Variations in Several Responses of HeLa Cells to X-Irradiation during the Division Cycle

Several responses of synchronized populations of HeLa S3 cells were measured after irradiation with 220 kev x-rays at selected times during the division cycle. (1) Survival (colony-forming ability) is maximal when cells are irradiated in the early post-mitotic (G(1)) and the pre-mitotic (G(2)) phases of the cycle, and minimal in the mitotic (M) and late G(1) or early DNA synthetic (S) phases. (2) Markedly different growth patterns result from irradiation in different phases: (a) Prolongation of interphase (division delay) is minimal when cells are irradiated early in G(1) and rises progressively through the remainder of the cycle. (b) Cells irradiated while in mitosis are not delayed in that division, but the succeeding division is delayed. (c) Persistence of cells as metabolizing entities does not depend on the phase of the division cycle in which they are irradiated. (3) Characteristic perturbations of the normal DNA synthetic cycle occur: (a) Cells irradiated in M suffer a small delay in the onset of S, a slight prolongation of S, and a slight depression in the rate of DNA synthesis; the major delay occurs in G(2). (b) Cells irradiated in G(1) show no delay in the onset of S, and essentially no alteration in the duration or rate of DNA synthesis; G(2) delay is minimal. (c) Cells irradiated in S suffer an appreciable S prolongation and a decreased rate of DNA synthesis; G(2) delay is shorter than S delay

Time-Lapse Cinemicrographic Studies of X-Irradiated HeLa S3 Cells: I. Cell Progression and Cell Disintegration

Time-lapse cinemicrographs of synchronous HeLa S3 cells irradiated with 220 kv X-rays at various stages of interphase provided data for constructing pedigrees, measuring the duration of both generation cycles and mitoses, and scoring events associated with cell disintegration for up to seven postirradiation generations. The onset of the first mitosis after doses of 500 rads was delayed as expected from previous studies of the age dependence of “mitotic delay.” The interval between this first mitosis and the next was indistinguishable from that for unirradiated control cells, while the subsequent two generations were again prolonged, on the average, though not so severely as was the irradiated generation. The duration of mitosis was increased proportionally more than interphase. Cell disintegration took place by way of two morphologically distinct processes. In three-quarters of the cases the cells were rounded and apparently trapped in metaphase when they disintegrated; the remaining disintegrations occurred in spread, interphase cells. In cells disintegrating from the rounded configuration, the generation preceding disintegration was prolonged relative to that in cells which divided; in cells disintegrating from either configuration, the penultimate generation was also prolonged. The mitotic times were disproportionately increased in both of these generations. It is suggested that in this system X-ray damage is preferentially expressed as derangement of the mitotic process; such damage ultimately brings about permanent mitotic arrest in the majority of cells

Time-Lapse Cinemicrographic Studies of X-Irradiated HeLa S3 Cells: II. Cell Fusion

Analysis of time-lapse cinemicrographs of X-irradiated HeLa S3 cells has shown that the incidence of cell fusion was increased from 0.9% (following 1267 divisions) in control cells to an average of 22% (following 655 divisions) in cells irradiated with 500 rad doses of 220 kv X-rays. The incidence depended on the stage of the generation cycle at which the parent cells were irradiated. It was nearly constant in the first three postirradiation generations. Fusion occurred at all stages of the generation cycle, but preferentially during the first 20%. Cells undergoing fusion progressed more slowly through the generation cycle and had a higher probability of disintegrating than did irradiated cells that did not fuse. The occurrence of fusion was clonally distributed in the population. It took place only between sister (or closely related) cells. Protoplasmic bridges were often visible between sister cells prior to fusion. Giant cells arose only as a result of fusion. The incidence of multipolar divisions, though higher than in unirradiated cells, was only 5.5% in cultures irradiated with 500 rads. Fusion occurred following 85% of the multipolar divisions and was often followed by a multipolar division

Lethal response of HeLa cells to x-irradiation in the latter part of the generation cycle.

The age-response for the killing of HeLa S3 cells by X-rays during the latter part of the generation cycle has been examined in detail. As synchronous cells move from the G1/S boundary through S phase, the relatively high sensitivity of late G1 cells gradually decreases; minimum sensitivity is reached in mid-S and maintained during the remainder of that phase. The response of cells as they progress from S to the point in G2 at which they are temporarily arrested by radiation (or by inhibitors of protein synthesis) was measured in populations free of both S phase cells and late G2 cells that had passed the arrest point: cells retain their high resistance from early G2 up to the arrest point. The response of G2 cells that have passed the arrest point before being irradiated was examined by exposing randomly growing cultures to X-rays and collecting cells periodically thereafter, as they entered mitosis. Survival values very close to those of sensitive mitotic cells were found in the 2 h period after irradiation during which unarrested cells continued to reach mitosis. Values typical of lateS/early G2 were found only after cells that had been arrested began arriving at mitosis. Thus, HeLa S3 cell undergo an abrupt increase in sensitivity at or near the arrest point. The sensitivity to a second irradiation of cells arrested in G2 by a conditioning X-ray dose increases rapidly in the early part of the arrest period

Modification of X-Ray-Induced Killing of HeLa S3 Cells by Inhibitors of DNA Synthesis

After irradiation of HeLa S3 cells with 220 kv x-rays during G1, treatment with any of six inhibitors of DNA synthesis results in the progressive enhancement of cell killing (loss of colony-forming ability). Incubation with hydroxyurea, cytosine arabinoside, or hydroxylamine reduces survival five- to twentyfold in about 8 hr, following an x-ray dose of 400 rads. In contrast, treatment with 5-fluorodeoxyuridine, deoxyadenosine, or thymidine after this same dose reduces survival less than twofold during a comparable time interval. These differences occur at drug concentrations which reduce the rate of DNA synthesis by at least 95% (except in the case of hydroxylamine, which inhibits DNA synthesis to a smaller extent), but which kill no unirradiated cells during the treatment periods. When inhibition of DNA synthesis with either hydroxyurea or cytosine arabinoside is reversed by addition of appropriate precursors of DNA, the enhancement is abolished. With hydroxyurea, the rate of cell killing is dependent on the dose of x-rays previously administered, and the extent of enhancement seems to be related to the drug concentration. Imposition of a delay between irradiation and addition of hydroxyurea does not abolish the enhancement effect, but instead causes a proportional lag in its inception. Postirradiation treatment of S phase cells with either hydroxyurea or cytosine arabinoside also enhances killing. Furthermore, unlike early G1 cells, S cells (and, as shown previously, cells blocked at the G1-S transition) are sensitized by preirradiation exposure to hydroxyurea