Interference of a synthetic C18 juvenile hormone with mammalian cells in vitro, I. Effects on growth and morphology

Some of structural and functional analogs of juvenile hormones are now under field examinations as growth inhibitors of some pest-insect populations. So far however very little is known about the possible interference of these compounds with mammalian cells or organisms. In this research the interference of a synthetic preparation of the insect C18 juvenile hormone with mouse embryo fibroblasts (ME-cells) and mouse cells of an established line (L-cells) was studied. Aliquots of juvenile hormone solution or those of the solvent (DMSO plus ethanol, 9:1) were included into the culture medium and after defined times of contact the cells were tested for their morphology, pattern of growth, proliferation rate and viability. The data for the parameters under examination were evaluated by means of the analysis of variance and checked by the Tuckey test. The sensitivity of ME-cells and L-cells to the agent tested was compared by means of the analysis of variance of the data for mitotic indices of these cells and by evaluation of the number of dead cells in cultures under the particular conditions of the experiments. The main findings can be summarized as follows: 1. Cells of both types are evidently more sensitive to juvenile hormone than to the solvent. 2. ME-cells are more sensitive to both agents than are L-cells. 3. The concentrations of the hormone in the medium required to evoked the cytocidal effect on the mouse cells similarly as those affecting some insect non-target cells were far above concentrations found in insect blood, but they were of the same order of magnitude as those used in physiological experiments with insect organs in vitro.     

Regenerative proliferation of mouse epidermal cells following adhesive tape stripping. Micro-flow fluorometry of isolated epidermal basal cells combined with 3H-TdR incorporation and a stathmokinetic method (colcemid).

The proliferating cells of mouse epidermis (basal cells) can be separated from the non-proliferating cells (differentiating cells) Laerum, 1969) and brought into a monodisperse suspension. This makes it possible to determine the cell cycle distributions (e.g. the relative number of cells in the G1, S and (G1 + M) phases of the cell cycle) of the basal cell population by means of micro-flow fluorometry. To study the regenerative cell proliferation in epidermis in more detail, changes in cell cycle distributions were observed by means of micro-flow fluorometry during the first 48 hr following adhesive tape stripping. 3H-TdR uptake (LI and grain count distribution) and mitotic rate (colcemid method) were also observed. An initial accumulation of G2 cells was observed 2 hr after stripping, followed by a subsequent decrease to less than half the control level. This was followed by an increase of cells entering mitosis from an initial depression to a first peak between 5 and 9 hr which could be satisfactorily explained by the changes in the G2 pool. After an initial depression of the S phase parameters, three peaks with intervals of about 12 hr followed. The cells in these peaks could be followed as cohorts through the G2 phase and mitosis, indicating a partial synchrony of cell cycle passage, with a shortening of the mean generation time of basal cells from 83-3 hr to about 12 hr. The oscillations of the proportion of cells in G2 phase indicated a rapid passage through this cell cycle phase. The S phase duration was within the normal range but showed a moderate decrease and the G1 phase duration was decreased to a minimum. In rapidly proliferating epidermis there was a good correlation between change in the number of labelled cells and cells with S phase DNA content. This shows that micro-flow fluorometry is a rapid method for the study of cell kinetics in a perturbed cell system in vivo.     

Long duration of mitosis and consequences for the cell cycle concept, as seen in the isthmal cells of the mouse pyloric antrum. II. Duration of mitotic phases and cycle stages, and their relation to one another

The kinetics of isthmal cells in mouse antrum were examined in three ways: the duration of cell cycle and DNA-synthesizing (S) stage was measured by the 'fraction of labelled mitoses' method; the duration of interphase and mitotic phases was determined from how frequently they occurred; and mice were killed at various intervals after an intravenous injection of 3H-thymidine to time the acquisition of label by the various phases of mitosis. The duration of the isthmal cell cycle was found to be 13.8 hr and that of the DNA-synthesizing (S) stage, 5.8 h. Estimates for the duration of the G1 and G2 stages were 6.8 and 1.0 hr, respectively. From the frequency of mitotic phases, defined as indicated in the preceding article (El-Alfy & Leblond, 1987) and corrected for the probability of their occurrence, it was estimated that prophase lasted 4.8 hr; metaphase, 0.2 hr; anaphase, 0.06 hr and telophase, 3.3 hr, while the interphase lasted 5.4 hr. In accordance with this, the duration of the whole mitotic process was 8.4 hr. Ten minutes after an intravenous injection of 3H-thymidine, 38% of labelled isthmal cells were in interphase and 62% in early or mid prophase, while cells in late prophase and other mitotic phases were unlabelled. After 60 min, label was in late prophase, after 120 min, in mid telophase and after 180 min, in late telophase. We conclude that there is overlap between some mitotic phases and cycle stages. Thus, while nuclei are at interphase during the early third of S, they are in prophase during the late two-thirds as well as during G2. Also, nuclei are in telophase during the early half of G1 but at interphase during the late half. Differences in nuclear diameter show that subdivision of both S and G1 into early and late periods is practical.     

Kinetics of the calcium induced stratification of human keratinocytes in vitro

In a low concentration of calcium (0.1 mM), keratinocytes form a monolayer with about 30% of cells synthesizing involucrin. After addition of calcium to the culture medium to a concentration of 1.2 mM, the monolayer stratifies within 24 h, with a preferential migration of involucrin positive keratinocytes. In the present study, we tried to determine if keratinocytes control the decision to migrate at a distinct cell cycle point. A percentage labelled mitosis (PLM) curve was constructed for keratinocytes grown in low calcium medium and values for the length of the cell cycle (47 h), S phase duration (11 h) and G2+M period (6 h), were obtained. Monolayer cultures at 80% confluence were switched to high calcium concentration at various times (from 0 to 48 h), after pulse labelling with [3H]-thymidine. Based on the PLM data, the behaviour of cells known to be in S, G1 and G2 at the time of the migration stimulus were followed. No significant difference in the percentage of labelled suprabasal cells was found for any point of the cell cycle. For cells submitting to stratification, in S phase involucrin staining showed that about 60% of the [3H]-thymidine labelled cells were also involucrin negative. These results indicate that upward migration of keratinocytes in cultured epithelium can be triggered at all points in the cell cycle with equal probability and is not restricted to those cells that already contained involucrin.     

Inhibitors of ester hydrolysis as synergists for biological activity of Cecropia juvenile hormone.

In Manduca sexta pupae the sensitivity to exogenous Cecropia C18 juvenile hormone (JH) is governed in large part by the rate at which the hormone is metabolized. By analysing the distribution of labelled JH and its metabolites, when dispensed by injection in light mineral oil, I have shown that the half-life of JH at concentrations ranging from 0·02 to 1 μg/g live weight of insect is approximately 24 hr.When the same doses of JH are dispensed in mineral oil containing endocrinologically inactive carboxylesterase inhibitors, organophosphate, and carbamate insecticides, the hormone's half-life in certain cases is prolonged significantly. The formulations containing those materials which most effectively prolong the hormone's half-life give higher assay scores than equivalent doses of hormone in mineral oil alone.From these results it is inferred that the chemicals tested synergize the Cecropia juvenile hormone's biological activity by serving presumably as inhibitors of the principal enzyme responsible for the rapid breakdown of exogenous C18-JH in haemolymph—a carboxylesterase. Preliminary in vitro experiments with carboxylesterase-rich Manduca pupal blood further support this inference.     

Changes in lysosomal enzyme activity in the mitotic cycle of L cells

Activities of lysosomal enzymes (acid phosphatase, N-acetyl-beta-D-glucosaminidase, acid lipase and cathepsin D) have been examined in a synchronized culture of mouse L-fibroblasts. Cell synchronization was achieved by the double thymidine block with a subsequent mitotic selection after colcemid treatment. Specific activities of the enzymes studied were found to be higher in S-G2 that in G1. There is a linear increase (approximate doubling) in enzyme activities per cell from G1 to M. Activity of galactosyltransferase, a marker of the Golgi apparatus, declined in mitotic cells in comparison with the interphase cells. Ultrastructural examination of L-cells revealed a reduction of the intracellular membrane system including the Golgi apparatus during mitosis. Changes in the Golgi apparatus activity have been considered as a possible regulatory point of lysosome formation. The data presented are compared with the results of morphological studies of lysosomal system in L-cells.     

Ultrastructural labeling of cell surface lectin receptors during the cell cycle.

The distribution of specific surface receptors in the course of the cell cycle has been studied on two transformed cell lines by means of ultrastructural labelling techniques employing Concanavalin A (ConA) and wheat germ agglutinin (WGA). Synchronized cultures of Cl₂TSV₅, an SV40-transformed hamster cell line and of CHO cells were labelled as monolayers or in suspension in the different phases of the cell cycle. In cells labelled in monolayers, a moderately discontinuous pattern of surface labelling was present during G 1, S, and G 2. On cells in mitosis, however, this pattern changes strikingly and becomes very discontinuous. These results indicate that the degree of receptor clustering is greater in mitosis than in interphase. In cells labelled in suspension, the differences in pattern between mitosis and interphase were absent. Colcemid treatment did not modify the distribution of the label, either in interphase or in mitosis. Moreover, cells in mitosis collected by Colcemid treatment and labelled at a moment in which parallel unblocked cultures had completed mitosis and passed into G 1 showed an interphase-type labelling pattern; this indicates that a certain dissociation exists between surface events and nuclear events during mitosis. These results are discussed in terms of several factors that may contribute to the production of receptor clustering, namely, direct lectin action, surface movement and membrane flow, participation of cytoplasmic structures and, finally, attachment of cells to a substratum.     

A new analytical method for determining duration of phases, rate of DNA synthesis and degree of synchronization from flow-cytometric data on synchronized cell populations.

L-cells synchronized by mitotic selection were investigated by flow-cytometry and the fractions of cells in the various cell cycle compartments were determined as a function of time. A new analytical evaluation procedure was developed, by which the mean transit-times of cells through various cell cycle phases can be calculated from these data. Three examples for application of the method are presented: (1) determination of the duration of G1, S, G2 + M and of the whole cell cycle; (2) calculation of the rate of DNA synthesis in several subcompartments of the S-phase; and (3) evaluation of the degree of synchronization at different stages of the cell cycle.     

In vitro metabolism of juvenile hormone III and juvenile hormone III bisepoxide by Drosophila melanogaster and mammalian cytosolic epoxide hydrolase

In vitro metabolism of juvenile hormone III (JH III) and juvenile hormone III bisepoxide was investigated using purified mouse liver cytosolic epoxide hydrolase (cEH) and cell fractions from Drosophila melanogaster. JH III was metabolized faster than JH III bisepoxide by epoxide hydrolase activity in D. melanogaster cell fractions and by cEH. After incubation with JH III bisepoxide, all cell fractions and cEH produced epoxy-diol, cis- and trans-tetrahydrofuran-diols, and tetraol as metabolites. An increase in the concentration of cEH resulted in an increase in the proportion of tetraol as a JH III bisepoxide metabolite but this trend was not observed in the D. melanogaster cell fractions. Differences between cell fractions in the metabolism of JH III and JH III bisepoxide suggests the presence of juvenile hormone epoxide hydrolase isozymes.     

The presence of parvalbumin in a nonmuscle cell line attenuates progression through mitosis

Based on studies that have examined the effect of calcium chelators on cells, it has been proposed that this cation plays a role in regulating cell proliferation. In this study a novel approach was used to indirectly examine the role of calcium in cell cycle progression. A cDNA for the Ca2+-binding protein parvalbumin has been expressed in mouse C127 cells, using a bovine papilloma virus-based expression vector. The normal role of parvalbumin is that of a calcium buffer in vertebrate fast twitch muscle, and the C127 cells do not normally express this protein. The presence of parvalbumin had several effects on the growth of C127 cells. The most striking phenotype was an increase in cell cycle duration which analysis showed was the result of an increase the length of G1 and mitosis (predominantly at prophase). Since changes in cell cycle duration typically occur as a result of changes in G1 duration, the observed increase in the length of mitosis is most unusual. The present results indicate that the previously observed increase in the rate of cell proliferation in cells with elevated calmodulin levels is not the result of a general increase in the level of cytoplasmic calcium-binding protein, but is specific to calmodulin. In addition, the results suggest that calcium regulates progression through mitosis by both calmodulin-dependent (metaphase transition) and -independent (prophase) mechanisms.     

Premature chromosome condensation and cell cycle analysis.

The application of the phenomenon of premature chromosome condensation for cell cycle analysis in HeLa and CHO cells has been examined. Random populations of HeLa and CHO cells pulse labelled with H3-TdR were separately fused with mitotic HeLa cells using U.V. inactivated Sendai virus. The resulting prematurely condensed chromosomes (PCC) were scored and classified into G1, S and G2-PCC on the basis of both morphological and autoradiographic data, The results of this study indicated that the G1, S and G2 phase cells are equally susceptible to virus-induced fusion with mitotic cells and subsequent induction into PCC. Hence the PCC method for cell cycle analysis is both practical and accurate. This study also revealed that the process of chromosome decondensation initiated during the telophase of mitosis continues throughout the G1 period reaching an ultimate state of decondensation by the end of G1, at which point the fusion of such cells with those in mitosis yield PCC with the most diffused morphology instead of the discrete single stranded structures characteristic of early G1-PCC. Thus, the decondensation of chromatin during G1 appears to be a prerequisite for the subsequent initiation of DNA synthesis.     

Control of cell progression through the mitotic cycle by carbohydrate provision. I. Regulation of cell division in excised plant tissue

A stationary phase in the root meristem of excised pea roots was established by prolonged carbohydrate deprivation in sterile culture medium. When the stationary phase had been established, cells that had collected in the G1 period of the mitotic cycle were induced to enter the S stage by subjection to relatively short intervals of carbohydrate provision (sucrose spurts). Progression and cycle location of the G1 cells induced to enter S were measured with tritiated thymidine and radioautography. The results indicated that the number of G1 cells induced to enter S increased directly with the spurt duration and that cells could be positioned and retained in the S and/or G2 periods by varying the duration of the spurt. The data support the hypothesis that S and maybe M stages have a relatively larger dependence on carbohydrate availability, and presumably a greater energy requirement, than G1 and G2.     

Synthesis and secretion of light-chain immunoglobulin in two successive cycles of synchronized plasmacytoma cells

Suspension-cultured mouse plasmacytoma cells (MPC-11) were accumulated in the late G1 phase by exposure to isoleucine-deficient medium for 20- 24 h. The arrested culture was fed with complete medium enabling the cells to continue the cell cycle synchronously, undergo mitosis, and enter a second cycle of growth. This method of synchronization left the protein-synthesizing ability intact as judged by the polysome profile and the capacity of the cells to incorporate labeled amino acids into protein after the restoration of isoleucine. After incubation in isoleucine-deficient medium and the addition of isoleucine to the culture, cells entered the S phase after a short lag, as judged by [3H]thymidine incorporation into nucleic acid and by spectrophotometric measurement of nuclear DNA. The cells were in mitosis between 12 and 18 h as judged by the increase in cell count and analysis of cell populations on albumin gradients. Synthesis and secretion of light- chain immunoglobulin were maximal in the late G1/early S phase of the first cycle. During late S phase, G2 phase, and mitosis, both synthesis and secretion were observed to be at a low level; however, immediately after motosis the cells which then entered the G1 phase apparently commenced synthesis of light chain immunoglobulin straight away, although secretion of labeled material remained at a low level.     

Cell proliferation kinetics in two human tumors grown in athymic nude mice.

The technique of labelled mitoses was used to investigate the cell proliferation kinetics in two human neoplasms, one a malignant melanoma and one a fibrosarcoma, transplanted to and grown serially in the athymic nude mutant (ANM) mouse. The experimental data obtained codrealted well with a theoretical percentage labelled mitoses curve based on the assumption that the time spent by a cell in each of the phases M, G1, S and G2 is described by four independent log-normal distributions. However, no unique second wave was defined by the experimental results. This means that only the deductions made about the duration of the G2 and S phases are reliable. The median duration of tma and the fibrosarcoma, respectively. By comparing these results with results published on cell cycle studies of transplantable animal tumors and human tumors in situ, it is concluded that the cell cycle parameters of a human tumor grown in the ANM mouse are close to those of the same tumor in the donor patient.     

Cell cycle parameters inAedes albopictus mosquito cells

Summary We have analyzed cell cycle parameters for theAedes albopictus C7-10 mosquito cell line, which has been systematically developed for somatic cell genetics, expression of transfected genes, and synthesis of hormone-inducible proteins. In rapidly cycling cells, we measured a generation time of 10–12 h. The duration of mitosis (M) was ≤1 h, and the DNA synthesis phase (S) required 6 h. UnlikeDrosophila melanogaster Kc cells, in which the G2 gap is substantially longer than G1, in C7-10 cells G1 and G2 each lasted approximately 2h. In these cells, the duration of both S and G2 was independent of the population doubling time, and the increase in population doubling time as cells approached confluency was due to prolongation of G1. When treated with the insect steroid hormone, 20-hydroxyecdysone, C7-10 mosquito cells complete the cycle in progress before undergoing a reversible arrest.     

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

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

Synthesis and secretion of albumin by a synchronized rat hepatoma cell line.

The rat hepatoma cell H4-12 which synthesizes and secretes albumin was synchronized by growth in isoleucine-deficient medium followed by a second block with excess thymidine. Albumin synthesis and secretion was measured in the synchronized cells at different time intervals representative of early S, late S, G2, mitosis, early G1 and late G1 phases of the cell cycle. Maximal albumin synthesis occurred during G1 although significant synthesis also occurred during the other cell cyle phases. Most (75--80%) of the radioactive albumin produced during a 15 min pulse incubation with L-[4,5-3H] leucine was found in the microsomal cell fraction and this nascent albumin was secreted into the incubation medium during a 160 min chase period. Fifty percent of the nascent albumin was secreted by 50--55 min and this pattern of secretion did not change during the cell cycle. These data indicate that albumin synthesis occurs throughout the cell cycle but that it is preferred during G1. The rate of intracellular transport and secretion of albumin does not vary during the different phase of the cell cycle.     

The role of protein metabolism in glucocorticoid-lnduced prolongation of G1 phase in human NHIK 3025 cells

It has previously been found that human NHIK 3025 cells have a glucocortiocoid-sensitive restriction point in mid-G1 phase of the cell cycle. When these cells were synchronized by mitotic selection and exposed to dexamethasone before the restriction point, G1 phase was prolonged whereas the rest of the cell cycle was unperturbed by the hormone. These observations were confirmed by flowcytometric mesurements of synchronized cells in the present study. Cells that received dexamethasone (10^?6 M) just after mitotic selection had a 4 hour prolongation of both G1 and the total cell cycle. However, the general rates of both protein synthesis and protein degradation were found not to be altered by the hormone, i.e., the rate of protein accumulation in dexamethasone exposed cells was equal to that of control cells. Dexamethasone exposed NHIK 3025 cells were found to be larger than control cells at the time of cell division. This is a direct consequence of a prolonged cell cycle duration with no change in general protein metabolism. It thus appears that the dexamethasone-induced prolongation of G1 phase is the result of a steroid-regulated G1 specific process(es) leading toward DNA replication, a process that does not alter general protein accumulation.     

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.     

Long duration of mitosis and consequences for the cell cycle concept, as seen in the isthmal cells of the mouse pyloric antrum. II. Duration of mitotic phases and cycle stages, and their relation to one another

Abstract. The kinetics of isthmal cells in mouse antrum were examined in three ways: (a) the duration of cell cycle and DNA-synthesizing (S) stage was measured by the 'fraction of labelled mitoses' method; (b) the duration of interphase and mitotic phases was determined from how frequently they occurred; and (c) mice were killed at various intervals after an intravenous injection of ³H-thymidine to time the acquisition of label by the various phases of mitosis.
The duration of the isthmal cell cycle was found to be 13.8 hr and that of the DNA-synthesizing (S) stage, 5.8 h. Estimates for the duration of the G₁ and G₂ stages were 6.8 and 1.0 hr, respectively.
From the frequency of mitotic phases, defined as indicated in the preceding article (El-Alfy & Leblond, 1987) and corrected for the probability of their occurence, it was estimated that prophase lasted 4.8 hr; metaphase, 0.2 hr; anaphase, 0.06 hr and telophase, 3.3 hr, while the interphase lasted 5.4 hr. In accordance with this, the duration of the whole mitotic process was 8.4 hr.
Ten minutes after an intravenous injection of ³H-thymidine, 38% of labelled isthmal cells were in interphase and 62% in early or mid prophase, while cells in late prophase and other mitotic phases were unlabelled. After 60 min, label was in late prophase, after 120 min, in mid telophase and after 180 min, in late telophase.
We conclude that there is overlap between some mitotic phases and cycle stages. Thus, while nuclei are at interphase during the early third of S, they are in prophase during the late two-thirds as well as during G₂. Also, nuclei are in telophase during the early half of G₁ but at interphase during the late half. Differences in nuclear diameter show that subdivision of both S and G₁ into early and late periods is practical.