Theodore T. Puck

The effects of x-irradiation have been quantitatively studied on single cells of a human cervical carcinoma (HeLa) under conditions such that 100 per cent of the unirradiated cells reproduce in isolation to form macroscopic colonies. This technique eliminates complexities due to interactions of members of large cell populations. Survival of single cells (defined as the ability to form a macroscopic colony within 15 days) yields a typical 2 hit curve when plotted against x-ray dose. The initial shoulder extends to about 75 r, after which a linear logarithmic survival rate is obtained, in which the dose needed to reduce survivors to 37 per cent is 96 r. This radiation sensitivity is tens to hundreds of times greater than that of any microorganism for which the equivalent function bas been studied. Evidence, though not proof, is presented that the lethal effect is due to a radiation-induced genetic defect which, however, cannot be a simple single gene inactivation. The locus of the action could be chromosomal. Beginning at doses of 100 r, or possibly earlier, growth-delaying effects of radiation are visible. Cells in which the ability to reproduce has been destroyed by doses below 800 r, can still multiply several times. At higher doses even a single cell division is precluded. A large proportion of the cells killed by radiation at any dose gives rise to one or more giant cells. These metabolize actively, grow to huge proportions but never reproduce under the experimental conditions employed. Methods of preparing large populations of giant cells are described. These giants are particularly susceptible to virus action. Some of the irradiated cells disappear from the plate, presumably by disintegration. This action of radiation is by far the least efficient, since even after 10,000 r, 5 to 10 per cent of the original cell inoculum is recoverable as giants.

Two methods for simple and rapid plating of single HeLa cells, human, carcinomatous cells, are described. These result in growth and formation of colonies from each single cell. One of these procedures uses irradiated, non-multiplying "feeder" cells to condition the medium. The second requires more gentle handling of the cells, but otherwise is virtually the same as that used in plating bacteria on semisolid, nutrient media. By extension of these methods, it is possible to isolate single mutant colonies and grow pure clonal stocks of animal cells. These genetically uniform strains are much more homogeneous in their behavior than the parental HeLa cell population. Growth curves obtained from developing colonies are highly reproducible. The most active mutant stocks so far isolated display a generation time of 18 to 20 hours. In pooled human serum HeLa cells assume a highly stretched, ameboid form, with marked motility; whereas growth of the same cells in a variety of non-human sera results in tightly packed, columnar, epithelial-like morphology. The two cell types possess volumes, nuclear cross-sections, plating efficiencies, and generation times which are identical within experimental error, but display widely different cross-sectional areas, suggesting that the basic change occurs in the cell surface. It is conceivable that this change may be related to that which enables the cells of a compact tumor to become invasive. Animal cells subjected to the standard trypsinization procedures which involve mechanical trauma and repeated washings in incomplete media leak large amounts of P and suffer impaired ability to reproduce as isolated cells. Application of the methods described in this paper as a tool for quantitative study of normal mammalian cell growth, physiology, genetics, and biochemistry, and the response of cells to drugs, viruses, high energy radiation, and other agents have been indicated.

A methodology designed to eliminate mitotic inhibitor action and involving use of pretested fetal calf serum and careful pH and temperature control has been described by which cells from normal human and animal tissue can be maintained in active growth for long periods in vitro without development of aneuploidy. By means of this procedure, it is possible reliably to establish cell cultures from minute skin biopsies which can be taken from any individual. Clones of mammalian cells with chromosomal markers have been isolated by this means from x-irradiated non-irradiated cell cultures. Application of these techniques to chromosome delineation in large numbers of human subjects; determination of chromosomal sex in patients; spontaneuos and induced genetic changes in somatic mammalian cells in vivo and in vitro; comparison of metabolic differences between normal and cancerous cells and other problems have been indicated.

Proceedings of the National Academy of Sciences (PNAS), a peer reviewed journal of the National Academy of Sciences (NAS) - an authoritative source of high-impact, original research that broadly spans the biological, physical, and social sciences.

Treatment of Chinese hamster ovary cells in vitro with dibutyrl adenosine cyclic 3':5'-monophosphate converts the culture from one of compact, randomly oriented cells that grow in multilayers to a monolayer of elongated, fibroblast-like cells growing parallel to one another. Testosterone propionate, which has a similar though smaller effect at high concentrations and after prolonged incubation, potentiates the action of dibutyryl cyclic AMP even when added at very low concentrations. The transformation is recognizable within one hour, affects cells throughout all or most of the life cycle, and is completely reversible. Both cell forms can reproduce, with approximately the same generation time. Agents like colcemid and vinblastine, which inhibit assembly of microtubules, prevent the transformation to the fibroblast-like form. It is postulated that the dibutyryl cyclic AMP and testosterone act by promoting organization of microtubules from protein monomers.