mitotic cells were derived from a hepatocyte sub-population arrested in the G2 phase. The injection of lead also stimulated a small increase in labeled hepatocytes within 6 hr. Analysis of grain counts gave no evidence for unscheduled DNA synthesis. The incremental labeled cells may have originated from a small fraction of the G1 population that was ready to enter the S phase without the usual pre-synthetic delay.     

Effects of Hydroxyurea On the Mitotic Activity and the G2 Phase In Hairless Mouse Epidermis

Hairless mice were given 5 mg hydroxyurea (HU) intraperitoneally (i.p.) followed by 0.15 mg Colcemid® at various times after HU. the animals were killed at 2 and 4 hr after Colcemid, the epidermal mitotic counts in dorsal skin were determined and the mitotic rates calculated. These were compared with the normal mitotic rates, and the ratios between the results from HU-treated and -untreated animals were calculated. Hydroxyurea caused a considerable reduction in the mitotic rate with a trough at 6 hr, followed by a wave of increased mitotic rate with a peak at 14 hr, followed by a secondary drop at 20 hr, and then a return to normal. Another group of mice were given HU only, and the fraction of epidermal cells in G₂ was measured by flow cytometry. From these animals, without previous injection of Colcemid, we also determined the mitotic counts and calculated the mitotic durations. Cells piled up in G₂ for the first 6 hr after HU injection, then the G₂ compartment was emptied. the results are discussed in relation to previous results from this department showing the effect of the same dose of HU on DNA synthesis in the same mouse strain. It is concluded that HU not only blocks or retards DNA synthesis in epidermal cells, but also affects the movement of cells through G₂ and M. the cell kinetic effects of HU thus seem to be very complex.     

Microsomal activation of thioacetamide-S-oxide to a metabolite(s) that covalently binds to calf thymus DNA and other polynucleotides

In the presence of NADPH liver microsomes isolated from phenobarbital-pretreated rats catalyze the conversion of [³H]thioacetamide-S-oxide to a reactive intermediate(s) which covalently binds to calf thymus DNA, calf liver RNA, polyguanylic acid (poly(G)) and polyadenylic acid (poly(A)). The highest level of binding of radioactivity was obtained with poly(G), followed by poly(A), RNA and DNA. The incorporation of radioactivity into DNA was linear for 30 min and there was a requirement for NADPH for time-dependent covalent binding to occur. Performing the microsomal incubations in an atmosphere of 80% CO/20% O₂ or adding partially purified anti cytochrome P-450 immune serum to the microsomal incubations inhibited the total metabolism of thioacetamide-S-oxide and had a small, but insignificant, inhibitory effect on binding of radioactivity to calf thymus DNA. Using a reconstituted monooxygenase system containing cytochrome P-450 purified from phenobarbital-treated rats we were unable to detect any metabolism of thioacetamide-S-oxide. Only background levels of radioactivity were incorporated into calf thymus DNA when microsomes isolated from phenobarbital-treated rats were incubated with [³H]thioacetamide in the presence of NADPH. These results suggest that thioacetamide-S-oxide is an obligatory intermediate in the metabolic activation of thioacetamide to a reactive metabolite(s) which binds to calf thumus DNA.     

The Circadian Variations In the Eithelial Growth of the Hamster Cheek Pouch: Quantitative Analysis of Dna Distributions*

The pronounced diurnal rhythm in DNA distribution of the hamster check pouch epithelium both in the S fraction and in the (G₂+ M) fraction was compared with previous studies of the changes in tritiated thymidine labelling index and mitotic activity. the DNA distributions were obtained by flow cytometry after ultrasonic disaggregation of the isolated epithelium into a suspension of single nuclei. the DNA distributions were analysed with the computer program of J. Fried (1976) and by planimetry. the S fraction was higher than the autoradiographic labelling index during the whole 24 hr period. Only the computer fitted S fraction and the labelling index had the same difference between maximal and minimal values, and maxima at the same time of day. the DNA distributions showed a diurnal release of G₁ cells into S phase proceeding through (G₂+ M) phase and returning to G₁ phase within a 24 hr period.     

Potentiation of thioacetamide hepatotoxicity by phenobarbital pretreatment in rats. Inducibility of FAD monooxygenase system and age effect

The ability of phenobarbital to induce the expression and activity of microsomal drug monooxygenases in the liver presents one of the most important issues in the field of chemical interactions and in the toxicity of xenobiotics. The model of rat liver injury induced by a single dose of thioacetamide (500 mg/kg intraperitoneally) was used to study the effect of phenobarbital (80 mg/kg/day intraperitoneally) for 5 days prior to thioacetamide. Serum parameters of liver injury such as aspartate aminotransferase activity, gamma-glutamyl transferase activity and the total bilirubin levels, as well as the activities of hepatic FAD and cytochrome P450 microsomal monooxygenases, were assayed in 2- and 12-month-old rats. Samples of blood and liver were obtained from controls (injected at 0 h with 0.5 ml of 0.9% NaCl) and at 12, 24, 48, 72 and 96 h of thioacetamide intoxication either to non-treated or phenobarbital pretreated rats. Potentiation of thioacetamide hepatotoxicity by phenobarbital pretreatment was demonstrated at morphological level, and by significant increases in the activities of serum aspartate aminotransferase and gamma-glutamyl transferase, and in the levels of total bilirubin. The extent of potentiation of thioacetamide-induced liver injury by phenobarbital pretreatment was similar in both age groups. Microsomal FAD monooxygenase activity, the enzyme responsible for thioacetamide biotransformation, was significantly enhanced (twofold) by phenobarbital pretreatment, and also underwent a further increase following thioacetamide, preceding the peak of necrosis. Cytochrome P450 monooxygenases were induced by phenobarbital pretreatment more than sixfold, and sharply decreased when phenobarbital was withdrawn and thioacetamide administered, showing at 48 h intoxication values close to basal. Phenobarbital pretreatment potentiated thioacetamide necrogenicity, and this potentiation was parallel to the induction of the microsomal FAD monooxygenase system, both by phenobarbital and by thioacetamide itself. The extent of thioacetamide-induced liver injury was significantly higher in 12-month-old rats, but the effect of phenobarbital pretreatment was similar in both age groups.     

Degenerative changes, DNA synthesis and mitotic activity in rat liver following single exposure to diethylnitrosamine

Degenerative and regenerative changes induced in rat liver by single exposure to diethylnitrosamine (DEN) were examined by morphological and biochemical approaches. Apoptotic changes were observed in livers of rats exposed to a 'subnecrogenic' dose of DEN (10 mg/kg) as well as in liver parenchyma of those receiving a necrogenic dose (100 mg/kg). Zonal centrilobular necrosis was observed exclusively in the latter group. Regenerative changes, i.e., increases in DNA synthesis, labeling index and mitotic activity, occurred only in animals exposed to the higher dose. The mitogenic effect obtained in these conditions was about half that induced by two-thirds hepatectomy and the maximum response occurred about 24 h later than in partially hepatectomized rats.     

Effect of diaminobutene and diaminopropane on diet-stimulated polyamine synthesis and cell proliferation in rat liver.

The effect of two putrescine analogs were studied on hepatic polyamine synthesis and cell proliferation, both of which were stimulated by food intake. Trans-1, 4-diamino-2-butene (diaminobutene), which is a potent competitive inhibitor of ornithine decarboxylase [EC 4.1.1.17] (ODC), repressed the induction of ODC and effectively inhibited the accumulation of putrescine in rat liver which was induced by the feeding of dietary protein. Unexpectedly, diaminobutene did not suppress DNA synthesis and mitotic activity in rat liver, suggesting that it can mimic the role of putrescine in cell proliferation. 1,3-Diaminopropane effectively repressed the induction of ODC caused by food intake and also suppressed DNA synthesis and mitotic activity without affecting the accumulation of RNA or protein. The suppression of mitotic activity by 1,3-diaminopropane was reversed by a single injection of putrescine, spermidine, spermine, or diaminobutene. It was concluded that rapid accumulation of polyamines, especially putrescine, was a prerequisite for the later enhancement of DNA synthesis and cell proliferation in rat liver caused by food intake.     

INDEPENDENCE OF CENTRIOLE FORMATION AND DNA SYNTHESIS

The temporal relationship between cell cycle events and centriole duplication was investigated electron microscopically in L cells synchronized by mechanically selecting mitotic cells. The two mature centrioles which each cell received at telophase migrated together from the side of the telophase nucleus distal to the stem body around to a region of the cytoplasm near the stem body and then into a groovelike indention in the early G₁ nucleus, where they were found throughout interphase. Procentrioles appeared in association with each mature centriole at times varying from 4 to 12 h after mitosis. Since S phase was found to begin on the average about 9 h after mitotic selection, it appeared that cells generated procentrioles late in G₁ or early in S. During prophase, the two centriolar duplexes migrated to opposite sides of the nucleus and the daughter centrioles elongated to the mature length. To ascertain whether any aspect of centriolar duplication was contingent upon nuclear DNA synthesis, arabinosyl cytosine was added to mitotic cells at a concentration which inhibited cellular DNA synthesis by more than 99%. Though cells were thus prevented from entering S phase, the course of procentriole formation was not detectibly affected. However, cells were inhibited from proceeding to the next mitosis, and the centriolar elongation and migration normally associated with prophase did not occur.     

The toxic effects in rats of some synthanecine carbamate and phosphate esters analogous to hepatotoxic pyrrolizidine alkaloids

Five synthetic compounds analogous to pyrrolizidine alkaloids have been tested for toxicity in rats. These were the bis-N-ethylcarbamate esters of synthanecines A, B, C and D (Compounds I–IV) and the bis-diethylphosphate ester (V) of synthanecine A. The amino alcohol moiety in each of these had a single 5-membered heterocyclic ring in place of the pyrrolizidine amino alcohol (necine) moiety of natural pyrrolizidine alkaloids.The toxicity of these compounds differed considerably. The synthanecine A carbamate (I) was the most toxic, male and female rats being similarly susceptible. Like many hepatotoxic pyrrolizidine alkaloids, a single dose of compound I caused acute centrilobular necrosis of the liver, chronic hepatotoxicity involving the development of persistent giant hepatocytes, and chronic lung injury. Compound III had similar actions but was less toxic. The synthanecine D carbamate (IV) caused acute liver necrosis but no chronic hepatotoxicity, whereas the synthanecine A phosphate (V) had the opposite effect, with only chronic hepatotoxicity.The different toxic effects were related to the structure and metabolism of the compounds. Doses of compounds I, III and IV associated with a similar degree of acute hepatotoxicity led to similar levels of pyrrolic metabolites in the liver. Compound II, which was not hepatotoxic, gave very little liver pyrrole. The liver level of pyrrolic metabolite from the phosphate ester (V) decreased more rapidly than that from (I), and was not associated with acute toxicity.Antimitotic activity, indicated by the appearance of bizarre giant cells, was shown by compounds capable of forming pyrrolic metabolites which were bifunctional alkylating agents, but not by compound IV, which could only form a monofunctional alkylating agent. Pretreatment with phenobarbitone lowered the susceptibility of rats to compound I and greatly increased the liver level of pyrrolic metabolites associated with acute hepatotoxicity. Some rats given compounds I and III had kidney lesions primarily involving the glomerulus. The results confirm that toxic effects characteristic of many natural pyrrolizidine alkaloids can be reproduced using simplified synthetic analogues, and that such toxicity is associated with pyrrolic metabolites.     

High sensitivity of DNA replication to 5-aminouracil in the middle of the S period

Summary Cell distribution in different compartments of the cell cycle (G₁, early, middle and late S, G₂ and mitosis) has been studied during treatment with 0.5 mM 5-aminouracil and recovery inAllium cepa L. root meristems by cytophotometric and autoradiographic methods. At optimum conditions for obtaining mitotic synchronization, 5-aminouracil gives rise to cell accumulation in the S period, preferentially in its middle zone where the relative DNA content is 2.8 ± 0.1 C. After a 14-hour treatment 33% of the proliferative population is accumulated in this particular region.During recovery, a drastic reduction of the S phase and a clear increase of the mitotic frequency are the most important events observed. Apparently, the removal of the drug frees the blockage and the accumulated cells complete their interphase making up the mitotic wave.     

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.     

Cultured Human Tumour Cells May Be Arrested In All Stages of the Cycle During Stationary Phase: Demonstration of Quiescent Cells In G1, S and G2 Phase

Six human colon carcinoma cell lines were induced to enter stationary phase of growth by nutrient deprivation and cell crowding. Growth kinetics parameters (cell number, flow cytometric analysis of DNA distribution, and labelling and mitotic indices) were measured sequentially for all lines during the various stages of in vitro growth. Our results demonstrated that a substantial fraction of cells (9–18%) were located in G₂, phase when they changed from an exponential to a stationary mode of growth. Moreover, a large number of cells in stationary phase of growth had an S-phase DNA content, as determined by flow cytometry, but failed to incorporate radioactive DNA precursors (up to 15-fold difference). to substantiate these findings. cells in stationary phase of growth were induced to enter exponential growth by re-seeding in fresh medium at a lower density. Subsequently observed changes in DNA-compartment distribution, and in labelling and mitotic indices were those expected from cells that had been arrested at different stages of the cycle during their previous stationary phase. Thus, the non-proliferating quiescent state (Q), traditionally located ‘somewhere’ in G₁, phase, appears to be composed also of cells that can be arrested at other stages of the cycle (Q_s, and Q_G). Although the proportion of such cells is rather small, their contribution to the growth kinetics behaviour of human in vivo tumours will become apparent following ‘recruiting’ or ‘synchronizing’ clinical manoeuvres and will prevent the formation of a clear-cut wave of synchronized cells.