Specific-locus mutation rates in the mouse following inhalation of ethylene oxide, and application of the results to estimation of human genetic risk.

Male (101 X C3H)F1 mice were exposed in an inhalation chamber to ethylene oxide (EtO) in air at a concentration of (generally) 255 ppm. After accumulating total exposures of 101 000 or 150 000 ppm.h in 16-23 weeks, the males were mated to T-stock females for a standard specific-locus mutation-rate study in which 71387 offspring were observed. The spermatogonial stem-cell mutation rate at each exposure level, as well as the combined result, does not differ significantly from the historical control frequency. At the lower and higher exposure levels, the results rule out (at the 5% significance level) an induced frequency that is, respectively, 0.97 and 6.33 times the spontaneous rate; the combined results rule out a multiple of 1.64. The relationship between mouse spermatogonial stem-cell mutation rates and EtO-induced testis ethylations was compared with the relationship between Drosophila post-stem-cell mutation rates and sperm ethylations (Lee, 1980). The comparison does not rule out equal mutability per ethylation; but it cannot prove parallelism. An assessment of the mouse-Drosophila relationship will require a more efficient alkylator than EtO and the use of comparable germ-cell stages. More meaningful conclusions may be drawn by utilizing the data for direct estimation of human risk by expressing the induced mutation frequency that is ruled out (at the 5% significance level) as a multiple of control rate and extrapolating to human exposure levels. The probable absence of major stem-cell killing (and thus, possibly, cell selection) by EtO indicates that such extrapolation probably does not produce an underestimate. For a human exposure concentration of 0.1 ppm on working days during the reproductive lifespan, the mouse experimental results rule out (at the 5% significance level) an induced spermatogonial stem-cell gene mutation rate greater than 8% of the spontaneous rate; for 1.0 ppm, they rule out an induced rate roughly equal to the spontaneous rate. The induced rate for any one poststem-cell stage would have to be about 3 orders of magnitude higher than that for stem cells to constitute an equivalent risk.