Regrowth kinetics of cells from different regions of multicellular spheroids of four cell lines

A basic understanding of the recruitment of quiescent tumor cells into the cell would be an important contribution to tumor biology and therapy. As a first step in pursuing this goal, we have investigated the regrowth kinetics of cells from different regions in multicellular spheroids of rodent and human origin. Cells were isolated from four different depths within the spheroids using a selective dissociation techinque. The outer cells were proliferating and resumed growth after replating with a 0–8‐hour lag period, similar to cells from exponentially growing monolayers. with increasing depth of origin, the lag periods prior to regrowth increased to 2–3 times the monolayer doubling time; cells from plateau‐phase monolayers showed a lag period of 1–1.5 times the doubling period. After resuming grwoth, all cells of a given cell line grew with the same doubling time and achieved the same confluency level. The inner spheroid cells and cells from plateau‐phase monolayers had reduced clonogenic efficiencies. The inner cells were initially 1.5–3 times smaller than the outer cells, but began to increase in volume within 4 hours of replating. The fractions of S‐phase cells were greatly decreased with increasing depth of origin in the spheroids; there were long delays prior to s‐phase recovery after plating, to a maximum of 1–1.5 times the normal doubling time. These results suggest that those quiescent cells from spheroids and monolayers which are able ot reenter the cell cycle are predominantly in the G1‐phase. However, quiescent cells from the innemost spheroid region require approximately twice as long ot enter normal cell cycle traverse as cells from plateau‐phase monolayers. The selective dissociation method can isolate very pure populations of proliferating and quiescent cells in a rapid and nonpeturbing manner; this system will be valuable in further characterizing quiescent cells from spheroids.

[1]  J P Freyer,et al.  A model for the growth of multicellular spheroids , 1982, Cell and tissue kinetics.

[2]  P. Keng,et al.  Radiation response of proliferating and quiescent subpopulations isolated from multicellular spheroids. , 1986, British Journal of Cancer.

[3]  P. Keng,et al.  Regrowth and radiation sensitivity of quiescent cells isolated from EMT6/Ro-fed plateau monolayers. , 1985, Cancer research.

[4]  P. Keng,et al.  Isolation of quiescent cells from multicellular tumor spheroids using centrifugal elutriation. , 1982, Cancer research.

[5]  Partial purification of a protein growth inhibitor from multicellular spheroids. , 1988, Biochemical and biophysical research communications.

[6]  L. S. Cram,et al.  An improved flow microfluorometer for rapid measurement of cell fluorescence. , 1973, Experimental cell research.

[7]  C. Stiles,et al.  An ordered sequence of events is required before BALB/c-3T3 cells become committed to DNA synthesis. , 1978, Proceedings of the National Academy of Sciences of the United States of America.

[8]  G. Todaro,et al.  Isolation of tumor cell growth-inhibiting factors from a human rhabdomyosarcoma cell line. , 1985, Cancer research.

[9]  R. Tobey Production and characterization of mammalian cells reversibly arrested in G1 by growth in isoleucine-deficient medium. , 1973, Methods in cell biology.

[10]  G. Barendsen,et al.  Changes of cell proliferation characteristics in a rat rhabdomyosarcoma before and after x-irradiation. , 1969, European journal of cancer.

[11]  L. R. Gurley,et al.  An Improved Sum‐Of‐Normals Technique For Cell Cycle Distribution Analysis of Flow Cytometric Dna Histograms , 1981, Cell and tissue kinetics.

[12]  J P Freyer,et al.  Proliferative and clonogenic heterogeneity of cells from EMT6/Ro multicellular spheroids induced by the glucose and oxygen supply. , 1986, Cancer research.

[13]  W. Düchting,et al.  Modeling and simulation of growing spheroids. , 1984, Recent results in cancer research. Fortschritte der Krebsforschung. Progres dans les recherches sur le cancer.

[14]  R. Higashikubo,et al.  Murine Mammary Tumour Cells In Vitro. I. the Development of A Quiescent State , 1984, Cell and tissue kinetics.

[15]  R E Durand,et al.  CELL CYCLE KINETICS IN AN IN VITRO TUMOR MODEL , 1976, Cell and tissue kinetics.

[16]  R. Sutherland Cell and environment interactions in tumor microregions: the multicell spheroid model. , 1988, Science.

[17]  A. Richmond,et al.  Purification of melanoma growth stimulatory activity , 1986, Journal of cellular physiology.

[18]  L. Mallucci,et al.  Properties of a cell growth inhibitor produced by mouse embryo fibroblasts , 1983, Journal of cellular physiology.

[19]  R. Higashikubo,et al.  Murine Mammary Tumour Cells In Vitro. Ii. Recruitment of Quiescent Cells , 1984, Cell and tissue kinetics.

[20]  R. Durand Isolation of cell subpopulations from in vitro tumor models according to sedimentation velocity. , 1975, Cancer research.

[21]  R. Coffey,et al.  Transforming growth factors and control of neoplastic cell growth , 1987, Journal of cellular biochemistry.

[22]  J. Freyer Role of necrosis in regulating the growth saturation of multicellular spheroids. , 1988, Cancer research.

[23]  Deakin As,et al.  Model for the growth of a solid in vitro tumor. , 1975 .

[24]  W. House,et al.  Detection of mycoplasma in cell cultures. , 1967, The Journal of pathology and bacteriology.

[25]  J. Freyer,et al.  Regulation of growth saturation and development of necrosis in EMT6/Ro multicellular spheroids by the glucose and oxygen supply. , 1986, Cancer research.

[26]  J P Freyer,et al.  Selective dissociation and characterization of cells from different regions of multicell tumor spheroids. , 1980, Cancer research.

[27]  J. Yuhas,et al.  Cytophotometric measurement of the cellular DNA content of [3H]thymidine-labelled spheroids. Demonstration that some non-labelled cells have S and G2 DNA content. , 1983, Cell and tissue kinetics.

[28]  J P Freyer,et al.  A reduction in the in situ rates of oxygen and glucose consumption of cells in EMT6/Ro spheroids during growth , 1985, Journal of cellular physiology.

[29]  J. M. Taylor,et al.  The hazard of accelerated tumor clonogen repopulation during radiotherapy. , 1988, Acta oncologica.

[30]  R. Durand Use of Hoechst 33342 for cell selection from multicell systems. , 1982, The journal of histochemistry and cytochemistry : official journal of the Histochemistry Society.

[31]  W. Wharton Hormonal regulation of discrete portions of the cell cycle: Commitment to DNA synthesis is commitment to cellular division , 1983, Journal of cellular physiology.

[32]  T. Chen,et al.  In situ detection of mycoplasma contamination in cell cultures by fluorescent Hoechst 33258 stain. , 1977, Experimental cell research.

[33]  H. Dertinger,et al.  A comparative study of post-irradiation growth kinetics of spheroids and monolayers. , 1975, International journal of radiation biology and related studies in physics, chemistry, and medicine.