Dna Synthesis and Cell Generation Pattern of Chronic Lymphatic Leukaemia Lymphocytes Stimulated By Phytohaemagglutinin

A detailed analysis of the cell recruitment and of the cell generation pattern of normal lymphocytes and chronic lymphatic leukaemia (CLL) lymphocytes, simulated by phytohaemagglutinin (PHA), was performed by the bromodi-oxyuridine (BUdR) Hoechst technique. It was found that in normal cultures the majority of cells divide two or three times, producing an early peak of DNA synthesis, while only a few cells grow exponentially and pass through many rounds of replication. On the contrary, the majority of CLL responsive cells grow exponentially, producing a delayed peak of DNA synthesis, while cells which divide only two or three times are scarce or absent. No difference in the minimal cell cycle length of the normal and the CLL exponentially growing population was found. In addition, a cell population recruited into cycle for the first time 5–6 days following PHA stimulation was observed in normal cultures but not in CLL cultures.     

Relation between cell cycle and yield of aberrations observed in irradiated human lymphocytes

The bromodeoxyuridine-Giemsa technique has been used to study systematically the incidence of cells in first or subsequent mitoses at different fixation times of human lymphocyte control cultures as well as the influence of ionizing radiations on cell kinetics. Second divisions appear (3%) in cultures harvested 48 h after initiation. In 72 h cultures 40% of the dividing cells are in second and 33% in third division. Administration of 200 rads of X-rays before PHA stimulation results in a mitotic delay but does not increase the incidence of SCE. The yield of dicentrics after an exposure to 200 rads was the same for all cells in first mitosis regardless of fixation time. These results demonstrate that there is no evidence for the existence of sensitive subpopulations that could be distinguished by the time of the first mitotic division following stimulation.     

Proliferative kinetics of human lymphocytes in culture measured by autoradiography and sister chromatid differential staining

A simple combination of autoradiography, to determine when a cell synthesized DNA, and sister chromatid differential staining, to determine how many times a cell has divided, was used to follow up the proliferating fate of human lymphocytes in culture. Cells were incubated continuously with 5-bromodeoxyuridine (BrdU) and pulse-labelled with 0.1 muCi/ml [3H]thymidine at various times after stimulation with phytohemagglutinin (PHA). The cells were then harvested at 4 h intervals up to 72 h, and the percentage of labelled mitoses was determined separately in first, second, or third division cells. The data showed that the cycling cells, whether they began cycling at earlier or later times after stimulation, had about the same generation times of 12--14 h. This confirms that the heterogeneity of cell generations seen in short-term lymphocyte cultures is in large part due to the difference in the times when cells began cell cycling in response to PHA.     

Sister chromatid exchange in lymphocytes in myelodysplastic syndrome

Sister chromatid exchange (SCE), percentage of first, second, third mitoses, blastic transformation index and mitotic index in patients with myelodysplastic syndrome (MDS) (3 with refractory anaemia, 2 with refractory anaemia with sideroblasts, 1 with refractory anaemia with excess of blasts, 4 with refractory anaemia with excess of blasts in transformation) and in 15 healthy volunteers were estimated. Three types of lymphocytes cultures were set up: first with phytohemaglutinin (PHA), second with PHA and bromodeoxyuridine (BRdU), third with BRdU. In healthy persons the SCE frequency was negatively correlated to proliferating rate index, but in MDS such correlation was not found. The lymphocytes cell cycle duration based on percentage of mitoses was longer in MDS patients than in controls. The results of our studies show the disturbances of lymphocytes during cell cycle division resulting in higher SCE frequency and lower proliferating rate compared to controls.     

Characterization of the adaptive response to ionizing radiation induced by low doses of X rays to human lymphocytes

In previous studies we have shown that low doses of radiation from incorporated tritiated thymidine can make human lymphocytes less susceptible to the genetic damage manifested as chromatid breakage induced by a subsequent high dose of X rays. We have also shown that this adaptive response to ionizing radiation can be induced by very low doses of X rays (0.01 Gy; i.e., 1 rad) delivered during S phase of the cell cycle. To see if a low dose of X rays could induce this response in cells at other phases of the cell cycle, human lymphocytes were irradiated with 0.01 or 0.05 Gy before stimulation by phytohemagglutinin (G0) or with 0.01 Gy at various times after stimulation (G1), followed by 1.5 Gy (150 rad) at G2 phase. Although G0 lymphocytes failed to exhibit an adaptive response, G1 cells irradiated as early as 4 h after stimulation did show the response. Experiments were also carried out to determine how long the adaptive response induced by 0.01 Gy could persist. A 0.01-Gy dose was delivered to lymphocytes in the first S phase, followed by 1.5 Gy in the same or subsequent cell cycles. Lymphocytes receiving a 1.5-Gy dose at 40, 48, or 66 h after stimulation exhibited an adaptive response, whereas those receiving a 1.5-Gy dose at 90 or 114 h did not. Duplicate cultures containing bromodeoxyuridine showed that at 40 h all the lymphocytes were in their first cell cycle after stimulation, at 48 h half of the lymphocytes were in their first cell cycle and half in their second, and at 66 h 80% of the lymphocytes were in their third cell cycle. Thus the adaptive response persists for at least three cell cycles after it is induced by 0.01 Gy of X rays. In other experiments, the time necessary for maximal expression of the adaptive response was determined by delivering 0.01 Gy at hourly intervals 1-6 h before the 1.5-Gy dose. While a 4-h interval was enough for expression of the adaptive response, shorter intervals were not.     

Cell-mediated immunity to influenza virus antigen and mitogen in guinea pigs: measurement with a semimicro protein synthesis assay

A rapid and precise method for the assay of cell-mediated immune response basing on protein synthesis stimulation of mitogen-activated guinea pig lymphocytes is modified in a way that enables the study of virus-immunological problems. When used as a micromethod it has the following advantages over conventional methods: short-term cell culture, need of low quantities of cells and rapid preparation of great numbers of samples for radioactivity measurements. In this study we report the results of comparative experiments on measuring lymphocyte stimulation after addition of PHA and stimulation of sensitized lymphocytes following contact with homologous influenza virus antigen in vitro. The most important reaction parameters are as follows: 5-6 . 10(5) spleen lymphocytes/microculture in microtiter plates, use of Eagles's MEM cell culture medium without leucine, supplemented with HEPES buffer and 10% autologous guinea pig serum; optimum lymphocyte stimulation by addition of 0.5 microliter PHA or 0.1-1.0 microgram virus protein/ml; immuno-stimulation by PHA can be measured in vitro already after 6 h and by influenzavirus antigen already after 24 h.     

PHA stimulation of human lymphocytes during amino acid deprivation. Protein,RNA and DNA synthesis

Resting lymphocytes are in the G₀ phase of the cell cycle. Upon activation by PHA, they progress into G₁ with accompanying increased protein and RNA synthesis, initiate DNA synthesis and divide. We have studied the kinetics of inhibition of macromolecular synthesis during activation in the absence of single amino acids. Three types of kinetics are observed. In the absence of tryptophan or isoleucine, stimulated lymphocytes show a normal increase in protein and RNA synthesis during the first 30 hours of stimulation, initiate DNA synthesis but are subsequently inhibited. In phenylalanine-deficient medium, no DNA synthesis occurs in spite of a slight increase in protein synthesis. No increase in macromolecular synthesis is observed in medium lacking any one of the other essential amino acids (eg: lysine). Our results indicate that the kinetics of macromolecular synthesis in tryptophan-deficient medium is the result of a limited reserve of protein-bound tryptophan which becomes exhausted after 30 hours. On the other hand, delayed inhibition of synthesis in isoleucine-deficient medium probably reflects an initially low requirement for this amino acid followed by inhibition of the synthesis of isoleucine-rich proteins involved in some late event of stimulation. Partial deprivation of lysine results in kinetics of protein synthesis similar to that in tryptophan- or isoleucine-deficient media. The results indicate that the kinetics of macromolecular synthesis during activation of lymphocytes in the absence of an essential amino acid is a function of the quantitative requirement for that amino acid, at a given time during stimulation. Upon replacement of lysine, lymphocytes inhibited by lysine deficiency begin RNA and protein synthesis immediately and at a rate faster than that of unstimulated cultures to which PHA is added. They also initiate DNA synthesis earlier and therefore, are closer to the S phase than resting lymphocytes. It is concluded that lymphocytes stimulated in the absence of lysine are activated even though no overall increase in macromolecular synthesis is observed. Furthermore, the kinetics of DNA synthesis following reversal of inhibition by phenylalanine suggests that lymphocytes stimulated during phenylalanine deprivation become arrested at most six hours before S. These results indicate that amino acid deficiencies lead to arrest of activated lymphocytes at various stages of stimulation, depending on how stringent these deficiencies are.     

Cell-stage dependence of mutagen-induced sister-chromatid exchanges in human lymphocyte cultures

The induction of sister-chromatid exchanges (SCEs) was studied in phytohemagglutinin (PHA)-stimulated human lymphocytes exposed for 1 h to mitomycin C (MMC, 3 X 10(-6) M), ethyl methanesulphonate (EMS, 2 X 10(-2) M), or 4-nitroquinoline-1-oxide (4NQO, 3 X 10(-5) M) at various cell-cycle stages of 72-h cultures. The doses of the chemical were chosen to give about 20 SCEs per cell when treated at Go. The SCE frequency increased almost linearly with MMC or EMS treatments at later times after PHA stimulation, peaking with those at 36 h (at around the first G1/S boundary in the 2 consecutive cell cycles, which was revealed by concomitant experiments), and then decreased with subsequent treatment times. Cell-cycle kinetics and the cell stages at which the cells were treated were measured by autoradiography and sister-chromatid differential staining. The data show that MMC and EMS produce larger numbers of SCEs when treated at stages closer to the beginning of S, and that the most efficient time of treatment is the G1/S boundary in the first cell cycle of the two consecutive cycles before sampling. Pulse treatment with EMS caused about 3 times larger inductions of SCEs when done at late G1/early S(G1/S boundary) in the first cell cycle compared to that at G0/early G1, whereas identical exposure to MMC at the first G1/S boundary produced only 1.5 times larger numbers of SCEs than that at G0/early G1. EMS and MMC both, however, induced 30-40% larger numbers of SCEs when treated at the G1/S boundary in the first cell cycle than when treated at the second cell cycle before sampling. On the contrary, treatment with 4NQO led to the induction of about the same numbers of SCEs even when treated at different cell-cycle stages before the second G1/S boundary. The SCE frequency in 4NQO-treated cells then decreased with subsequent treatment times.     

Effect of aluminum chloride on mitogenesis,mitosis, and cell cycle in human short-term whole blood cultures: Lower concentrations enhance mitosis

Aluminum, the third most common element in the earth's crust (second to oxygen and silicon) and recently suspected by some investigators to be implicated in Alzheimer disease etiology, has been studied in relation to its effect on mitogenesis, mitosis, and cell cycle. We have observed that 2–4 mM concentrations of AlCl₃ have decreased the number of cells that undergo mitogenesis (PHA-induced blast transformation) and mitosis in human short term whole blood cultures. We have also shown that the rate of the cell cycle was slowed down, i.e., cell cycle time was increased in the presence of AlCl₃. Also, we have demonstrated a reversible effect on aluminum-induced reduced mitotic index in long-term EBV-transformed lymphoblastoid cultures. Although safeguards such as limiting aluminum serum concentrations have been recommended to protect individuals undergoing dialysis, it should be realized that concentration accumulations of aluminum may increase over chronic exposures. Accordingly, if the number of cells stimulated by PHA is reduced in the presence of AlCl₃, there may be a reduction of immune competence, since the degree of PHA stimulation has been used as an indicator of immune response. Similar reductions in mitotic index could affect every tissue involved with cell division. Although it may not be the same for higher concentrations, from our results, we have also shown that decreased mitotic rates were reversible in long-term EBV-transformed lymphoblastoid cultures. Increased numbers of mitoses were observed in human short-term whole blood cultures that were exposed to 2 μM concentrations of aluminum chloride. The concentration is close to those found in normal human serum and within the “safeguard” range recommended for dialysis patients. A similar trend for aluminum sulfate was also observed, while preliminary results for three other aluminum species, lactate, citrate, and maltol, were also reported. Although previous reports have indicated a positive effect of aluminum on mitosis in vitro or in vivo, this is the first such report involving human material. It is clear that higher concentrations of aluminum chloride at 2.0–4.0 mM reversibly inhibit mitosis while more dilute concentrations of 1–2 μM, closer to those found in normal serum, enhance mitosis. The present results, as well as those in the literature, suggest that aluminum may be an essential element in cellular processes for optimal growth, development, and health maintenance. Future research will further test this hypothesis.     

KINETICS OF PHYTOHEMAGGLUTININ STIMULATED LYMPHOCYTES IN CHRONIC LYMPHOCYTIC LEUKEMIA

The DNA synthesis pattern and several kinetic parameters of in vitro PHA stimulated normal and CLL lymphocytes were determined. The DNA synthesis peak of CLL lymphocytes occurred 2–3 days later than that of normal lymphocytes. The generation time, estimated by the labeled mitoses method, was found to be 28 hr and 20 hr for CLL and normal lymphocytes respectively. This difference was mainly due to longer S and G_t periods. It was also shown that both CLL and normal lymphocytes divide several times. These data were confirmed by the chromatid labeling pattern and by the halving of the grains and the double labeling techniques. By combining continuous and pulse labeling the growth fraction of CLL lymphocytes was found to be progressively increasing, because of the recruitment of new cells in cycle, from the third day of culture. Therefore the delayed peak of DNA synthesis of CLL lymphocytes was caused by a longer cell cycle and by a longer pre-replicative phase.     

Cell cycle analysis of human peripheral blood T lymphocytes in long-term culture

We have studied the cell cycle of resting T lymphocytes from long-term (LT) cultures following stimulation with phytohemagglutinin (PHA) and recombinant Interleukin 2 (IL-2). We examined the kinetics of entry into S phase by autoradiography, the accumulation of cellular RNA by microfluorometric techniques, and ultrastructural morphology by electron microscopy. In addition, we examined the expression at the mRNA level of six cell cycle-dependent growth-regulated genes (c-fos, c-myc, KC-1, JE-3, vimentin, and histone H3). We show that T lymphocytes of LT cultures respond differently to mitogenic stimulation than the T lymphocytes of freshly isolated peripheral blood mononuclear cell cultures. At the ultrastructural, biochemical, and molecular levels, resting T lymphocytes of LT cultures can be distinguished from physiological (G0) lymphocytes of peripheral blood.     

Physical,chemical, and biological factors affecting sister-chromatid exchange induction in human lymphocytes exposed to mitomycin C prior to culture

In experiments to assess the effects of several biological, chemical, and physical variables on sister-chromatid exchange (SCE) induction in cultured lymphocytes exposed to mitomycin C (MMC) before PHA stimulation we observed: (1) high SCE frequencies in female cells, and normal SCE frequencies in Y-bearing metaphases in mixed cultures containing equal numbers of MMC-treated female lymphocytes and untreated male lymphocytes; (2) small, but statistically significant, decreases in SCEs with increasing pH after G₀ exposure in the pH range 6.6–7.6; (3) pronounced reductions in MMC-induced SCEs in lymphocytes exposed at 4°C vs. 37°C. In other studies, SCE induction was evaluated in cultures exposed during G₀ to MMC concentrations ranging from 0.25 to 2.5 μg/ml for varying time intervals ranging from 5 min to 24 h. For all concentrations tested SCE induction varied as a linear function of G₀ exposure time. To compare SCE induction between cultures, we calculated the mean frequencies of SCEs induced per metaphase/unit dose MMC/unit G₀ exposure time (SCE/μg/h). A mean frequency of 20.7 ± 4.8 SCE/μg/h was observed for 41 lymphocyte cultures suggesting that a single term adequately describes the rate of SCE induction following G₀ exposure to a 10-fold range in concentration of MMC for time intervals of 30 min to 24 h.     

In vitro response of lymphocytes to phytohemagglutinin (PHA) as studied with antiserum to PHA : II. Cell cycle analyses

The cell cycle and phase times of human lymphocytes responding to PHA have been analysed with the percent labelled metaphases (PLM) technique. The range of generation times (13–18 h) and DNA synthesis times (6.5–10.5 h) reported here compare well with previous measurements in the literature. Cycle analyses of the early responding cells of the initial response, selected with partial anti-PHA serum inhibition, and of restimulated cells yield relatively well-defined PLM curves. The short cycle times measured from these curves may reflect the early cycles after stimulation or a subpopulation of responding cells. Analyses at two times during both the initial and restimulation responses suggest that cycles lengthen with time after stimulation. The poor PLM curves of the initial response and the restimulation response of cells released from anti-PHA inhibition indicate considerable intercellular variation in cycle times. Cells in the initial long G 1 phase contribute to this variation. PHA dose does not appear to affect the cycle time.     

Lymphocyte reactivity in pregnant women and newborn infants.

The mitotic response to phytohaemagglutinin (PHA) was determined in lymphocytes of mothers and their newborn infants obtained at delivery and seven days later by measuring the rate of 125 I-idoxuridine uptake into DNA in lymphocytes cultured in their own plasma and after washing and resuspension in fetal bovine serum. There was no difference in the unstimulated counts of maternal lymphocytes taken at delivery, whether unwashed or washed, compared with those from nonpregnant controls. With PHA stimulation the mitotic response of the maternal lymphocytes cultured in their own plasma was reduced compared with that of the control lymphocytes but washed maternal cells showed a similar response to the controls. These findings suggest that the reduced lymphocyte mitotic response to PHA in pregnancy is due to a plasma inhibitory factor This inhibition was not evident in maternal blood taken seven days after delivery. DNA synthesis in unstimulated cultures from newborn infants at birth and seven days after birth was greater than that in adult control cultures. With PHA stimulation the mitotic response of cord-blood lymphocytes cultured in their own plasma paralleled that of control lymphocytes but washed newborn cells showed a greater response. Thus plasma suppression similar to that observed in the mother seems also to affect infants at birth. This inhibition was not demonstrable in blood taken from infants of 7 days.     

Stimulation of chicken lymphocytes by T- and B-cell mitogens.

Cultures of chicken spleen, peripheral blood, thymus, and bursal lymphocytes were tested for mitogenic stimulation by phytohaemagglutinin (PHA), concanavalin A (ConA), pokeweed mitogen (PWM), bacterial lipopolysaccharide (LPS), trypsin, and insulin. Spleen and blood leukocytes were stimulated by both the lectins and LPS, and also to some degree by trypsin and insulin as judged by increased incorporation of [³H]thymidine into acid-insoluble material. This was observed in cultures incubated in serum-free medium as well as in the presence of foetal bovine serum or autologous plasma. Thymus cells were reproducibly stimulated by high concentrations of PHA. No significant responses were obtained in bursal cell cultures with any of the compounds tested. Removal of cotton wool-adherent cells from the spleen cell suspensions resulted in a subpopulation of cells which were stimulated by PHA but showed little response to ConA, PWM, or LPS. This procedure did not remove surface immunoglobulin-bearing cells from the original suspension. Both these enriched spleen lymphocytes and the unfractionated spleen, blood and thymus leukocyte cultures were effectively stimulated by a partially purified PHA but with a highly purified PHA preparation only at very high concentrations. These and other results suggest that the mitogenic components in crude PHA preparations are different for chicken and human or mouse cells.     

Sister-chromatid exchanges and cell-cycle kinetics in human lymphocyte cultures exposed to alkylating mutagens: apparent deformity in dose-response relationships

Experiments have been carried out using human whole-blood cultures to determine the effects of sampling times and of the duration of 5-bromodeoxyuridine (BrdUrd) treatment before fixation on sister-chromatid exchange (SCE) frequencies following exposure to mitomycin C (MMC). Cells were pulse treated for 1 h with 3 X 10(-6) M MMC at G1, and then sampled at 4-h intervals up to 88 h after stimulation of cultures with phytohemagglutinin (PHA). Results showed that this MMC treatment induced a 5-6 h proliferation delay per cell cycle, and that SCE frequencies first increased with time of fixation, peaking at 68 h, and then decreased. When cells were similarly treated with MMC, but subsequently exposed to BrdUrd for various times before fixation of cultures at 72 h, the SCE frequencies markedly increased with increasing durations of BrdUrd incubation times. These data indicate that, in mutagen-treated cultures, lymphocytes having relatively longer cell-cycle times show a higher mean frequency of SCEs. In a subsequent experiment, cells were treated for 1 h with increasing doses of MMC or 4-nitroquinoline 1-oxide (4NQO) at 0, 24, or 48 h, and then fixed at 72 h after PHA stimulation. Results showed that the optimal treatment times at which the agents could most efficiently produce SCEs were different for MMC and 4NQO, and that the dose-response curves tended to 'bend down' at very high doses; that is, treatments with very high doses induced smaller than expected numbers of SCEs. However, cells similarly treated with very high doses showed a higher, expected frequency of SCEs when sampled at 84 h, but again had a lower than expected SCE frequency when fixed at 96 h. The results indicate that there is an optimal time for sampling at which one can observe the maximum increase in SCE frequencies following mutagen exposure, and strongly suggest that the higher the dose, the later the optimal sampling time. Because of the apparent deformity of dose-response curves obtained after various treatments and sampling times, it seems necessary that extra fixation-time points be included in test protocols so as to avoid false negatives or confirm possible positives.     

Effect of the tumor promoter TPA on the distribution of PHA-stimulated human lymphocytes by cell cycle phases

Patterns of the cell cycle distribution in human peripheral blood lymphocytes, stimulated by PHA alone and PHA plus 12-o-tetradecanoylphorbol-13-acetate (TPA), were studied using DNA cytometry in different times after PHA stimulation. In the first period (nearly 3 days after PHA stimulation) TPA induces no significant differences in the characters under consideration, but in the later period, when the proliferation of the cultures stimulated by PHA alone is reducing, in other cultures stimulated by PHA plus TPA the percentage of cells in S-phase does not reduce, whereas the percentage of cells in G2-phase is rising, which may suggest that this phase is blocked. Concurrently the tetraploid cells are appearing. Accumulation of cells in G2-phase can be overcome by the application of chlorpromazine, which is known to inhibit the membrane-associated protein kinase C.     

BrdU-Hoechst flow cytometry reveals regulation of human lymphocyte growth by donor-age-related growth fraction and transition rate

An improved BrdU-Hoechst flow assay was applied to cell kinetic studies of human lymphocyte cultures during a 24-96 hr interval after PHA stimulation. The assay shows that the duration of the initial lag phase and the proportions of noncycling cells increase as a function of donor age, whereas the rates of transition from each cell cycle compartment to the next decrease. Cell cycle arrest occurs in the first S and G2 phase after stimulation of lymphocytes from a 75-year-old donor but not from younger donors. The data are consistent with several models of cell cycle kinetics, so long as these models are modified to include a fraction of noncycling cells in each cell cycle compartment.     

Characterization of temperature-sensitive mutants of animal cells

An early increase in lymphocyte plasma membrane K⁺ transport is essential for PHA stimulated lymphocytes to divide. Little is known about the specific source and amount of energy required to support the increased transport by activated lymphocytes. Since ouabain, a cardiac glycoside, specifically inhibits the transport ATPase, we have measured the decrement in glycolysis and tricarboxylic acid cycle activity when untreated and PHA treated lymphocytes were exposed to ouabain. This metabolic decrement represents the portion of metabolism associated with monovalent cation transport and closely related processes. Since TCA cycle activity accounted for only 0.2% of glucose consumption, aerobic glycolysis was the major source of energy, i.e., ATP, for increased transport. Approximately one-third of the total lactate production in both control and PHA stimulated lymphocytes was ouabain-sensitive. Ouabain sensitive lactate production in control, 105 μmol/10¹⁰ cells/hour, increased 1.8-fold to 193 μmol/10¹⁰ cells/hour after PHA treatment. Active K⁺ influx in similar cell populations increased from 40 μmol/10¹⁰ cells/hour to 74 μmol/10¹⁰ cells/hour (1.9-fold) after PHA treatment. The increment in ouabain-sensitive energy production and K⁺ transport were closely correlated and, therefore, 0.38 moles of K⁺ are transported for each mole of ATP generated in both control and PHA treated cells. The increased requirement for transport related energy is provided by increasing the ouabain-sensitive ATP production rather than altering the efficiency of ATP transduction.