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.     

THE KINETICS OF CELL PROLIFERATION IN THE TRACHEOBRONCHIAL EPITHELIA OF RATS WITH AND WITHOUT CHRONIC RESPIRATORY DISEASE

Labelling indices of the tracheobronchial epithelia of conventionally-derived rats with chronic respiratory disease (CRD) and minimal-disease rats without CRD have been determined. The duration of the DNA synthesis phase (t_s) computed from the percentage of mitoses labelled at various intervals of time after injection of tritiated thymidine was 7 hr: t_G2 was 3.5 hr. Using the measured value of t_s and the labelling indices, the mean turnover times of the tracheobronchial epithelia in three groups of six 5-week-old conventionally-derived rats were calculated to be 11.2, 14.6 and 22.4 days, while in similar groups of 5-week-old minimal-disease rats the turnover times were found to be 24.3, 36.5 and 41.6 days. The majority of cell divisions in the tracheobronchial epithelium of these minimal disease rats were probably required for growth rather than renewal. The mean turnover time of this tissue in 5-week-old Syrian hamsters was 73 days. The cells of the rat tracheobronchial epithelium have been classed as basal or superficial, depending on their shape and proximity to the basement membrane. The mean turnover time of the basal cells in 5-week-old minimal-disease rats was 11.7 days calculated from labelling indices. The migration method of Brown & Oliver (1968) gave a similar value for the basal cells in minimal-disease rats, and a value of 9.5 days for the basal cells in a group of conventionally-derived rats. The mean turnover time in the latter was only 5.4 days if two rats with tracheobronchitis were included. Consideration of the slow rate of fall in mean grain count over labelled cells at intervals of time after labelling and the calculated turnover times suggests that the proliferative fraction of the basal cell population is close to unity. Well-labelled cells were still present in both basal and superficial populations in the minimal-disease rats at 10 days after labelling. The marked effects of CRD on cell proliferation in this epithelium are emphasized and the significance of this in relation to published work is discussed.     

蟾蜍血液淋巴细胞姐妹染色单体互换及细胞周期动力学研究

本文对中华大蟾蜍Bufo bufo gargarizans血液淋巴细胞在植物血球凝集素(PHA)刺激条件下的细胞周期动力学及丝裂霉素C(MMC)诱发姐妹染色单体互换(SCE)的敏感性进行了研究。用姐妹染色单体差别染色方法确定细胞的分裂次数。实验结果表明,中华大蟾蜍血液淋巴细胞在体外培养2天后出现第二次分裂细胞,3天后达峰值(占分裂细胞中期相的38.9％),此后,其百分比逐日下降,培养后4天出现第三次分裂细胞,第5天出现第四次分裂细胞。Brdu浓度在8—24μg/ml范围内对SCE本底无影响。6ng/ml MMC所诱发的SCEs比对照组高3倍以上,说明中华大蟾蜍对MMC的诱变作用相当敏感。     

EFFECTS OF MELANOPROTEINS AND THEIR PRECURSORS ON CELL PROLIFERATION THE PROBLEM OF SELECTIVITY

The actions of melanin and its precursors on mitotic frequencies, cell division and ³H-thymidine incorporation in protokaryotic and eukaryotic cells are studied. It was also suggested that the binding of melanin precursors with proteins in the melanosomes is a way of scavenging a cytotoxia activity.     

EFFECT OF METHOTREXATE ON THE CELL CYCLE OF L1210 LEUKEMIA

The influence of methotrexate (MTX) on the proliferative activity of cells in different phases of cell cycle has been studied. MTX (5 mg/kg) was injected i.p. 3 days after the inoculation of 5 × 10⁶ leukemia cells into F₁ (DBA × C57 BL) mice. It was shown that MTX causes degeneration of cells, being in G₁- as well as in S-phase at the time of drug injection. Incorporation of ³H-TdR was suppressed for a period ranging from 2 to 12 hr after MTX administration, which is demonstrated by the decrease in the number of grains per cell. The number of cells labeled after ³H-TdR injection was also sharply decreased during this period. For a period of 3 until 15 hr after MTX administration the mitotic index decreased significantly as a result of inhibition of DNA synthesis. The blocking of the G₁-S transition was evident during 4 hr after MTX. Thereafter the G₁-S transition proceeds at a rate which is practically equal to that for nontreated controls. MTX did not inhibit transition to mitosis of cells being in G₂-phase and in a very late S-phase at the time of drug injection. The sensitivity of G₁-cells to the cytocidal effect of MTX shows that for L1210 leukemia cells MTX can be classified as a cycle-specific drug killing both G₁ and S-cells rather than S-phase specific agent with self-limitation.     

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.     

细胞周期及DNA损伤剂引起的细胞NAD含量变化及其意义

本文观察了FL细胞中ADP-核糖基转移酶(ADPRT)底物NAD含量的细胞周期性变化及其与DNA复制之间的关系。FL细胞NAD含最在G_1期最高,而在S期DNA合成高峰后0—3小时(S/G_2期)达到最低点。ADPRT抑制剂3 AB能够抑制NAD含量的细胞周期性变化,而且S期DNA合成亦受到抑制,并呈现S期延长,提示ADP-核糖基化作用可能参与DNA复制过程。本文还观察了三种DNA损伤剂MNNG、MMS及4NQO对处于细胞周期不同时相的FL细胞NAD含量的影响,以及ADPRT抑制剂3 AB及尼克酰胺对此影响的作用。证明ADPRT抑制剂可以特异地抑制DNA损伤性NAD含量下降而对正常FL细胞NAD含量及代谢抑制剂2,4-DNP所致的NAD含量下降没有影响。从而有可能建立一个以测量细胞内NAD含量为指标的简便、快速、特异的检测DNA损伤因子的方法。     

GRANULOPOIESIS AND CELL KINETICS IN CHRONIC MYELOID LEUKAEMIA

The present study is an analysis of the kinetic data for chronic myeloid leukaemia derived from personal observations and cases reported in the literature. A comparison is made with the parameters for normal granulopoiesis and the growth pattern of the CML cell population discussed.     

KINETICS OF MURINE HAEMOPOIETIC CELL PROLIFERATION IN DIFFUSION CHAMBERS

Murine bone marrow cells were cultured in cell impermeable diffusion chambers in the abdominal cavities of mice. The kinetics of granulocyte and macrophage formation were studied by stathmokinetic and autoradiographic techniques. During the period of most rapid growth of proliferative granulocytes, their generation time and its different phases were: t _c∽ 8 hr, t _G1∽ 1·5 hr, t _s∽ 5·5 hr, t _G2∽ 0·7 hr and t _M∽ 0·25 hr.
The generation time of macrophages and their precursors was approximately 8 hr. Formation of macrophages was significantly reduced when chamber inoculum was increased, as judged by ³H-TdR labelling index.     

TIME SEQUENCE OF NUCLEAR PORE FORMATION IN PHYTOHEMAGGLUTININ-STIMULATED LYMPHOCYTES AND IN HELA CELLS DURING THE CELL CYCLE

The time sequence of nuclear pore frequency changes was determined for phytohemagglutinin (PHA)-stimulated human lymphocytes and for HeLa S-3 cells during the cell cycle. The number of nuclear pores/nucleus was calculated from the experimentally determined values of nuclear pores/µ² and the nuclear surface. In the lymphocyte system the number of pores/nucleus approximately doubles during the 48 hr after PHA stimulation. The increase in pore frequency is biphasic and the first increase seems to be related to an increase in the rate of protein synthesis. The second increase in pores/nucleus appears to be correlated with the onset of DNA synthesis. In the HeLa cell system, we could also observe a biphasic change in pore formation. Nuclear pores are formed at the highest rate during the first hour after mitosis. A second increase in the rate of pore formation corresponds in time with an increase in the rate of nuclear acidic protein synthesis shortly before S phase. The total number of nuclear pores in HeLa cells doubles from ~2000 in G₁ to ~4000 at the end of the cell cycle. The doubling of the nuclear volume and the number of nuclear pores might be correlated to the doubling of DNA content. Another correspondence with the nuclear pore number in S phase is found in the number of simultaneously replicating replication sites. This number may be fortuitous but leads to the rather speculative possibility that the nuclear pore might be the site of initiation and/or replication of DNA as well as the site of nucleocytoplasmic exchange. That is, the nuclear pore complex may have multiple functions.     

CELL PROLIFERATION KINETICS OF EPIDERMIS AND SEBACEOUS GLANDS IN RELATION TO CHALONE ACTION

Median S-phase lengths of pinna epidermis and sebaceous glands, and of epithelia from the oesophagus and under surface of the tongue of Albino Swiss S mice were estimated by the percentage labelled mitoses method (PLM). The 18.4 and 18.8 hr for the median length of S-phase for pinna epidermis and sebaceous glands respectively made it possible for these two tissues to be used experimentally for testing tissue specificity in chalone assay experiments. The 10.0 and 11.5 hr for oesophagus and tongue epithelium respectively made experimental design for chalone assay difficult when pinna epidermis was the target tissue. The results of the Labelling Index measured each hour throughout a 24-hr period showed no distinct single peaked diurnal rhythm for pinna epidermis and sebaceous glands. Instead a circadian rhythm with several small peaks occurred which would be expected if an S-phase of approximately 18 hr was imposed on the diurnal rhythm. This indicates that there may be very little change in the rate of DNA synthesis. The results are given for the assay in vivo of purified epidermal G₁ and G₂ chalones, and the 72–81% ethanol precipitate of pig skin from which they could be isolated. These experiments were performed over a time period which took into account the diurnal rhythm of activity of the mice as well as the S-phase lengths. Extrapolating the results with time of action of the chalone shows that the G₁ chalone acts at the point of entry into DNA synthesis and that the S-phase length was approximately 17 hr for both the pinna epidermis and sebaceous glands. This may be a more correct value since the PLM method overestimates the median S-phase length as it is known that in pinna skin the [³H]TdR is available to the tissues for 2 hr and true flash labelling does not take place. The previous reports that epidermal G₁ chalone acts some hours prior to entry into S-phase resulted from experiments on back skin where the S-phase is shorter and there is a pronounceddiurnal rhythm which could mask the chalone effect. The epidermal G, chalone had no effect on DNA synthesis even at different times in the circadian rhythm. Thus the circadian rhythms and S-phase lengths of the test tissues need to be considered when experiments are performed with chalones. Ideally, the target tissues selected for cell line specificity tests should have the same cell kinetics for the easier and more accurate assessment and interpretation of results. When the tissues have markedly different cell kinetics, experimental procedures and results need to be evaluated accordingly. The point of action of G, chalone can only be assessed if the effect is measured over the peak of incorporation of 13H]TdR into DNA. The results of the effects of skin extracts are analysed in relation to changes in the availability of i3H]TdR for the incorporation into DNA and to the possibility of there being two distinct populations of proliferating cells.     

ABSENCE OF EFFECT OF MULTIPLE INTRAPERITONEAL INJECTIONS ON CELL PROLIFERATION, AND ESTIMATION OF THE CELL CYCLE TIME IN THE EPITHELIUM OF THE OESOPHAGUS AND FORESTOMACH IN MICE, HAMSTERS AND RATS

Counts of labelled epithelial nuclei in mice given single or multiple injections of tritiated thymidine (to label cells synthesizing deoxyribonucleic acid), either alone or after 24 or 48 hr multiple injections of water, showed that multiple intraperitoneal injections did not disturb normal cell proliferation. The rate of cell proliferation was the same in the epithelium of the oesophagus and forestomach, and in these epithelia there was no difference between mice, hamsters and rats. Cell cycle times were estimated in these epithelia from the number of nuclei labelled in animals given single or multiple injections of tritiated thymidine.     

CELL PROLIFERATION IN COMPLEX TISSUES: THE CONTROL OF THE MITOTIC CYCLE OF CELL POPULATIONS IN THE CULTURED ROOT MERISTEM OF SUNFLOWER (HELIANTHUS)

Experiments were performed with cultured primary root tips of sunflower (Helianthus annuus var. Russian Mammoth) to determine: (1) if progression in the mitotic cycle of meristematic cells was nutritionally controllable by carbohydrate starvation and replenishment; (2) where in the mitotic cycle control was effected; and (3) whether nutritional deprivation could be used to detect phenotypically different subpopulations in a complex tissue. Meristematic cells were rendered stationary by carbohydrate starvation, as indicated by the absence of cell division; this condition was reversed by carbohydrate provision. After 72 or 96 hr of starvation most cells stopped in G1 (80–90%) and G2 (10–20%), and a very few (“leaky” cells) continued to enter S. “Leaky” cells represent a small population with an S period of approximately 4.1 hr that either lack a principal control point in G1 or have an unusual metabolism whereby the control point requirements are met and have a carbohydrate dependence for mitosis. Though phenotypically different, no specific functions can be attributed to “leaky” cells at this time.     

泽蛙(Rana limnocharis)活体内骨髓细胞增殖动力学的研究

离体培养的动物细胞增殖规律已有不少的报道,但是两栖类活体内细胞增殖过程如何,尚未见报道。本文运用SCD术,对泽蛙活体内骨髓细胞增殖动力学进行了较系统地观察,最后推算出Tc为12—24小时。     

CHANGES IN CELL PROLIFERATION KINETICS OCCURRING DURING THE LIFE HISTORY OF MONOLAYER CULTURES OF A MOUSE TUMOUR CELL LINE

Following inoculation of monolayer cultures of EMT6 mouse tumour cells at 10⁵ cells, a short lag is followed by 3 days of exponential growth with a population doubling time of 12 hr. A plateau cell number is reached between days 4 and 5 and is maintained for at least 8 days. During exponential growth, the pulse ³H-TdR labelling index is 55–60%, all cells are in cycle, and the median cycle time is 11–12 hr. For the first 3 days of plateau phase, the labelling index is about 25 % and there is considerable cell loss. The cell cycle is 32–40 hr, and S-phase is very long. Later in plateau phase, the labelling index falls to <2 % and there is little cell loss. The changes in kinetics occurring in EMT6 cultures are discussed with reference to reported changes occurring in other cell lines.     

INTRAPOPULATION KINETICS OF THE MITOTIC CYCLE

Data obtained with time lapse cinemicrographic techniques showed that the distribution of generation times for exponentially proliferating human amnion cells in culture is skewed to the right and that reciprocals of generation times appear normally distributed. As shown for bacteria, the true age distribution is much broader than theoretical distributions which fail to take into account the dispersion of generation times. By means of the technique utilizing autoradiographic detection of tritiated thymidine in cells whose mitotic histories were recorded by time lapse cinemicrography, it was shown that the G1 distribution is similar to the generation time distribution but is more variable. In our experiments, the G2 + prophase distribution resembled the generation time and G1 distributions. The data suggested two possibilities for S: either it is relatively constant, or it is inversely related to the lengths of G1 and G2 + prophase. Since G1 is more variable than the total cycle, and G2 + prophase more variable than the computed sum of S + G2 + prophase + metaphase, it was concluded that the relationships between parts of the cycle are non-random and that compensating mechanisms apparently help regulate the lengths of successive parts of the mitotic cycle in individual cells.     

THE LABELLED MITOSES CURVE AND THE ESTIMATION OF THE PARAMETERS OF THE CELL CYCLE

A method is described for fitting a 'fraction labelled mitoses'curve to a set of data points and for estimating the values of the best fitting parameters of the cell cycle. Estimates of the SE of the parameters are obtained. The method depends on the fact that when gamma distributions are used to describe the durations of the phases of the cell cycle, the Laplace transform of a FLM curve can be described by simple analytic functions enabling a least squares fit to be made to a set of Laplace transforms of the experimental data. The method is easy to program and quick to execute.     

CELL KINETICS IN DIFFUSION CHAMBERS: SURVIVAL, RESUMPTION OF PROLIFERATION, AND MATURATION RATE OF MURINE HAEMOPOIETIC CELLS

Bone marrow cells and blood leucocytes from mice have been cultured in vivo in diffusion chambers. Granulocytes and macrophages were formed in the chambers, whereas lymphocytes and mature end cells were gradually lost.
The proliferation, differentiation and death of cultured cells were quantified by total and differential cell counting, by scintillation counting and by radio-autographic evaluation of ³H-thymidine incorporation. Hydroxyurea and vinblastine were used as cytotoxic agents.
Ordinarily 40–60% of the cells inoculated could not be recovered after a few hours in culture. Proliferative cells resumed DNA synthesis shortly after implantation, and the rate of synthesis did not decline on further culturing. Steady-state progenitor cells had a pre-replicative lag period of about 18 hr, whereas regenerating progenitors started to synthesize DNA after about 14 hr. After 72 hr of culturing newly formed segmented granulocytes were detected. Maturation from the myelocyte to the segmented granulocyte stage lasted about 18 hr. Eosinophilic granulocytes had a long life span in the chambers, whilst the segmented neutrophils were rapidly eliminated after a life span estimated to be about 2 days.     

CELL CYCLE KINETICS OF ENDOREDUPLICATION IN GAMMA-IRRADIATED ROOT MERISTEMS OF PISUM SATIVUM

Label and mitotic indices and microspectrophotometry of unlabeled interphase cells were used to measure the proportion of root meristem cells of Pisum sativum in each cell cycle stage after exposure to protracted gamma irradiation. Three seedling types were investigated: 1) intact seedlings, 2) seedlings with cotyledons detached and treated with lanolin paste applied to the area of cotyledon excision, and 3) seedlings with detached cotyledons and treated with a G2 Factor applied to the area of cotyledon excision in lanolin paste. In intact seedling meristems, predominant cell arrest occurred with a 4C amount of DNA while 0.30 of the cells underwent endoreduplication to arrest with an 8C amount of DNA. Only 0.07 cells arrested with a 2C amount of DNA. Polyploid cells were produced several days after the start of irradiation and were derived from a diploid cell population. In seedlings exposed to lanolin only, without cotyledons, most cells arrested with a 2C amount of DNA with no polyploid cells. In seedlings exposed to a G2 Factor in lanolin after cotyledon excision, most cells arrested with a 4C amount of DNA but no cells underwent endoreduplication. These experimental results suggest that the G2 Factor derived from cotyledons of Pisum sativum was necessary for predominant cell arrest in G2 but alone was not sufficient for the polyploidization step.