HYDROXYUREA EFFECTS IN THE C3H MOUSE II. MAMMARY TUMOR CELL KINETICS

The cellular kinetics of C3H mouse mammary tumors were studied following a single dose (3 mg/g body weight) of hydroxyurea (HU). This dose was large enough to cause a significant perturbation in the growth curves of these tumours. This was accomplished by labeling the cells with tritiated 5-iodo-2'-deoxyuridine and performing detailed autoradiographic analysis. This dose of HU caused a temporary inhibition in growth and completely inhibited DNA synthesis for 4–5 hr. The HU-killed cells (pyknotic and karyorrhectic) reach a maximum around 10–12 hr and are apparently all removed in about 1 day. Tumors from a fast-growing line (S102F) showed some evidence for cell synchrony upon recovery from HU inhibition but desynchronization occurred within one cell cycle. The cell generation time was not decreased during the acute recovery phase, but the growth fraction shifted from 0·6 to 1·0, and the data suggested that the normal flow of cells from the proliferating pool to the degenerate pool was temporarily interrupted. The cellular kinetic parameters have probably returned to normal by 48 hr after the HU injection.     

CELL PROLIFERATION IN THE CASTRATE MOUSE SEMINAL VESICLE IN RESPONSE TO TESTOSTERONE PROPIONATE

The cell proliferation kinetics following induced DNA synthesis in the mouse seminal vesicle were measured after treatment with testosterone propionate. Fraction labelled mitosis curves at 24, 48 and 72 hr after injection gave t ₂ values of 1·5, 2·0 and 1·8 hr respectively, and t _s values of 10·5, 8·0 and 8·0 hr. T _c measured 48 hr after stimulation was 17·5 hr. Growth fraction rose from 0·14 at 24 hr to 0·64 at 48 hr, and fell to 0·32 by 72 hr. A simple model is proposed in which the rise and fall of mitotic index and labelled index is determined by the 'cell distribution ratio'.     

KINETICS OF GROWTH OF HAEMOPOIETIC COLONY CELLS IN AGAR

Cell kinetic parameters of mouse granulocytic and mononuclear cells growing in colonies in agar cultures have been measured. Analysis of flash and continuous labelling studies with ³H-thymidine together with determinations of colony size, growth fraction and mitotic indices, gave the following values for the phases of the cell cycle: G₁= 6·3 1·6 hr, S = 5·8 ± 1·4 hr, G₂= 1·7 ± 0·1 hr and M = 0·7 ± 0·1 hr (42 ± 8 min). No difference in the cell cycle parameters of granulocytic and mononuclear cells were found in this study.
Colonies of different size from cultures of the same age group had similar labelling indices, indicating that the size of a colony is not a function of the rate of proliferation of cells in the colony. Rather, variation in colony size is probably representative of an initial delay in the onset of colony development.     

HYDROXYUREA EFFECTS IN THE C3H MOUSE: I. DUODENAL CRYPT CELL KINETICS

Duodenal crypt cell kinetics in C3H mice have been studied before and after the injection of a single dose (3 mg/g body weight) of hydroxyurea (HU). This was done by autoradiographic analysis of crypt cells which had been labeled with tritiated 5-iodo-2'-deoxyuridine. This dose of HU kills the cells which are synthesizing DNA at the time of injection, inhibits DNA synthesis completely for 4–5 hr, and causes a partial synchronization of the cells when they recover from the inhibitory effects of HU. Duodenal crypt recovery is manifested by a decrease in the mean cell cycle time, an increase in the proliferating fraction, and a lengthening of the crypts. The acute cellular responses are apparently complete within 24–48 hr, but the length of the crypt has not returned to normal by 48 hr after HU administration.     

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.     

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.     

Cell kinetics-dependent antitumor effect of irinotecan hydrochloride induced by the synchronizing effect of hydroxyurea: cell kinetics and dosing time

Influence of hydroxyurea (HU) on the antitumor effect of irinotecan hydrochloride (CPT-11) was investigated in ICR male mice transplanted with sarcoma 180 cells (S-180). A single dose of CPT-11 (100 mg/kg) was injected at various times after a single dose of HU (300 mg/kg). The relative tumor weight varied significantly depending on the timing of CPT-11 injection after HU injection (P < 0.01). The higher antitumor effect of CPT-11 was observed when DNA synthesis of S-180 cells increased (20 hr), and the lower effect was observed when the DNA synthesis decreased (0 hr). The loss of body weight also varied significantly depending on the timing of CPT-11 injection after HU injection (P < 0.01). The toxicity of CPT-11 was higher when the inhibitory effect of HU on DNA synthesis of bone marrow cells was stronger (15 hr), and the lower toxicity was observed when the inhibitory effect was not observed (0 hr). The plasma SN-38 concentration at 2 hr after CPT-11 injection was higher at 20 hr after HU injection than at 0 hr after HU injection. The difference in plasma esterase activity between 0 hr and 20 hr after HU injection was regarded as the mechanism underlying the dosing time-dependent difference of the SN-38 concentration. These experiments suggest that HU can produce a different phase of cell cycle between tumor cells and normal cells. This leads to increase the antitumor effect of CPT-11 without increasing the adverse effect of the drug. It is essential to consider the dosing time in the two-drug combination therapy.     

Mitotic Rate of Rat Thyroid Follicular Cells In Vivo In Response to A Single Injection of Thyrotropin (Tsh)

The mitotic rate of thyroid follicular cells was assessed by a stathmokinetic method at intervals from 15 min to 24 hr after a single injection of 1 iu/kg of thyrotropin (TSH). the mitotic rate was increased 15 min after TSH and remained elevated for 3 hr. Two further peaks of mitotic activity were present at 9 hr and 24 hr after TSH. Serum TSH concentrations were increased from 5 min to 3 hr with a maximum at 1 hr.     

Dose-dependent cytokinetic changes following 1-beta-D-arabinofuranosylcytosine and hydroxyurea in L1210 and S-180 in vivo.

DNA synthesis inhibition and recovery in L1210 and S-180 ascites tumors following 1-beta-D-arabinofuranosylcytosine (Ara-C) and hydroxyurea (HU) were measured autoradiographically as a basis for optimizing drug schedules. Tumor bearing mice, 10(6) cells day 0, were treated on day 4 with 20, 200 or 2000 mg/kg Ara-C or 50, 300 or 1800 mg/kg HU. At various intervals following drug, [3H]thymidine was administered i.p. and mice were killed 1 hr later. Tumor cells were analyzed for labeling index (LI) and grain count (GC) to determine the percentage of cells in S phase and the distribution of DNA synthesis rates among the labeled cells, respectively. Following each dose of HU, DNA synthesis was inhibited completely. Recovery of LI was rapid and approached control values by 6 hr. Following each dose of Ara-C, DNA synthesis was inhibited completely for at least 6 hr. Recovery of LI was first noted 6 hr following 20 mg/kg Ara-C and 9 hr following 200 mg/kg. Following both doses the LI reached 100% of the control value by 26 hr. GC analysis indicated that following Ara-C treatment, DNA synthesis was reinitiated first with cells with low GC from 6 to 12 hr followed by cells with increasing GC from 12 to 20 hr. The labeling intensity reached control values by 20 hr and an 'overshoot' occurred by 26 hr. These data suggest that the recovery of DNA synthesis rate is a gradual process. Survival data for mice receiving two doses of Ara-C indicated that the optimal interval for retreatment following the lower dose of Ara-C occurred by 6 hr as compared to 12--16 hr for the higher dose. These times coincided in both instances with recovery of LI to 33--50% of control values. Early recovery of LI may be the best method currently available for estimating the optimal time for retreatment with an S phase specific drug.     

Dose-Dependent Cytokinetic Changes Following 1-β-D-Arabinofuranosylcytosine and Hydroxyurea In L1210 and S-180 In Vivo

DNA synthesis inhibition and recovery in L1210 and S-180 ascites tumors following 1-β-D-arabinofuranosylcytosine (Ara-C) and hydroxyurea (HU) were measured autoradiographically as a basis for optimizing drug schedules. Tumor bearing mice, 10⁶ cells day O, were treated on day 4 with 20, 200 or 2000 mg/kg Ara-C or 50, 300 or 1800 mg/kg HU. At various intervals following drug, [³H]thymidine was administered i.p. and mice were killed 1 hr later. Tumor cells were analyzed for labeling index (LI) and grain count (GC) to determine the percentage of cells in S phase and the distribution of DNA synthesis rates among the labeled cells, respectively. Following each dose of HU, DNA synthesis was inhibited completely. Recovery of LI was rapid and approached control values by 6 hr. Following each dose of Ara-C, DNA synthesis was inhibited completely for at least 6 hr. Recovery of LI was first noted 6 hr following 20 mg/kg Ara-C and 9 hr following 200 mg/kg. Following both doses the LI reached 100% of the control value by 26 hr. GC analysis indicated that following Ara-C treatment, DNA synthesis was reinitiated first with cells with low GC from 6 to 12 hr followed by cells with increasing GC from 12 to 20 hr. the labeling intensity reached control values by 20 hr and an ‘overshoot’ occurred by 26 hr. These data suggest that the recovery of DNA synthesis rate is a gradual process. Survival data for mice receiving two doses of Ara-C indicated that the optimal interval for retreatment following the lower dose of Ara-C occurred by 6 hr as compared to 12–16 hr for the higher dose. These times coincided in both instances with recovery of LI to 33–50% of control values. Early recovery of LI may be the best method currently available for estimating the optimal time for retreatment with an S phase specific drug.     

BRAIN GLYCOGEN AFTER INTRACISTERNAL INSULIN INJECTION

Abstract— Intracisternal injection of 0·1 i.u. of insulin to rats caused an increase in the brain glycogen content. Intravenous and intraperitoneal injection of the same amount had no effect on brain glycogen. The increase after intracisternal injection was first observed after 3–4 hr.     

AUTORADIOGRAPHIC CONFIRMATION OF THE MITOTIC DIVISION OF EVERY MOUSE JEJUNAL CRYPT CELL LABELLED WITH 3H-THYMIDINE

The question was investigated of whether for crypt epithelia of the jejunum of the mouse all cells labelled after a single injection of ³H-TdR subsequently divide or whether cells exist in the crypt which synthesize metabolic DNA and, therefore, do not undergo division after labelling.
A double labelling experiment was performed with a first injection of ³H-TdR followed 1 hr later by an injection of ¹⁴C-TdR. Then from double emulsion autoradiographs of isolated squashed crypts the number of ³H-only, ¹⁴C-only and double labelled cells and mitoses were counted.
The double labelling produced a narrow, 1 hr wide sub-population of ³H-only labelled cells. This subpopulation of S cells completed its division before labelled cells were lost from the crypts by migration onto the villi. The results showed that this subpopulation of ³H-only cells completely doubled within 3 hr and then remained constant through 6 hr. From this result it was concluded that every cell labelled after a single injection of ³H-TdR divides.
From the same autoradiographs the flow rate through the end of mitosis was measured. From the flow rate and the mitotic index a mitotic duration of 0·5 hr was determined. The agreement of this measured mitotic time with the value calculated from the labelling index, mitotic index and S duration is also strong evidence that every labelled cell divides.
Both experiments show that the intestinal crypt does not contain cells synthesizing metabolic DNA.     

Cortisol responses of pallid sturgeon and yellow perch following challenge with lipopolysaccharide

Plasma cortisol responses of pallid sturgeon Scaphirhynchus albus and yellow perch Perca flavescens following injection with equal doses of lipopolysaccharide were compared. Concentrations of cortisol in plasma from pallid sturgeon did not change following injection (6·0–11·0 v. 6·4 ng l⁻¹ pre-stress) while in yellow perch plasma they were shown to increase up to 6 h (117·0 v. 9·8 ng l⁻¹ pre-stress) after the injection. These results are consistent with other reports for pallid sturgeon that illustrate a reduced cortisol response following other applied stressors relative to teleosts and suggest differences in the expression and regulation of their inflammatory responses.     

DYNAMICS OF LEUKOCYTE MIGRATION INTO THE MOUSE ASCITES TUMOR

There is a marked increase in the number of peritoneal leukocytes (lymphocytes, monocytes and granulocytes) during the growth of Ehrlich ascites tumor in mice. No local proliferation (as indicated by a labeling at 1 hr following a single ³H-TdR injection) was observed in the normal peritoneal leukocytes or those in the ascites tumor, except for a very minor labeling of some tumor macrophages. Kinetics of peritoneal leukocytes was studied with a series of twelve injections of ³H-thymidine (20 μCi every 8 hr) in normal mice as well as mice injected with 10⁶ tumor cells i.p. 2 hr after the last ³H-TdR injection. Animals were sacrificed at intervals up to 6 days. Granulocyte labeling in the blood as well as peritoneal space was near 100% in both groups of animals at all the intervals. Temporal changes in the labeling of lymphocytes (from 10% at 0 day to 22% at day 6), and monocytes (from 20% at 0 day to 57% at day 6) were identical in the blood and peritoneal space of normal animals, indicating a free exchange of cells between these compartments. Higher labeling indices than those in the controls were attained in the blood of tumor-bearing hosts (viz 40% for lymphocytes and 80% for monocytes at 6 days) suggesting an increased turnover of these cells in the circulation. In addition, peritoneal mononuclear cells of tumor-bearing mice showed even a higher labeling than those in the blood (viz 65% for lymphocytes and 92% for monocytes at 6 days) indicating a selective migration and/or retention of newly formed cells within the tumor, in contrast to a random migration into the normal peritoneal cavity. Furthermore, an identical labeling of macrophages to that of monocytes within the tumor indicated a short monocyte-macrophage transition. The preferential accumulation of young mononuclear cells into the tumor may be of functional importance.     

DNA TURNOVER IN ADRENAL MEDULLARY CELLS OF DIFFERENT STRAINS OF RATS AND ITS ENHANCEMENT AFTER INTERMITTENT EXPOSURE TO COLD

In Italico and Wistar rats maintained at room temperature 1% of nuclei of cells in the adrenal medulla incorporate ³H-thymidine. Following intermittent exposure to cold, the numbers incorporating increase to 10% and 7% in Italico and Wistar strains respectively. Only in the Wistar strain does the increase occur during actual exposure.
Assuming S to be 6–8 hr the labelling indices actually determined indicate a turnover time of DNA of 21–29 days. Since mitotic indices in experimental and control animals were found to be 0.004% without colchicine treatment and 0.009% after 3 hr of colchicine treatment, the turnover times of cells were calculated to be 1388–3125 days. To correlate mitotic indices and labelling indices, an S period of 400 hr would have to be assumed. It is concluded therefore that: (i) most of the observed labelling of DNA is due to metabolic turnover of DNA and only a small proportion represents pre-mitotic synthesis, (ii) differences in the rates of DNA synthesis found during exposure to cold in Italico and Wistar rats respectively are sufficient to account for the differences in reduction of DNA previously found between the two strains under these experimental conditions.     

DIURNAL VARIATION IN THE LABELING INDEX OF MOUSE EPIDERMIS: A DOUBLE ISOTOPE AUTORADIOGRAPHIC DEMONSTRATION OF CHANGING FLOW RATES

A diurnal rhythmicity in the labeling index was observed in the epidermis of hairless mice, injected with either ¹⁴C- or ³H-thymidine, at different times during a 24 hr period. A modified autoradiographic technique, using ¹⁴C- and ³H-thymidine and two overlying emulsion layers, makes it possible to clearly differentiate synthesizing cells which are singly labeled with either carbon-14 or tritium, and cells labeled with both isotopes. At various times during a 24 hr period, hairless mice were injected with thymidine-2-¹⁴C and colcemid, followed at 2 or 3 hr by a second injection of ³H-thymidine. The labeling indices were calculated for the ¹⁴C- and ³H-thymidine injection times. These labeling indices were consistent with the control, single isotope, labeling indices and exhibited the same diurnal rhythm. Cells singly labeled with ³H- or ¹⁴C-thymidine have either started or completed DNA synthesis during the interval between the two injections. Flow rates into and out of DNA synthesis, throughout the 24 hr period, can be calculated from these singly labeled cells. The flow rates varied rhythmically throughout the day and paralleled changes in the labeling indices. The influx and efflux flow rates, at all times measured, were not equal. The influx flow rate was reflected in the efflux rate at a time later equal to the duration of S. By means of these flow rates, the per cent of cells in DNA synthesis was calculated for each hour during a 24 hr period. The resulting labeling index curve matches the observed 24 hr diurnal rhythm in labeling indices. By extension of these flow rates through mitosis, the resulting mitotic index curve is comparable to the reported 24 hr diurnal rhythm in mitotic indices.     

Cell Proliferation In Emt6 Tumors Treated With Single Doses of X-Rays Or Hydroxyurea. I. Experimental Results

EMT6 mouse mammary tumors were treated in vivo with 5 mg/mouse of hydroxyurea (HU) or 300 rads of X-rays. the proliferation of the tumor cells was followed for 28 hr after treatment. Changes in the ³H-TdR labeling index, the mitotic index, the specific activity of the ³H-TdR-labeled DNA, and the proportion of suspended, clonogenic cells in the S phase of the cell cycle were examined and compared. Evidence was found for reassortment of the surviving cells in treated tumors into partially synchronous cohorts. the partial synchrony in the proliferation of the surviving cells was not accurately predicted by the changes in the labeling index and the mitotic index. the changes in DNA specific activity proved unacceptable as an indicator of cell proliferation in solid EMT6 tumors treated with low doses of radiation or HU.     

Alpha-fetoprotein serum levels and the development of estrogen-sensitive cell multiplication in the hamster uterus

Subcutaneous injections of 5 or 25 micrograms estradiol-17 beta (E2)/kg in ovariectomized adult hamsters produced substantial increases in uterine wet weight, protein content and the mitotic indices of the glandular and luminal epithelia. However, no significant increase was seen in total uterine DNA. Intact hamsters from 2 to 25 days of age received a daily subcutaneous injection of 5 micrograms E2/kg for 2 consecutive days. Significant increases in uterine wet weight and protein content first occurred at 8 and 17 days, respectively. No significant increase was observed in uterine DNA. In a separate experiment, hamsters between 2 and 20 days of age received one subcutaneous injection of 5 micrograms E2/kg. Mitotic indices in the stroma were increased at 6 and 10 days of age. Mitotic indices in the luminal epithelium were significantly increased only at 6 days of age. Rocket immunoelectrophoresis revealed a sharp decline in serum alpha-fetoprotein (AFP) concentrations after 2 days of age. Estradiol concentrations in the sera of immature hamsters gradually decreased from 55 pg/ml at 0 days of age to 17 pg/ml at 20 days of age. These results provide a quantitative analysis of the effects of E2 upon cell proliferation in the hamster uterus. The correlation of declining AFP levels and the incipience of the mitotic response to estrogen suggests that AFP may directly inhibit estrogen-sensitive cell multiplication in the neonate. Other possible causes for the lack of a mitotic response in the uterus of the newborn hamster to the administration of E2 are also discussed.     

Characteristics of egg and larval production in captive bluespotted gobies

Spawning of the Hawaiian coral-reef goby Asterropteryx semipunctata was diurnal, occurring at various times throughout the day. Mean length of eggs deposited in nests was 0·76 mm (range 0·67–0·84); mean egg width was 0·47 mm (range 0·41–0·52). Clutch size varied from 296 to 1552 eggs (mean=886±309), and was independent of standard length, total body weight, and body condition. Mean relative clutch size was 1·59 eggs mg^-1 total body weight (range 0·84–2·43). Clutches hatched 4–5 nights after being deposited in a nest. Mean notochord length of newly-hatched larvae was 1·88 mm (range 1·60–2·04). The minimum period of time that elapsed between egg deposition and subsequent growth of a new batch of oocytes to spawning size was 5–6 days, providing a reasonable estimate of minimum spawning interval. Compared with other gobiids, tropical species tend to have shorter incubation periods, smaller eggs and smaller larvae at hatching.     

Ontogeny of the gastrointestinal tract and selected digestive enzymes in cobia Rachycentron canadum (L.)

The ontogeny of the digestive system of cobia Rachycentron canadum from hatching to 22 days post-hatch (dph) (20·1 mm standard length) was examined with light microscopy. The activities of selected pancreatic enzymes were also determined during this period in order to optimize current rearing methods for this species. At hatching (3·6 mm), the digestive tract consisted of a relatively undifferentiated, straight tube positioned dorsally to the yolk sac. The major morphological changes in the digestive tract primarily occurred over the first 1–4 dph (3·6–4·4 mm). During this time, larvae began exogenous feeding (3 dph) and the digestive tract differentiated into five histologically distinct regions: buccopharynx, oesophagus, stomach anlage, anterior intestine and posterior intestine. Yolk reserves were exhausted by 5 dph (4·5 mm) and the oil globule began rapidly decreasing in size disappearing entirely by 9–10 dph (6·3–6·8 mm). Gastric glands differentiated at this time, and by 12 dph (8·1 mm) surface mucous cells of the stomach anlage stained positive for neutral mucosubstances. By 16 dph (11·6 mm), the blind sac (fundic region) of the stomach formed as did the pyloric caecae which initially appeared as a single protrusion of the anterior intestine just ventral to the pyloric sphincter. Generally, enzyme activities (U larva⁻¹) for amylase (0·0–1·8), chymotrypsin (0·0–7902·4), trypsin (0·2–16·6) and lipase (9·3–1319·0) were measurable at or soon after hatching and increased steadily from c. 8–22 dph (5·7–20·1 mm). The results of this study are discussed in terms of current and future weaning practices of this species.