KINETICS OF CELL PROLIFERATION IN THE PRE-IMPLANTED MOUSE EMBRYO IN VIVO AND IN VITRO

The cell proliferation of pre-implanted mouse embryos was investigated after development in vivo and in vitro. The studies were started at the pronuclear stage, 2 h post conception (p.c.) and continued until the hatching of blastocysts, 120–144 h p.c. The number of cell nuclei, the DNA content of each nucleus, the mitotic index and the labelling index were determined. From these data it was possible to calculate the length of the cell generation cycle and its various phases. With the exception of the first cell cycle the S-phase was constant. The G₁- as well as the G₂-phase varied in length during the different cell cycles. From 31–72 h p.c. the increase in cell number was exponential. After cultivation in vitro this increase was smaller than in vivo. At later periods the proliferation rate decreased with proceeding development. In late blastocysts most of the cells were in the G₁-phase. The development of the embryos was somewhat faster in vivo than in vitro. But in principle conditions were comparable.     

A COMPARISON OF IN VIVO AND IN VITRO STATHMOKINETIC METHODS FOR THE STUDY OF CELL PROLIFERATION IN HAMSTER ORAL EPITHELIA

Mitotic indices (MI) expressed as numbers of metaphase figures per 100 basal cells in the cheek pouch and palatal epithelium of the Syrian hamster following metaphase arrest with vinblastine sulphate (VLB) were compared using in vivo and in vitro techniques. The MI in vivo 4 1/2 hr after intraperitoneal injection of 4 mg VLB/kg body weight was 2·69 ± 0·37 for cheek pouch and 12·08 ± 1·09 for palate. MI in vitro was measured using small tissue explants cultured for 4 hr in medium supplemented with VLB at concentrations ranging from 6-600 μg/ml. The maximum MI for cheek pouch epithelium in vitro (2·7) did not differ significantly from that observed in vivo (P > 0·50) and was obtained in the presence of 12–30 μg VLB/ml, a concentration comparable with that used in vivo. In contrast, the maximum MI for palate epithelium in culture (5·6) was significantly lower than that in vivo (P < 0·001) and was only achieved in the presence of extremely high concentrations of VLB. Possible reasons are discussed for the discrepancy between the MI for palatal epithelium in vivo and in vitro.     

ANALYSIS OF THE PROLIFERATION KINETICS OF BURKITT'S LYMPHOMA CELLS

The in vitro proliferation kinetics of a cell line derived from a patient with American Burkitt's lymphoma were investigated at three different growth phases: lag (day 1), exponential (day 3) and plateau (day 5). The growth curve, labeling and mitotic indices, percentage labeled mitosis (PLM) curves and DNA content distributions were determined. The data obtained have been analysed by the previously developed discrete-time kinetic (DTK) model by which a time course of DNA distributions during a 10-day growth period was characterized in terms of other cell kinetic parameters. The mean cell cycle times, initially estimated from PLM curves on days 1, 3 and 5, were further analysed by the DTK model of DNA distributions and subsequently the mean cell cycle times with respect to DNA distributions during the entire growth period were determined. The doubling times were 39·6, 31·2 and 67·2 hr, respectively, at days 1, 3 and 5. The mean cell cycle time increased from 23·0 to 37·7 hr from day 3 to day 5 mainly due to an elongation of the G₁ and G₂ phases. A slight increase in the cell loss rate from 0·0077 to 0·0081 fraction/hr was accompanied by a decrease in the cell production rate from 0·0299 to 0·0184 fraction/hr. This calculated cell loss rate correlated significantly with the number of dead cells determined by trypan blue exclusion. Analysis of the number of dead cells in relation to the cell cycle stage revealed that a majority of cell death occurred in G₁ (r= 0·908; P < 0·0001). There was a good correlation between the in vitro proliferation kinetics at plateau phase of this Burkitt's lymphoma derived cell line and the in vivo proliferation kinetics of African Burkitt's lymphoma (Iversen et al., 1974), suggesting the potential utility of information obtained by in vitro kinetic studies.     

ON THE EXISTENCE OF A Go-PHASE IN THE CELL CYCLE

The model is based on the assumption that the cell cycle contains a G_o-phase which cells leave randomly with a constant probability per unit time, γ. After leaving the G_o-phase, the cells enter the C-phase which ends with cell division. The C-phase and its constituent phases, the‘true’G₁-phase, the S-phase, the G₂-phase and mitosis are assumed to have constant durations of T, T₁T_s, T₂ and T_m, respectively. For renewal tissue it is assumed that the probability per unit time of being lost from the population is a constant for all cells irrespective of their position in the cycle. The labelled mitosis curve and labelling index for continuous labelling are derived in terms of γ, T, and T_s. The model generates labelled mitosis curves which damp quickly and reach a constant value of twice the initial labelling index, if the mean duration of the G_o-phase is sufficiently long. It is shown that the predicted labelled mitosis and continuous labelling curves agree reasonably well with the experimental curves for the hamster cheek pouch if T has a value of about 60 hr. Data are presented for the rat dorsal epidermis which support the assumption that there is a constant probability per unit time of a cell being released from the Go-phase.     

DELAY OF CELL CYCLE PROGRESSION AFTER X-IRRADIATION OF SYNCHRONIZED POPULATIONS OF HUMAN CELLS (NHIK 3025) IN CULTURE

The effect of X-irradiation on the cell cycle progression of synchronized populations of the human cell line NHIK 3025 has been studied in terms of the radiation-induced delay of DNA replication and cell division. Results were obtained by flow cytometric measurement of histograms of cellular DNA content and parallel use of conventional methods for cell cycle analysis, such as pulse labelling with [³H]thymidine and counting of cell numbers. The two sets of methods were generally in good agreement, but the advantages of employing two independent techniques are pointed out. Irradiation was found to have a minor influence on DNA replication. As compared with unirradiated populations, half-completed DNA replication was 20-30 min delayed in populations given 580 rad in mid-G₁ or 290 rad in early S. Cell cycle progression was markedly delayed in G₂. The sensitivity induction of this delay was 0·6 min/rad for populations irradiated in mid-G₁, and 1·4 min/rad for populations irradiated in early S.     

Establishment and Growth Kinetics of the Mutant Ehrlich-Lettré Ascites Cell Strain Hd33 In Permanent Suspension Culture1,2

Cells of a mutant in vivo subline of the Ehrlich-Lettré mouse ascites tumour (ELAT) were converted to growth in suspension culture. Kinetic analysis revealed the selective character of the conversion process; without a detectable adaptation period, a fraction of about 2 × 10^-5 of the explanted cells continued to grow in vitro. the resulting, mutant Ehrlich-Lettré ascites cell strain was designated HD33 and propagated uninterruptedly from 1974 on. the corresponding in vivo ELAT subline HD33 was derived from the HD33 ascites cell strain by intraperitoneal retransplantation. In HD33 cell suspension cultures, the population doubling time, the average intermitotic interval, as determined by videomonitoring, and the average duration of the cell cycle, as determined from percentage of labelled mitoses (PLM) data, were all measured at 15 hr. Cell loss and quiescent compartments were insignificant. the duration of the G₁ phase was effectively zero. Both PLM data and [³H]/[¹⁴C] thymidine double-labetling measurements revealed an S-phase duration of between 11 and 12 hr. the G₂ phase lasted 3–5 hr. The HD33 strain differs from comparable suspension strains of wild-type Ehrlich ascites cells in the insignificant role of density-dependent inhibition in growth, and the striking prolongation of the S phase which is associated with an excessive, cytoplasmic storage of glycogen by the mutant cells.     

Cell proliferation in the subependymal layer of the adult mouse in vivo and in vitro

Pulse labelling experiments with [³H] thymidine (dT) and double labelling experiments with [³H]dT and bromodeoxyuridine (BrdUrd) were carried out on cells of the subependymal layer in the brain of adult normal mice in vivo, in vivo/in vitro and in vitro. The results should (i) lead to information about cell cycle parameters of these cells in the brain of adult mice, since these cells have been studied mostly in the rat brain up to now and (ii) answer the question whether results concerning cell proliferation obtained in vivo correspond with those from brain slices incubated in vitro with or without prelabelling in vivo. In vivo an LI of 20.2 ± 2.7% (x?± SEM) and T_s= 7.2 ± 0.7h were found. Furthermore, grain count halving experiments led to a surprisingly short cycle time (T_c) of 11.2–14.2 h. The longer T_c values (18–20 h) reported in the literature for subependymal cells in the rat brain seem to be due to evaluations of different areas around the lateral ventricle without considering the migrating behaviour of these cells which is quite different regionally. The in vitro studies (with or without prelabelling in vivo) showed a significantly reduced LI due to the fact that about 20% of the S phase cells, possibly lying in the middle of S, stopped further DNA synthesis after transfer to culture. This was shown by comparing the cell fluxes at the G₁/S and S/G₂ borders of in vivo vs. in vitro studies.     

EXISTENCE OF AN ENDOGENOUS INHIBITOR OF DNA SYNTHESIS IN RABBIT SMALL INTESTINE SPECIFICALLY EFFECTIVE ON CELL PROLIFERATION IN ADULT MOUSE INTESTINE

Aqueous extracts from rabbit organs were prepared by homogenization and centrifugation at 105,000 g . After precipitation with ammonium sulphate, the 0–50 fraction was separated by ultrafiltration through Amicon XM 100 and XM 300 membranes yielding two filtrate fractions (U₁ and U₂) and one retentate fraction (U₃). Only U₁ and U₃ inhibited thymidine incorporation into DNA. After a single injection of U₁ from rabbit small intestine, the uptake of tritiated thymidine was decreased in mouse jejunal and colonic DNA. This effect, totally reversible after 7 hr, was found in neither the kidney nor the testis. The U₁ fractions of colon and non-digestive organs (kidney, testis) were found not to exert a significant inhibition on thymidine incorporation into intestinal DNA in vivo. The U₃ fraction from rabbit small intestine also decreased the uptake of tritiated thymidine in mouse jejunal and colonic DNA in vivo. However, this inhibition was irreversible and not tissue-specific. Slowing of cell migration was also noticed in the jejunum of mice injected with U₁ or U₃, as ascertained radioautographically by determining the position of the leading edge of the labelled cells in U₁- or U₃-injected mice compared with controls. A decrease of mitotic activity in U₁- and U₃-injected mice was recorded 8·5 hr after a single injection of small intestinal fractions. Our results suggest that U₁ and U₃ from rabbit small intestine contain one or more substances which may act on the G₁—S transition of the cell cycle in the mouse intestine. However, only the effect of U₁ is reversible and tissue specific. Our data suggest the existence of a factor, having a low molecular weight, which regulates intestinal cell proliferation.     

Discrepancy between the initial DNA damage and cell survival after camptothecin treatment in two murine lymphoma L5178Y sublines

Two L5178Y (LY) murine lymphoma cell sublines, LY-R, resistant, and LY-S, sensitive, to X-irradiation display inverse cross-sensitivity to camptothecin (CPT): LY-R cells were more susceptible to this specific topoisomerase I inhibitor than LY-S cells. After 1 h incubation with CPT, the doses that inhibited growth by 50 per cent (ID₅₀) after 48 h of incubation were 0·54μM for LY-R cells and 1·25 μM for LY-S cells. Initial numbers of DNA–protein crosslinks (DPCs) measured at this level of growth inhibition were two-fold higher in LY-R (5·6 Gray-equivalents) than in LY-S cells (3·1 Gray-equivalents), which corresponds well with the greater in vitro sensitivity of Topo I from LY-R cells to CPT.^1,2 Conversely, the initial levels of single-strand DNA breaks (SSBs) and double-strand DNA breaks (DSBs) were lower in LY-R cells (4·2 Gray-equivalent SSBs and 5·8 Gray equivalent DSBs) than in LY-S cells (8·0 Gray-equivalent SSBs and 12·0 Gray-equivalent DSBs). Dissimilarity in the replication-dependent DNA damage observed after 1 h of treatment with CPT was not due to a difference in the rate of DNA synthesis between the two cell lines, but may have arisen from a substantially slower repair of DNA breaks in LY-S cells.³ Release from G₂ block by caffeine co-treatment significantly increased cell killing in the LY-S subline, and only slightly inhibited growth of LY-R cells. These results show that after CPT treatment cells arrest in G₂, allowing them time to repair the long-lived DSBs. As LY-S cells are slower in repairing the DSBs, they were more susceptible to CPT in the presence of caffeine.     

Latitudinal and altitudinal growth patterns of brown trout Salmo trutta at different spatial scales

Spatial variation in growth of stream‐dwelling brown trout Salmo trutta was explored in 13 populations using a long‐term study (1993–2004) in the Bay of Biscay drainage, northern Spain. The high variability in fork length (L_F) of S. trutta in the study area was similar to the body‐size range found in the entire European distribution of the species. Mean L_F at age varied: 0+ years, 57·4–100·7 mm; 1+ years, 111·6–176·0 mm; 2+ years, 155·6–248·4 mm and 3+ years, 194·3–290·9 mm. Average L_F at age was higher in main courses and lower reaches compared with small tributaries and upper reaches. Annual specific growth rates (G_L) were: 0+ to 1+ years, 0·634–0·825 mm mm⁻¹ year⁻¹; 1+ to 2+ years, 0·243–0·342 mm mm⁻¹ year⁻¹; 2+ to 3+ years, 0·166–0·222 mm mm⁻¹ year⁻¹, showing a great homogeneity. Regression models showed that water temperature and altitude were the major determinants of L_F at age variability within the study area. A broader spatial analysis using available data from stream‐dwelling S. trutta populations throughout Europe indicated a negative relationship between latitude and L_F of individuals and a negative interaction between latitude and altitude. These findings support previous evidence of the pervasive role of water temperature on the L_F of this species. Altitude appeared as the overall factor that includes the local variation of other variables, such as water temperature or food availability. At a larger scale, latitude was the factor that encompassed these environmental gradients and explained the differences in L_F of S. trutta. In summary, L_F at age in stream‐dwelling S. trutta decreases with latitude in Europe, the converse of Bergmann's rule.     

Combined flow and absorption DNA measurements of [3H]TdR-labelled tumour cells. I. Studies of MCa-11 cells grown as tumours in vivo and as exponential cultures in vitro*

Abstract. Flow cytometry of cellular DNA content provides rapid estimates of DNA distributions, i.e. the proportions of cells in the different phases of the cell cycle. Measurements of DNA alone, however, yield no kinetic information and can make it difficult to resolve the cell cycle distributions of normal and transformed cells present in tumour biopsy specimens. The use of absorption cytophotometry of the Feulgen DNA content and [³H]TdR labelling of the same nuclei provides objective criteria to distinguish the ranges of DNA content for G₀/G₁, S, and G₂/M cells. We now report on a study in which we combined flow and absorption cytometry to resolve the cell cycle distributions of host and tumour cells present in biopsy specimens of MCa-11 mouse mammary tumours labelled in vivo for 0.5 hr with [³H]TdR. A similar analysis of exponential monolayer cultures, labelled for 5 min with [³H]TdR under pulse-chase conditions, revealed a highly synchronous traversal of almost all cells through the different phases of the cell cycle. Combination of the flow and absorption methods also allowed us to detect G₂ tumour cells in vivo and a minor tumour stem-line in vitro, to show that these two techniques are complementary and yield new information when they are combined.     

STUDIES ON THE REGULATION OF LYMPHOCYTE PRODUCTION IN THE MURINE THYMUS AND SOME EFFECTS OF A CRUDE THYMUS EXTRACT

Cell proliferation in the murine thymus was studied in vivo under normal conditions and from 0 to 24 hr after a single injection of a water-soluble extract from mouse thymus, mouse spleen, and mouse skin. The thymus extract reduced during the first 24 hr the mitotic activity 40%; the spleen extract had a weaker inhibitory effect. The skin extract had no such effect. The thymus extract and spleen extract inhibited the flux of cells into the S phase 0–8 hr after the injection of the extract. Initial labelling index was also reduced in this period. Eight hours after injection of the thymus or spleen extracts the inhibited cells initiated DNA synthesis. The rate of progression of blast cells through the cell cycle was normal 24 hr after the injection of the extracts. It was deduced from the analysis that the thymus extract inhibits processes triggering Go/Gi cells into DNA synthesis, the inhibition of G₂ efflux being of minor importance. Finally a model for the regulation of proliferating thymic blast cells and the emigration of small lymphocytes from the thymus is proposed.     

Protein affinity chromatography reveals cell cycle dependent association of cellular factors with human DNA polymerase α

DNA polymerase α/primase (Polα) is the key replication enzyme in eukaryotic cells. This enzyme synthesizes and elongates short RNA primers at an unwound origin of replication. Polα was used as an affinity ligand to identify cellular replication factors interacting with it. Protein complexes between Polα and cellular factors were analyzed by co-immunoprecipitations with monoclonal antibodies directed against Polα and by protein affinity chromatography of cell extracts derived from pure G₁-and S-phase cell populations on Polα affinity columns. Co-immunoprecipitations resulted in the identification of a polypeptide with a molecular weight of 46 kDa. For Polα affinity chromatography, the ligand was purified from insect cells infected with a recombinant baculovirus encoding the catalytic subunit (p180) of Polα (Copeland and Wang, 1991). With 5×10⁸ infected Sf9 cells, a rapid one step purification protocol was used which yielded in five hours 0.6 mg pure enzyme with a specific activity of 140,000 units/mg. The G₁-and S-phase cell populations were generated by block, release and counterflow centrifugal elutriation of exponentially growing human MANCA cells. Starting with 2×10⁹ non synchronous cells, 5×10⁸ G₁-phase cells were isolated. Chromatography of cell extracts derived from G₁-or S-phase cells on Polα affinity columns resulted in identifying several polypeptides in the range of 40–70 kDa. Some of these polypeptides are more abundant in eluates derived from S-phase extracts than from G₁-phase extracts.     

SPECIFIC INHIBITION OF CELL PROLIFERATION IN THE MOUSE INTESTINE BY AN AQUEOUS EXTRACT OF RABBIT SMALL INTESTINE

An aqueous extract was prepared from the mucosa of rabbit small intestine by homogenization and centrifugation at 105,000 g. After precipitation with ammonium sulfate, the 0–50 fraction (F₁) and the supernatant (F₂) were collected, dialysed against a phosphate buffer and tested on rats in vitro and mice in vivo. The F₁ fraction was found to inhibit thymidine incorporation into rat intestinal DNA in vitro, but this effect was not found to be tissue specific (liver, kidney). Two hours after a single injection of F₁ (10 mg protein content), the uptake of tritiated thymidine was decreased in jejunal and colonic DNA in mice. This effect was maximal between 2 and 4 hr and totally reversible after 7 hr; this effect was found in neither the kidney nor the testis. A slowing of cellular migration was also noticed in the jejunum and the colon. Conversely, the F₂ fraction did not inhibit the synthesis of jejunal and colonic DNA either in vitro or in vivo. Our results suggest that the F₁ fraction of the aqueous extract of rabbit small intestine contains one or more substances which may act either on intestinal DNA synthesis or on the G₁–S transition of the cellular cycle in the mouse intestine. This reversible and specific intestinal action appears to inhibit cell proliferation and presents several of the characteristics defining a chalone.     

ANALYSIS OF PROLIFERATION AND DIFFERENTIATION OF FOETAL GRANULOCYTE-MACROPHAGE PROGENITOR CELLS IN HAEMOPOIETIC TISSUE*

Analysis of in vitro colony formation in agar cultures of foetal haemopoietic tissues of eight mammalian species has shown that granulocyte-macrophage progenitor cells are present in foetal liver, yolk sac, marrow and spleen in numbers approaching the incidence in adult marrow. Such characteristics as buoyant density, growth rate and differentiation served to distinguish foetal from adult colony forming cells (CFCs). Cell cycle analysis performed by exposing haemopoietic cells to high doses of tritiated thymidine in vitro showed that foetal CFC proliferation in species of short gestation (rabbit, rat, mouse) approached or exceeded that observed in adult marrow. In contrast, in species of long gestation (human, monkey, calf, lamb, guinea-pig) a period of variable duration was observed when foetal liver CFCs entered a non-cycling G₀ or blocked G₁ phase. In these species foetal liver CFCs were found to be proliferating actively early in gestation and following the non-cycling phase again re-entered a proliferative state associated with onset of active granulopoiesis in foetal marrow and possible migration of CFC from liver to marrow. These results indicate the existence of granulocyte-macrophage progenitor populations displaying foetal characteristics and adapted to particular stages of haemopoietic development, a situation which closely parallels that reported for erythropoiesis.     

The fine structure of peritrophic membranes of the blowfly, Calliphora erythrocephala, grown in vitro under different conditions.

The formation of peritrophic membranes (PM) in vitro was studied in a flow chamber in order to avoid the accumulation of metabolic substances during prolonged incubation. During the first 8 to 10 hr of incubation the production of PM was nearly constant—3·5 ± 1·4 mm PM/hr. After about 10 hr it decreased and stopped after about 35 hr. Between 1 and 8 hr after the beginning of incubation the width of the periodic crossband pattern reached or nearly reached the values found in PM which had formed in vivo; afterwards it decreased more and more. During the first 20 min of incubation a ‘disturbed zone’ of PM without any regular crossband pattern is formed.In the cardia of adult Calliphora erythrocephala there are three formation zones forming three PM of different fine structures. The fine structure of PM 1 to 3 formed in vitro during the first 6 to 8 hr of incubation in Leloup's medium 1, with an osmolarity of 340 mOsmol, a pH of 6·8, and a temperature of 27°C, does not differ from the PM grown in vivo. PM 1–3 grown in vitro in Tyrode's solution with added glutamine or in Leloup's medium with added β-ecdysone show a considerable increase in thickness and a disturbed formation of the electron dense layer of PM 1.     

ATP-driven proton pumping in two species of Chara differing in salt tolerance

Chara corallina is an obligate freshwater alga, while C. buckellii can be grown in salt and freshwater culture. When grown in fresh water, C. buckellii has electrophysiological properties similar to C. corallina, but when cultured in salt water, it has a less negative membrane potential and has a higher conductance. We show in internally perfused, tonoplast-free cells that the ATP-dependence of the two species cultured in fresh water is similar, although C. buckellii hyperpolarizes at lower ATP concentrations. We determined the pump parameters in perfused and intact cells. Using both techniques, C. corallina and C. buckellii cultured in fresh water show similar values of E_p, G_p and I_p. However, there is a significant difference between the two techniques: E_p is more negative (–400 to –700 mV) in perfused cells than in intact cells (–220 to –260mV); G_p is lower (0·1–0·2 versus 0·3–0·9 S m^?2); and I_p is higher (40–60 versus 10–18 mA m^?2). Salt-cultured C. buckellii was compared with freshwater C. buckellii using intact cells; G_p and E_p were similar, but I_p was much higher in salt-cultured cells (60 versus 15mA m^?2). This higher pump rate is due to the depolarization of the membrane of salt-cultured algae, which is caused by a higher passive conductance. The significance of the less negative membrane potential and the higher rate of proton pumping is discussed with respect to the banding pattern and salt stress.     

Population structure of the olive flounder (Paralichthys olivaceus) in Korea inferred from microsatellite marker analysis

The population structure of olive flounder Paralichthys olivaceus was estimated using nine polymorphic microsatellite (MS) loci in 459 individuals collected from eight populations, including five wild and three hatchery populations in Korea. Genetic variation in hatchery (mean number of alleles per locus, A = 10·2–12·1; allelic richness, A_R = 9·3–10·1; observed heterozygosity, H_O = 0·766–0·805) and wild (mean number of alleles per locus, A = 11·8–19·6; allelic richness, A_R = 10·9–16·1; observed heterozygosity, H_O = 0·820–0·888) samples did not differ significantly, suggesting a sufficient level of genetic variation in these well‐managed hatchery populations, which have not lost a substantial amount of genetic diversity. Neighbour‐joining tree and principal component analyses showed that genetic separation between eastern and pooled western and southern wild populations in Korea was probably influenced by restricted gene flow between regional populations due to the barrier effects of sea currents. The pooled western and southern populations are genetically close, perhaps because larval dispersal may depend on warm currents. One wild population (sample from Wando) was genetically divergent from the main distribution, but it was genetically close to hatchery populations, indicating that the genetic composition of the studied populations may be affected by hydrographic conditions and the release of fish stocks. The estimated genetic population structure and potential applications of MS markers may aid in the proper management of P. olivaceus populations.     

DURATION OF CELL CYCLES IN CULTURED ROOTS OF CONVOLVULUS

The durations of the cell cycle in physiologically different regions of the meristem of cultured roots of Convolvulus arvensis were determined by the metaphase-accumulation technique involving colchicine. The cell cycle in the root cap increases from 13 hr in the actively dividing initials of the first tier to 155 hr in the slowly dividing initials of tiers 2–4 to an indeterminate value for derivatives of the initials in the root cap columella. The cycle times for the cells of the central cylinder and cortex are 21 and 27 hr, respectively. The cells of the quiescent center have a cycle of an estimated 420 hr. The duration of the cell cycle in these different regions is discussed in relation to the increased duration of G₁ in slowly or non-dividing cells. The possible regulation of cell division by the synthesis of a cell-division factor in the quiescent center is also discussed.     

5-AMINOURACIL TREATMENT : A Method for Estimating G2

Treatment of Vicia faba lateral roots with a range of concentrations of 5-aminouracil (5-AU) indicate that cells are stopped at a particular point in interphase. The timing of the fall in mitotic index suggests that cells are held at the S - G₂ transition. When cells are held at this point, treatments with 5-AU can be used to estimate the duration of G₂ + mitosis/2 of proliferating cells. Treatment with 5-AU can also be used to demonstrate the presence of subpopulations of dividing cells that differ in their G₂ duration. Using this method, 5-AU-induced inhibition, we have confirmed that in V. faba lateral roots there are two populations of dividing cells: (a) a fast-dividing population, which makes up ~85% of the proliferating cell population and has a G₂ + mitosis/2 duration of 3.3 hr, and (b) a slow-dividing population, which makes up ~15% of dividing cells and has a G₂ duration in excess of 12 hr. These estimates are similar to those obtained from percentage labeled mitosis (PLM) curves after incorporation of thymidine-³H.