Separation of cells from a murine fibrosarcoma on the basis of size. I. Relationship between cell size and age as modified by growth in vivo or in vitro

Overview of Cell Synchronization

The widespread interest in cell synchronization is maintained by the studies of control mechanism involved in cell cycle regulation. During the synchronization distinct subpopulations of cells are obtained representing different stages of the cell cycle. These subpopulations are then used to study regulatory mechanisms of the cycle at the level of macromolecular biosynthesis (DNA synthesis, gene expression, protein synthesis), protein phosphorylation, development of new drugs, etc. Although several synchronization methods have been described, it is of general interest that scientists get a compilation and an updated view of these synchronization techniques. This introductory chapter summarizes: (1) the basic concepts and principal criteria of cell cycle synchronizations, (2) the most frequently used synchronization methods, such as physical fractionation (flow cytometry, dielectrophoresis, cytofluorometric purification), chemical blockade, (3) synchronization of embryonic cells, (4) synchronization at low temperature, (5) comparison of cell synchrony techniques, (6) synchronization of unicellular organisms, and (7) the effect of synchronization on transfection.

Overview of cell synchronization

Widespread interest in cell synchronization is maintained by the studies of control mechanisms involved in cell cycle regulation. During the synchronization distinct subpopulations of cells are obtained representing different stages of the cell cycle. These subpopulations are then used to study regulatory mechanisms of the cycle at the level of macromolecular biosynthesis (DNA synthesis, gene expression, protein synthesis), protein phosphorylation, development of new drugs, etc. Although several synchronization methods have been described, it is of general interest that scientists get a compilation and an updated view of these synchronization techniques. This introductory chapter summarizes: (1) the basic concepts and principal criteria of cell cycle synchronizations, (2) the most frequently used synchronization methods, such as physical fractionation (flow cytometry, dielectrophoresis, cytofluorometric purification), chemical blockade, (3) synchronization of embryonic cells, (4) synchronization at low temperature, (5) comparison of cell synchrony techniques, (6) synchronization of unicellular organisms, and (7) the effect of synchronization on transfection.

Evaluation of cell subpopulations isolated from human tumor xenografts by centrifugal elutriation

Human epidermoid tumor cells (Coll2, ME180, A431, HEp3) grown as xenografts in nude mice, were dissociated into single cell suspensions using an enzyme cocktail containing 0.025% collagenase, 0.05% pronase, and 0.04% DNase. The dissociated cell suspensions were separated by centrifugal elutriation into fractions containing homogeneous cell subpopulations primarily based on the differences in the rates of sedimentation. The quality of separation was evaluated by several techniques including flow cytometry, cell volume distributions, in vitro colony forming assay and morphological examination of Wright-Giemsa stained cells. In each separated fractions, the host to neoplastic cell ratio, the DNA ploidy, the plating efficiency and the cell cycle distribution were determined. After an initial separation of non-neoplastic host cells from malignant cells, a purity of greater than 95% host cells was obtained from the four xenografts studied. DNA analysis of tumor suspensions showed that neoplastic cells of different xenografts contained aneuploid cells with a DNA index of 1.51 to 1.95. The neoplastic cells were further separated into fractions according to their positions in the cell cycle. Fractions containing greater than 95% G1, 65% S, and 72% G2M cells were obtained from HEp3 xenografts. Less efficient separation with respect to cell cycle was attained with cells derived from Coll2, ME180, and A431 xenografts. Colony forming abilities of the neoplastic cells were determined at different phases of the cell cycle and found to be similar to those of the unseparated cell suspensions after corrections for non-neoplastic host cells were made. These investigations indicate that centrifugal elutriation is an effective technique of obtaining homogeneous subpopulations of cells from human tumor xenografts for various tumor biology and cell kinetics studies.

Metastatic abilities of murine sarcomas and carcinomas. II. Relationship to cell volume and DNA index

The cell volume and DNA content were determined in 12 murine tumors and correlated with the ability of these tumors to metastasize spontaneously or to form lung nodules when injected i.v. The cell volume significantly correlated with spontaneous metastatic potential of investigated tumors (r = 0.683; 0.02 less than P less than 0.05) but not with the ability of tumor cells to form artificial metastasis. The DNA index significantly correlated with both spontaneous metastasis (r = 0.594; 0.02 less than P less than 0.05), and lung colonization (r = 0.631; 0.02 less than P less than 0.05). The DNA index barely correlated with the cell volume (r = 0.564; P = 0.10).

Plasminogen activator activity in clonogenic cell populations separated from a murine fibrosarcoma

Tumor cells from a murine fibrosarcoma (FSa) produce plasminogen activator (PA), a protease that converts the zymogen plasminogen into the trypsin-like enzyme plasmin. Several studies indicate that tumor cell invasion is accompanied by proteolysis and that PA, generated by highly malignant cells, is by far the most ubiquitous protease associated with malignant transformation. Subpopulations of FSa cells were isolated by using density gradient centrifugation and the ability of these populations to form lung colonies was compared with their associated levels of PA production. Five populations of cells from a murine fibrosarcoma were separated in continuous gradients of Renografin in the density range 1.05-1.18 g/cm2. The PA activities of an unseparated control cell lysate and cell lysates of the five separated populations were determined by using [125I]fibrin as a substrate in a reaction between cell lysate and plasminogen. The assay was based on the release of digested [125I]fibrin from the surface of Petri dishes into the supernatant solution, and the results were expressed as a percentage of the total radioactivity. The cell populations collected at densities of 1.05 and 1.09 (B1, B2) were the more clonogenic with relative clonogenic efficiencies of 2.6 and 3.3 times that of the unseparated tumor population, respectively. Analysis for PA demonstrated that enzyme formation was restricted mostly to these two populations. Cells from populations 4 and 5 did not secrete increased amounts of PA and had reduced clonogenic efficiencies compared with the unseparated FSa control population. These results are consistent with the hypothesis that PA activity is correlated with the clonogenicity of tumor subpopulations isolated from a heterogeneous and complex tumor system such as the FSa.

Characterization of radiation resistant hypoxic cell subpopulations in KHT sarcomas. (I). Centrifugal elutriation

Studies were performed to determine the location, with respect to cell cycle phase, of the radiobiologically hypoxic cells in KHT sarcomas. Cells dispersed from solid KHT tumours were separated into subpopulations at different stages of the cell cycle by centrifugal elutriation. Flow cytometric analysis of the DNA content of these subpopulations indicated that the degree of synchrony that could be achieved was greater than or equal to 95% for G1 cells, 70-75% for S cells and 70-75% for G2M cells. The approach to locate and characterize hypoxic cells was based on the premise that due to their lack of oxygen such cells would preferentially survive radiation treatment. Consequently KHT sarcomas were irradiated in situ either in dead animals or in animals breathing air. Following treatment, the tumours were dissociated, the cells elutriated into the various phases of the cell cycle and clonogenic cell survival was determined. Complete dose-response curves were determined for cells in the G1, S and G2M cell cycle phases. The various cell cycle subpopulations obtained from tumours irradiated while mice breathed air, all demonstrated survival curves with a break and final slope which paralleled that of the corresponding anoxic cell survival curve. From these curves the proportion of hypoxic tumour cells in the G1 phase was calculated to be 10.1 +/- 1.7%. Because the elutriated S and G2M enriched cell fractions were to some extent contaminated by cells from other phases of the cell cycle, the percentage of hypoxic S and G2M tumour cells was estimated to range from 0-7% and 0-5% respectively. However, since G1 cells comprised the majority of all the neoplastic cells in these tumours, the data suggest that hypoxic cells in KHT sarcomas are found primarily in this cell cycle stage.

Density distributions of human squamous carcinoma cells: influence of growth conditions, proliferative status and DNA content

Human squamous carcinoma cells (A431, CaSki) were grown in vitro as multicellular spheroids or as exponential and plateau-phase monolayer cultures. Single-cell suspensions were obtained by disaggregating the spheroids and monolayer cultures with trypsin-EDTA. Their buoyant density distributions were then compared by centrifuging the suspensions for 30 min at about 800gave and 4 degrees C in linear, continuous Percoll gradients. We found differences in buoyant density related to the growth condition (i.e. cells grown as spheroids or plateau-phase cultures were more dense than those from exponential cultures) and to the cell-line (i.e. CaSki cells were more dense than the A431 cells). Cells isolated from the inner layers of the spheroids appeared to be less dense than those from the outer layers. In addition, quiescent cells separated from the A431 spheroids by centrifugal elutriation, a technique based on cell size, were more dispersed in buoyant density than the corresponding proliferating cells recovered from the same spheroids. Flow cytometric analysis with mithramycin was performed to measure the DNA content of the cells. We found that the CaSki cells contained relatively more DNA than the A431 cells whereas, for the same cell line, growth as monolayer cultures or as multicellular spheroids did not influence their relative DNA content. We conclude that the growth conditions, the proliferative status of the cells and possibly their relative DNA content may influence the density distribution of these cells.

In situ radiation response and oxygen enhancement ratio of KHT sarcoma cells in various phases of the cell cycle

Studies were performed to evaluate the radiation response across the cell cycle of KHT sarcoma cells grown as solid tumours. Centrifugal elutriation, a relatively non-perturbing method for synchronising cells, was used to obtain homogeneous populations of cells with respect to their positions in the cell cycle from suspensions prepared directly from KHT tumours. More than 90% of the non-neoplastic cells were removed and the tumour cells separated into fractions containing 90-95% G1 cells, 70-75% S cells and 70-75% G2M cells. Since survival following in situ irradiation is influenced by the presence and proportion of oxygen-deficient or hypoxic tumour cells, in order to study the radiation response across the cell cycle, KHT sarcoma cells were irradiated under conditions of uniform oxygenation. This was achieved by irradiating the tumour cells either in situ in dead animals or, in vitro, after tumour dissociation and cell separation, while fully oxic or anoxic. Under all these conditions, the most radioresistant portion of the cell cycle was found to be late G1 and early S. G2M were always most radiosensitive. Complete radiation dose-response curves under oxic or anoxic conditions were also obtained for cells in all phases of the cell cycle. From these the oxygen enhancement ratio (OER) was calculated to be 2.4, 2.6 and 2.5 for cells in the G1, S and G2M cell cycle phases respectively.

Effectiveness of AMSA alone or in combination with radiation on murine fibrosarcoma pulmonary nodules

The cytotoxic effects in vivo of 4'-(9-acridinylamino) methanesulfon-m-anisidide (AMSA), radiation or both modalities in combination on murine fibrosarcoma (FSa) cells grown as pulmonary tumors were determined. Fourteen days following the i.v. injection of viable FSa cells, recipient mice developed between 100 and 150 visible pulmonary nodules. At that time, tumor-bearing animals were exposed to either single or combined modality treatments, as well as single and fractionated dose regimens. Animals were sacrificed 1 hour after the last treatment. Tumor nodules were excised, made into a single cell suspension and separated on the basis of cell size by centrifugal elutriation. Flow microfluorometry (FMF) was used to determine the cell-cycle parameters and the relative synchrony of the separated populations, as well as the percentage contamination by normal diploid cells in each of the tumor cell populations. Known numbers of viable cells from each elutriator fraction were injected into recipient mice to determine their colony-forming efficiency (CFE). Surviving fractions were determined by comparing the CFEs of treated FSa cells from each of the separated elutriator fractions with those of appropriate untreated controls. Following a single i.v. dose of AMSA (30 mg/kg), populations of cells enriched in S phase were the most sensitive. When a single dose of AMSA was combined with a single dose of radiation (100 rad), there was a marked schedule dependence with the more effective sequence, especially if a 12 hour interval was chosen between doses, being AMSA followed by irradiation. No schedule dependence was observed if both modalities were combined and administered under a fractionated protocol of four fractions of AMSA (5 mg/kg per fraction) and four fractions of radiation (300 rad per fraction). Under these conditions the greatest reduction in CFE was in cell subpopulations most enriched in S and G2 + M phase cells.

Cytotoxic effects of vincristine on tumour subpopulations separated from pulmonary nodules

The cytotoxic and stathomokinetic effects of vincristine (VCR) on murine fibrosarcoma (FSa) cells, grown either in vitro as primary cultures or in vivo as micro- or macroscopic pulmonary nodules, were determined and compared. FSa cells were separated and synchronized on the basis of size by centrifugal elutriation. Flow microfluorometry (FMF) was used to determine the cell-cycle parameters and the relative synchrony of the separated populations, thus allowing determination of age-dependent cytotoxicity. The colony-forming efficiencies (CFE) of these cells were determined using a lung colony assay. Synchronized cell population of FSa cells, separated by centrifugal elutriation, were injected into recipient animals and exposed 20 min later to a single dose of VCR to determine their age-specific sensitivity. Under these conditions there appeared to be a suggestion of an enhanced killing of cells enriched in the G2 + M phase. However, following prolonged VCR exposure in vitro (e.g., 2.5 micrograms ml-1; 25 ml for 24 h) to primary cultures of FSa cells or in vivo (e.g., 0.25 mg kg-1 per fraction i.p.; 5 fractions in 24 h) to macroscopic pulmonary tumour nodules, elutriated FSa cell populations most enriched with G1 phase cells exhibited the lowest CFE. If under either condition exposed cells were allowed to recover in the absence of VCR for 24 h prior to their removal and separation, FSa cell survival increased in each of the elutriated populations. In contrast, while G1 enriched cell populations from in vitro exposed cultures still exhibited a significant reduction in CFE, no such age-specific response was observed for in vivo exposed macroscopic pulmonary nodules. The stathomokinetic effect of VCR on FSa cells was also readily observed in vitro using FMF analysis (e.g., an increase of from 20 to 38% in the G2 + M phase compartment). While no such effect was observed in vivo using FMF analysis, cluster of mitotic figures were observed. The mitotic indices (MI) of the in vivo exposed FSa cells increased from 2.5 to 8.4%.

Treatment of artificially-induced pulmonary metastases with fractionated doses of vincristine and/or radiation therapy

The cytotoxic effects in vivo of vincristine (VC), radiation, or both modalities in combination on murine fibrosarcoma (FSa) cells grown as pulmonary tumors were determined. Fourteen days following the i.v. injection of viable FSa cells, recipient mice developed between 100 and 150 visible pulmonary nodules. At that time, tumor-bearing animals were exposed to either single or combined modality treatments, as well as single and fractionated dose regimens. Animals were sacrificed 1 hour after the last treatment. Tumor nodules were excised and made into a single cell suspension and separated on the basis of cell size by centrifugal elutriation. Flow microfluorometry (FMF) was used to determine the cell-cycle parameters and the relative synchrony of the separated populations, as well as the percentage contamination by normal diploid cells in each of the tumor cell populations. Known numbers of viable cells from each elutriator fraction were injected into recipient mice to determine their colony-forming efficiency (CFE). Surviving fractions were determined by comparing the CFEs of treated FSa cells from each of the separated elutriator fractions with those of appropriate untreated controls. Following a single dose of VC (1 mg/kg), populations of cells enriched in late S and G2 + M were the most sensitive. However, following the administration of five doses (0.25 mg/kg each) over a 24 hour period, populations of cells most enriched in G1 cells exhibited the lowest percentage of survivors. A single dose of radiation (1000 rad) was most effective in killing S-phase cells. When administered in five fractions (250 rad per fraction), each separated by a 6 hour interval, no phase-specific sensitivity was observed. The combination of both modalities exhibited a marked schedule dependence, with a single dose (1000 rad) of radiation followed by five doses of VC (0.25 mg/kg) being the most effective treatment protocol observed.

Phase-specific cytotoxicity in vivo of hydroxyurea on murine fibrosarcoma pulmonary nodules

The cytotoxic effects in vivo of hydroxyurea (HU) on murine fibrosarcoma (FSa) cells grown as pulmonary tumours were determined. Tumour cells from 13-day-old nodules were made into suspension and separated on the basis of cell size by centrifugal elutriation. Flow microfluorometry (FMF) was used to determine the cell-cycle parameters and the relative synchrony of the separated populations, as well as the degree of contamination by normal diploid cells in each of the tumour-cell populations. HU cytotoxicity was tested by administering both a single 1 mg/g i.p. dose into mice that had been injected i.v. 20 min earlier with known numbers of synchronized viable FSa cells, and i.p. doses of 1 mg/g each into mice bearing 13-day-old pulmonary nodules. In the latter experiments, animals were killed 1 h after the last dose, and the tumour nodules were excised and made into a single-cell suspension and elutriated. Known numbers of cells from each fraction were injected into recipient mice to determine survival. In both sets of experiments, cell killing by HU correlated with the percentage of S-phase cells. The treatment of 13-day-old pulmonary nodules with 3 doses of HU also depleted the (G2+M) phase tumour cells and increased the heterogeneity between tumour subpopulations, as determined by FMF analysis.

Shedding of mitotic cells from the surface of multicell spheroids during growth

During the growth of EMT6/Ro mammary tumor multicell spheroids, a large number of cells are shed into the suspension medium. The rate of cell shedding was 218 cells per square millimeter of spheroid surface per hour, or up to 1.5% of the total spheroid cell content per hour. Shed cells had a clonogenic capacity equal to that of exponential monolayer cultures and were further characterized by volume distribution, mitotic index, flow cytofluorometry, and autoradiography. The results indicated that cells are released from the spheroid surface at mitosis, presumably due to a loosening of the cell-to-cell attachment during this cycle phase. These mitotic cells, when placed in monolayer culture, attached and grew synchronously with a cell cycle time of about 13 hours. Shed cells kept in suspension culture had a similar cell cycle time, but these cells reaggregated immediately after mitosis. The results indicated that cell shedding and reaggregation both occur near the time of mitosis and are intrinsic factors regulating the initiation and subsequent growth of multicell spheroids. Although these studies were done with spheroids cultured in vitro, shedding of mitotic cells may play an important role in the in vivo process of metastasis.

Cytotoxic effect in vivo of selected chemotherapeutic agents on synchronized murine fibrosarcoma cells

The cytotoxic effects in vivo of single doses of either adriamycin (ADM), 1-beta-D-arabinofuranosylcytosine (Ara-C), bleomycin (BLM), cis-diamminedichloroplatinum (II) (cis-DDP), or cyclophosphamide (CY) on murine fibrosarcoma (FSa) cell populations were determined. Tumour cells were separated and synchronized by centrifugal elutriation. Viable tumour cells from selected elutriator fractions were then injected i.v. into whole-body-irradiated mice. Twenty minutes later selected doses of ADM, Ara-C, BLM, cis-DDP or CY were administered to selected groups of these animals. Fourteen days later the mice were killed. Killing of injected tumour cells by each of the chemotherapeutic agents was evidenced by a reduction in the lung cells by each of the chemotherapeutic agents was evidenced by a reduction in the lung colonies per cell injected in treated animals. Under these conditions the response of FSa cells in vivo to the 5 drugs tested differed both qualitatively and quantitatively. Ara-C was S-phase-specific in toxicity. ADM, BLM, and cis-DDP were preferentially toxic to S, G2+M and G1 cells respectively. CY, a drug requiring bioactivation to form alkylating metabolites, was found to be equally toxic to G1 and G2+M enriched populations, but less effective in killing cell populations enriched with early-S cells.

Synchronization of 9L rat brain tumor cells by centrifugal elutriation

Asynchronous 9L cells were separated into relatively homogeneously-sized populations using centrifugal elutriation with both a conventional collection method and a long collection method. A substantial increase in the homogeneity of the volume distributions and in the degree of synchrony of the separated fractions was obtained using the long collection method. Autoradiographic data indicated that fractions containing greater than or equal to 97% G1 cells, greater than or equal to 80% S cells, and 70-75% G2 cells could be routinely recovered with this procedure. Recovery in these fractions varied from 5 to 8% of the total number of cells elutriated. The colony forming efficiency (CFE) of cells from fractions representing each phase of the cell cycle was a constant 60-70%, which was comparable to the 60-80% usually found for asynchronous 9L cells. The percentage of cells in the G1, S, and G2 phases in the elutriated fractions was more accurately determined from the volume distribution than from computer fits of the DNA histogram obtained from flow cytometry. In genereal, the degree of synchrony was related to the coefficient of variation (CV) of the volume distributions of the elutriated fractions. The CV was about 14% for all elutriated fractions. When the greater than or equal to 97% G1 population was allowed to progress to S and G2, the CVs were about 17 and 20.2%, respectively. Thus, the best nonperturbing method for obtaining synchronous 9L cells in the S or G2 phases was direct elutriation with the long collection method.

Arrest and metastasis of blood-borne tumor cells are modified by fusion of plasma membrane vesicles from highly metastatic cells

B16 mouse melanoma sublines in culture spontaneously shed intact plasma membrane vesicles. These vesicles can be fused with the plasma membrane of cells from homologous and heterologous B16 sublines by using polyethylene glycol and phytohemagglutinin-P. Fusion of vesicles from a highly metastatic subline (F10) that localizes exclusively in the lung with cells from a poorly metastatic subline (F1) significantly increased the ability of F1 cells to become arrested in the lung and form metastases in this organ. In contrast, fusion of F1 vesicles with F10 cells did not alter the ability of vesicle-modified cells to localize in the lung or form lung metastases. F10 vesicle-modified F1 cells reverted to their original arrest behavior and metastatic capacity after removal of F10 vesicle components from the plasma membrane. The changes in the arrest and metastatic behavior of F10 vesicle-modified F1 cells were highly highly specific. Vesicles from other B16 sublines that are poorly metastatic and show limited localization in the lung (F1, FLLr, and F10Lr) did not modify the arrest behavior and metastatic capacity of FU cells. These results suggest that the differences in the abilities of the F1 and F10 sublines to localize in the lung are determined by differences in cell surface properties.

Centrifugal elutriation (counterstreaming centrifugation) of cells

Lindahl first described the separation of cells by velocity sedimentation utilizing a special technique (counterstreaming centrifugation) that was later modified slightly and renamed centrifugal elutriation. Centrifugal elutriation has been applied, with variable degrees of success, to the separation of hemopoietic cells, mouse tumor cells, testicular cells, and a variety of other specialized cells as well as cells in particular phases of the cell cycle. The capacity of the elutriator to separate large numbers of cells is its chief advantage. The purities of the separated cells have not been compared with the purities of cells separated by other methods in most cases; such comparisons would permit more sophisticated comparison of elutriation with other techniques for velocity sedimentation.