Measuring cell proliferation by relative movement. I. Introduction and in vitro studies

Abstract

This paper presents two new ways of analysing data which may be obtained from pulse labelling a population of cells with bromodeoxyuridine and analysing that population as a function of time with bivariate flow cytometry. The progression of cells is measured by the change in position in the cell cycle, as shown by a change in the mean DNA content of the labelled and unlabelled cells. The particular measures of the mean DNA content used are extensions of the relative movement of the labelled undivided cells, RM^lu(t), which was introduced by Begg and co-workers to measure the DNA synthesis time, T_s. In general, the relative movement is defined as the mean DNA fluorescence of a population of cells less the DNA fluorescence of the cells in G₁ and divided by the difference in DNA fluorescence of the cells in G₂+ M and G₁. In this paper we examine the relative movements of all the labelled cells and all of the unlabelled cells, denoted RM^L(t) and RM^U(t) respectively. It is found that RM^L(t) and RM^U(t) exhibit clear cyclic behaviour and distinguishable characteristics which depend directly on the transit times (T) of the cell cycle phases, i.e. T_G1, T_s and TG_2+m. Furthermore, the peak heights of the RM^U(t) curve are shown to depend strongly on the growth fraction of the population under consideration. A theoretical treatment of the curves so obtained is presented, and is shown to yield values in close agreement with those from other methods for measuring these transit times and a lower limit to values for the growth fraction of Chinese hamster ovary cells grown in vitro.