Some Factors Governing Feeding Behavior of Homalozoon vermiculare (Ciliophora, Holotricha)

SYNOPSIS. Feeding activity of Homalozoon vermiculare on Paramecium and Blepharisma and on a number of non-living materials was compared in order to understand its feeding behavior and some of the factors governing it. During a given period it involves a series of feeding responses, each response being completed in 5 stages: (i) contact of prey or non-living particles with the oral rim of Homalozoon, (ii) ejection of toxin by Homalozoon, if the food is a living organism, (iii) paralysis of the prey, (iv) grasping, and (v) swallowing. The feeding activity of Homalozoon differs from one food to another and also on any one food at different times. These differences are governed by (i) the physiologic condition of Homalozoon and (ii) certain food characteristics. Its starvation, but not its developmental stage, markedly influences its feeding activity on any food. The food characteristics most important for feeding by Homalozoon are: (i) concentration of prey or non-living particles in the medium, insuring their adequate contact with the organism's mouth, (b) susceptibility of living organisms to paralysis by the toxin, (c) suitability of particle size for accommodation in the organism's mouth, and (d) suitability of the food material to stimulate the grasping and swallowing responses. Homalozoon much prefers Paramecium to Blepharisma on account of (i) a greater susceptibility of Paramecium to paralysis by the toxin, and (ii) certain differences in the chemical characteristics of the certain proteins, particularly albumins, hemoglobin, etc., of the 2 organisms.     

The Role of Microtubules in Macronuclear Division of Blepharisma*

SYNOPSIS. The macronucleus of the heterotrich ciliate Blepharisma undergoes a spectacular change in form in preparation for its division. The elongation phase of this cycle has been examined by light and electron microscopy. Coincident with elongation, microtubules appear closely applied to the outer surface of the macronucleus and parallel to the direction of elongation, and disappear as elongation is completed. It is demonstrated that the antimitotic drugs colchicine and podophyllotoxin reversibly block macronuclear elongation but do not entirely inhibit morphogenetic events including cell division. The failure of colchicine-treated macronuclei to begin or continue elongation is correlated with the prevention of formation, disruption, and/or disorientation of the extranuclear microtubules.     

Retardation of Regeneration and Division of Blepharisma by Ultraviolet Radiation and Its Photoreversal

Regeneration of Blepharisma undulans variety japonicus from which the hypostome has been removed is retarded by dosages of 3000 to 4600 ergs/mm.² at wavelength 2654A most strongly when the fragment is exposed soon after cutting. Dosages greater than 4600 ergs/mm.² prevent regeneration. Regeneration is also retarded strongly when the Blepharisma are cut soon after irradiation. Starvation retards regeneration and potentiates the effect of ultraviolet radiations. Division after regeneration of Blepharisma is also retarded by ultraviolet radiations about equally, regardless of when the Blepharisma are cut indicating a more lasting effect of the radiations upon the cells. Blepharisma cut after irradiation usually recover from the effects of the radiations sooner than uncut individuals given the same dosage. Retardation of division by ultraviolet radiation is subject to photoreversal by visible light, especially in a nitrogen atmosphere, provided the ultraviolet dose is not excessive. Visible light alone if prolonged, retards regeneration or may even kill the cut fragments of Blepharisma.     

A New Liquid Medium for Trypanosoma (Schizotrypanum) cruzi*

A new liquid medium, with fetal calf serum as the sole undefined component, was devised for the cultivation of Trypanosoma cruzi. The need for the serum is ascribed to its mitogenic proteins, which stimulate division of, and the uptake of [³H]thymidine by the parasites. In the new medium, T. cruzi has a cycle culminating in the appearance of up to 90% metacyclic forms in the stationary phase. This cycle is repeated on each serial transfer.     

The regulation of DNA replication during senescence and rejuvenation of Dunaliella tertiolecta by factors other than available metabolic energy

The unicellular green alga, Dunaliella tertiolecta undergoes a 4-fold reduction in DNA while progressing from early to late log phase of culture. During the period when the reduction in DNA occurs, the cells continue to divide at the maximal rate. Pulse labelling indicates little incorporation of [³H]thymidine into DNA during late log phase. Stationary phase cultures diluted with fresh medium undergo a lag period during which there is a 4-fold increase in DNA and a rapid incorporation of [³H]thymidine into DNA into DNA before division. The evidence indicates that the differences in the levels of DNA are not attributable to tetraploidy, multinucleated cells or a high level of redundancy of G-C-rich satellite DNA in early log phase cells. During stationary phase there is an increase in cellular starch and a decrease in free nucleotides. Electron microscopy reveals that stationary phase cells are distorted by many granules proven to be starch by their susceptibility to amylase treatment. The production of starch by stationary phase cells indicates that DNA replication does not cease because of a deficit of metabolic energy but because of some direct function of culture density.     

Partial Synchronization of Cell Division in Suspension Cultures of Haplopappus gracilis

Four different chemicals were tested in their ability to synchronize cell division in asynchronous cell cultures of Haplopappus gracilis. Twentyfour-hour treatments with 5-amino uracil resulted in a peak in the mitotic index about 14–16 hours after the end of the treatment. The increase in the frequency of mitoses was about three times that of the control. Hydroxyurea, at a concentration of 3 mM, gave after a treatment period of 12–24 hours an increase in the frequency of mitoses which appeared about 10 hours after the treatment. The mitotic index was about 35 per cent, which is 4 times that of the control. 5-Fluorodeoxyuridine (FUdR) at a concentration of 2 × 10^?7M gave a mitotic burst about 16 hours after treatment. At that time about 15 per cent of the cells were dividing which was about twice that of the control. The block was reversed with 4 × 10^?5M thymidine. Thymidine at a high concentration caused a reduction in the frequency of mitoses during the treatment. After 15 to 16 hours in a thymidine free medium a mitotic peak appeared with a doubling of the frequency of mitoses in treated cells. Cytological studies showed that parlicularly hydroxyurea but also 5-aminouracil and 5-fluorodeoxyuridine produced gaps and fragments at the concentrations which gave cell synchronization.     

Contraction of protoplasm. III. Cinematographic analysis of the contraction of some heterotrichs

The contraction of Stentor and Blepharisma, in response to mechanical and electrical stimulation and of Spirostomum in response to mechanical stimulation is described. All three species respond to electrical stimulation by contraction of the cytoplasm, beginning at the anodal end regardless of orientation of the animal. The differences in contractile ability and shapes during contraction are discussed in relation to body form and microanatomy. Stentor and Spirostomum also respond to mechanical stimulation. Dropping a weight on the slide causes contraction of the whole body of Spirostomum, but not of Stentor. Stimulation of the oral region of Stentor by means of a vibrating needle causes a contraction of the entire body, but this sensitivity is limited to the oral region. Blepharisma does not respond to mechanical stimulation. Spirostomum and Stentor undergo rapid spontaneous contractions, but Blepharisma does not contract spontaneously.     

DNA and RNA Syntheses by Intraerythrocytic Stages of Plasmodium knowlesi*

Incorporation of the nucleic acid precursors, orotic acid, adenosine, thymidine, and uridine, was studied in various stages of intraerythrocytic Plasmodium knowlesi from infected rhesus monkeys. Incubation of the parasitized erythrocytes with the precursors was for 3 hr periods using a plasma-free culture medium. The samples containing primarily rings, early trophozoites, or late trophozoites incorporated orotic acid, adenosine, and uridine into RNA; however, these stages exhibited negligible or very low levels of incorporation of any of the precursors into DNA. The sample containing late trophozoite and schizont stages incorporated orotic acid, adenosine, and uridine into RNA, and orotic acid, adenosine, and very low levels of thymidine into DNA. These results indicate that DNA synthesis (the S phase of the cell cycle) occurs very close to the time of nuclear division, and that either the G1 or G2 phase is very short in P. knowlesi. It was also observed that adenosine and orotic acid, 2 precursors which are incorporated into both DNA and RNA, are utilized differently by the intraerythrocytic parasites. Incorporation of orotic acid into RNA and DNA and adenosine incorporation into DNA were continuous for the entire incubation period, whereas incorporation of adenosine into RNA was very low during the last 2 hr of each period. It was further demonstrated that the parasites utilized exogenous uridine for synthesis of RNA, and that the older parasite stages incorporated thymidine into DNA.     

Thymidine transport by Novikoff rat hepatoma cells synchronized by double hydroxyurea treatment

Suspension cultures of Novikoff rat hepatoma cells were synchronized by a double hydroxyurea block. About 80% of the cells of the population doubled 5 to 8 h after the reversal of the second hydroxyurea block. At all stages of the cell cycle, thymidine was rapidly incorporated into the acid-soluble pool of the cells (mainly dTTP) and the rate of incorporation was limited by the rate of thymidine transport. The rate of thymidine transport per cell roughly doubled during the S or late S phase and decreased again to the base level during cell division. This was reflected by corresponding changes in V_max for thymidine transport, whereas the apparent K_m remained constant throughout the cell cycle.     

Nucleic acids methylation of synchronized BHK 21 HS 5 fibroblasts during the mitotic phase

The methylation of nucleic acids has been investigated during the cell cycle of an asparagine dependent strain of transformed fibroblasts (BHK 21 HS 5). The synchrony was carried out by a partial asparagine starvation of cells for 24 hours. The amino acid supply induced all cells to enter synchronously the G₁ phase. Methylation and DNA synthesis were respectively measured by pulsed [methyl-¹⁴C] methionine and [methyl-³H] thymidine incorporation. DNA methylation followed a biphasic pattern with maximal methyl incorporations during both S phase and mitosis. A partial desynchronisation induced the S phase of the second cycle to proceed before all the cells have achieved their division. Hydroxyurea was used in order to inhibit the DNA synthesis of cells entering the second cell cycle, which might interfer with the mitosis of the first one. The inhibitor was added either at the first beginning of cell division or during all the G₁ phase. In both conditions it suppressed ³H thymidine incorporation of the second cycle. However, mitosis took place and methylations occurred as in previous experiments. The DNA methylation of the mitotic phase in the first cell cycle could thus be dissociated from the classical post-synthetic DNA maturation and did not correspond to any DNA methylation appearing in the course of the second cell cycle.     

Effects of 1000 R whole-body X-irradiation on DNA synthesis and mitosis in the duodenal crypts of the BCF1 mouse

Summary Effects of 1000 R, whole-body X-irradiation on the proliferative cells of the mouse duodenal crypts, in the four phases of the generation cycle; namely, the DNA synthesis phase, S; the pre-mitotic gap, G ₂; the division phase or mitosis, M; and the pre-synthesis gap, G ₁. As pointed out by Whitmore and Till (1964) G₁ and G₂ are characterized only by the fact that no DNA synthesis is taking place in these phases.In the intestinal crypts of BCF₁ mice, a 1000 R whole-body X-ray exposure blocks cells in G₂ for approximately 18 hours, and reduces the number of cells in S to less than 1/2 that observed in control animals during the first 12 hours after exposure. Cells synthesizing DNA, and undergoing division, remain few in number for more than 48 hours. Between 48 and 72 hours a compensatory reaction begins, and the number of cells in M and S increases from 28 at 48 hours to 150 at 72 hours and reaches a mean value of 482 at 96 hours.Work supported under the auspices of the US Atomic Energy Commission.     

The uncoupling of macromolecular synthesis from cell division in SV3T3 cells by glucocorticoids: The imposition of a G2 block

Through a receptor-mediated process glucocorticosteroids block cell division by 20–45 hours in SV40-transformed 3T3 (SV3T3) mouse fibroblasts growing in a low calf serum (0.30% v/v) medium containing biotin. However, the rate of DNA synthesis, determined at various times after dexamethasone addition by the incorporation of radioactive thymidine into acid-insoluble material, is not inhibited by this steroid as late as 66 hours. A modest decrease is observable by 91 hours. There is also no reduction in the uptake of exogenous thymidine into acid-soluble cellular pools. Similarly, RNA synthesis and the uptake of radioactive uridine are not affected by the glucocorticoid up to 69 hours. Measurements of the amounts of cellular DNA (by the fluorescent dye, 4′,6-diamidino-2-phenylindole) and protein revealed that both macromolecules are present in elevated quantities in steroid-treated cells. (The constancy of the protein content in the nonproliferative stage suggests that protein synthesis and degradation are occurring at equal rates.) If the steroid is removed and fresh 10% calf serum medium added, cell division commences (even if nearly 90% of protein synthesis is inhibited by cycloheximide) as early as 45 minutes later such that by 2 hours the viable cell count increases by as much as 70%. Since the growth curve after recovery resembles a step function, it appears that the cells are partially synchronized by the glucocorticoid. These results demonstrate that the glucocorticoid cytostatic effect in SV3T3 cells is the result of a block not in G₁, as previously thought, but in G₂.     

THE MECHANISM OF 5-AMINOURACIL-INDUCED SYNCHRONY OF CELL DIVISION IN VI CIA FABA ROOT MERISTEMS

Cessation of mitosis was brought about in Vicia faba roots incubated for 24 hours in the thymine analogue, 5-aminouracil. Recovery of mitotic activity began 8 hours after removal from 5-aminouracil and reached a peak at 15 hours. If colchicine was added 4 hours before the peak of mitoses, up to 80 per cent of all cells accumulated in mitotic division stages. By use of single and double labeling techniques, it was shown that synchrony of cell divisions resulted from depression in the rate of DNA synthesis by 5-aminouracil, which brought about an accumulation of cells in the S phase of the cell cycle. Treatment with 5-aminouracil may have also caused a delay in the rate of exit of cells from the G₂ period. It appeared to have no effect on the duration of the G₁ period. When roots were removed from 5-aminouracil, DNA synthesis resumed in all cells in the S phase. Although thymidine antagonized the effects of 5-aminouracil, an exogenous supply of it was not necessary for the resumption of DNA synthesis, as shown by incorporation studies with tritiated deoxycytidine.     

THE EFFECT OF Mn(II) ON THE AUTOINDUCING GROWTH INHIBITION FACTOR IN Deinococcus radiodurans

Decreases in cell division at the stationary phase in bacterial cultures are often due to the depletion of nutrients and/or accumulation of toxic waste products. Yet, during the stationary phase, the highly radiation-resistant bacterium Deinococcus radiodurans undergoes new rounds of cell division when Mn(II) is added to the medium in a phenomenon known as manganese-induced cell division (MnCD). When cells were cultured in medium without Mn(II)-enrichment, a heat-resistant, proteinase K-resistant factor (or factors) with a molecular mass less than 10 kD accumulated in the spent medium. Inclusion of the concentrated spent medium in fresh medium could inhibit the growth of D. radiodurans significantly, and the degree of inhibition was dose dependent. However, the relative stimulatory effect of MnCD was also dose dependent—the higher the inhibition, the stronger was the MnCD response. Previous studies have shown that nutrients were not limiting and deinococcal cells would continue metabolizing its nutrients at stationary phase. Cells became more sensitive to radiation when nutrients in the medium eventually became depleted. We speculated that D. radiodurans might produce this factor in the medium to control its population density. The reduction in cell population would conserve the nutrients that in turn might enhance the survival of the species.     

DIVISION SYNCHRONY IN PRIMARY CULTURES OF AN ENDOZOIC DINOFLAGELLATE1

Division cysts of zooxanthellae harbored by Anthopleura elegantissima were isolated from random host-associated populations by their preferential attachment to plastic surfaces. By selecting cysts at similar stages in the cell cycle, synchronous division, excystation, and daughter cell reencystment were obtained in a medium enriched with amino acids. The interval of DNA synthesis in a single growth cycle was determined by pulse-labeling with radioactive thymidine. Analysis of the sequence of morphologic changes within such cycles suggested that the initial selection procedure isolates G₂ cells. The transit time from first generation G₂ division cysts to subsequent reentry into G₂ was about 70 hr.     

Binding of thyrotropin releasing hormone and prolactin release by synchronized GH3 rat pituitary cell line.

GH3 cells were synchronized by growing them in a low serum concentration (1%). They were thereafter put back in normal medium (17.5% serum) (time 0 of synchronization). Four parameters were then examined every two hours for up to 40 hours : rate of [³H] thymidine incorporation, cell number, binding of [³H] Thyrotropin Releasing Hormone (TRH) after a 30 min exposure, and prolactin (PRL) content of culture medium and cell extract.The rate of thymidine incorporation presented a 10–20 fold increase in S phase, beginning on 12–16 hours and lasting at 26 hours. The cell population was doubled at 28 hours. [³H] TRH binding to attached cells was observed throughout the cell cycle, but presented a significant increase (40–80%) during the S phase. In contrast, the % increase of PRL release in response to TRH was optimum (300% of control) in G₁ phase. Variations of the PRL cell content as well as of the PRL spontaneous release ability of the cell do not account for the variations of TRH responsiveness. The discrepancy between the two parameters of the TRH-GH3 cells interaction strongly suggest a morphological or functional heterogeneity of the TRH-binding sites.     

Reversible release of chick embryo fibroblast cultures from density dependent inhibition of growth

Initiation of proliferation in density-inhibited chick embryo fibroblast cultures induced by insulin or trypsin was partially reversed by replacing the medium with supernatants from parallel non-stimulated cultures. Growth stimulation by neuraminidase, pokeweed mitogen, bacterial lipo polysaccharide or purified tuberculin was less, or not at all, affected by this procedure. Medium change per se caused some proliferation in non-stimulated cultures. Increased rate of sugar uptake in insulin-stimulated cultures returned to the level of that in non-stimulated cultures within a few hours after medium change. This reversion took place apparently irrespective of the phase of the cell cycle. Replacing the medium with supernatants from non-stimulated cultures induced a rapid decline in subsequent thymidine incorporation during the first S-phase, and completely abolished the second peak of DNA synthesis. The fraction of cells irreversibly committed to mitosis increased when the time after stimulation increased. Less than three hours' incubation with insulin or trypsin was needed to initiate proliferation of a significant fraction of the cell population. It is concluded that reversion of the initiated cycle of a given cell is no more possible after the cell has entered the S-phase.     

An artifact in measurement of S phase initiation and its implication for the kinetics of S phase-specific enzyme activities

It is shown that the different onset of S phase as measured by autoradiography vs cumulative thymidine uptake is an artifact. We consequently propose that S phase-specific enzyme activities may accumulate a few hours prior to the actual initiation of DNA synthesis. A “pre-S” DNA synthesis that can be readily detected only by autoradiography has been proposed. Published data show that DNA synthesis in cultured animal cells is initiated approx. 2 h later when measured by cumulative incorporation of [³H]thymidine ([³H]TdR) as compared with autoradiography. We show here that the difference is in reality an artifact, owing to not taking into account both gradual, asynchronous entry of cells into S phase, as well as time-dependent accumulation of radioactivity into each cell after it has entered S phase. Combination of these two factors leads to the conclusion that [³H]TdR should be incorporated approximately as the square of time following entry of the first cell into S. Taking this into account, the two methods then are in agreement, as predicted. This argument also applies to the enzyme activities shown to increase with DNA synthesis in synchronized cultures. Such an enzyme accumulation really could begin some time earlier than indicated by conventional plots of cumulative enzyme activity vs time and may, in fact, precede the onset of S by a few hours.     

Thymidine phosphorylation in synchronous cultures of Tetrahymena pyriformis GL

Recently it has been established that thymidine can be phosphorylated in two ways in Tetrahymena pyriformis

1. 1. by action of thymidine kinase

2. 2. by action of nucleoside phosphotransferase.

The present report confirms that thymidine kinase is a peak enzyme during S phase. It is suggested that a different thymidine concentration in the thymidine kinase assay might explain why previous workers have been unable to find thymidine kinase in Tetrahymena.     

CELL POPULATION KINETICS OF EXCISED ROOTS OF PISUM SATIVUM

The cell population kinetics of excised, cultured pea roots was studied with the use of tritiated thymidine and colchicine to determine (1) the influence of excision, (2) the influence of sucrose concentration, (3) the average mitotic cycle duration, and (4) the duration of mitosis and the G₁, S, and G₂ periods of interphase.¹ The results indicate that the process of excision causes a drop in the frequency of mitotic figures when performed either at the beginning of the culture period or after 100 hours in culture. This initial decrease in frequency of cell division is independent of sucrose concentration, but the subsequent rise in frequency of division, after 12 hours in culture, is dependent upon sucrose concentration. Two per cent sucrose maintains the shortest mitotic cycle duration. The use of colchicine indicated an average cycle duration of 20 hours, whereas the use of tritiated thymidine produced an average cycle duration of 17 hours.