ACTION OF X-RAYS ON MAMMALIAN CELLS

doi:10.1084/jem.103.5.653

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The Journal of Experimental Medicine, Vol 103, 653-666, Copyright, 1956, by The Rockefeller Institute for Medical Research New York

ARTICLE

ACTION OF X-RAYS ON MAMMALIAN CELLS

Theodore T. Puck Ph.D.¹ and Philip I. Marcus ¹

¹ From the Department of Biophysics, Florence R. Sabin Laboratories, University of Colorado Medical Center, Denver

The effects of x-irradiation have been quantitatively studiedon single cells of a human cervical carcinoma (HeLa) under conditionssuch that 100 per cent of the unirradiated cells reproduce inisolation to form macroscopic colonies. This technique eliminatescomplexities due to interactions of members of large cell populations.

Survivalof single cells (defined as the ability to form a macroscopiccolony within 15 days) yields a typical 2 hit curve when plottedagainst x-ray dose. The initial shoulder extends to about 75r, after which a linear logarithmic survival rate is obtained,in which the dose needed to reduce survivors to 37 per centis 96 r. This radiation sensitivity is tens to hundreds of timesgreater than that of any microorganism for which the equivalentfunction bas been studied.

Evidence, though not proof, is presentedthat the lethal effect is due to a radiation-induced geneticdefect which, however, cannot be a simple single gene inactivation.The locus of the action could be chromosomal.

Beginning at dosesof 100 r, or possibly earlier, growth-delaying effects of radiationare visible.

Cells in which the ability to reproduce has beendestroyed by doses below 800 r, can still multiply several times.At higher doses even a single cell division is precluded.

Alarge proportion of the cells killed by radiation at any dosegives rise to one or more giant cells. These metabolize actively,grow to huge proportions but never reproduce under the experimentalconditions employed. Methods of preparing large populationsof giant cells are described. These giants are particularlysusceptible to virus action.

Some of the irradiated cells disappearfrom the plate, presumably by disintegration. This action ofradiation is by far the least efficient, since even after 10,000r, 5 to 10 per cent of the original cell inoculum is recoverableas giants.

Submitted on February 2, 1956

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