Cell sensitivity to transplacental mutagenesis by N-ethyl-N-nitrosourea is greatest during early gestation in the Syrian hamster

Veno-occlusive disease in a fetus caused by pyrrolizidine alkaloids of food origin

We report the occurrence of veno-occlusive disease in a preterm neonate who was symptomatic with hepatomegaly and ascites and was delivered by caesarean section for threatening fetal asphyxia and died shortly afterwards. Post mortem examination revealed veno-occlusive disease typical for pyrrolizidine alkaloid poisoning. The content of pyrrolizidine alkaloids in the liver could be confirmed. Analysis of a herbal mixture which was used for cooking in the family revealed high amounts of the respective alkaloids clarifying the source of the poison and the causal relationship.

Cell sensitivity to transplacental carcinogenesis by N-ethyl-N-nitrosourea is greatest in early post-implantation development

In a clear demonstration of the changing sensitivity of the developing mammal to transplacental carcinogenesis, Ivankovic and Druckrey [S. Ivankovic, H. Druckrey, Transplacentare Erzeugung maligner Tumoren des Nervensystem: I. Athyl-nitroso-harnstoff (ANH) an BD IX-Ratten, Z. Krebsforsch. 71 (1968) 320-360] exposed pregnant BD IX rats to a pulse of N-ethyl-N-nitrosourea (ENU), a reactive carcinogen with a half-life of 20 min. No tumors were seen with ENU exposure before gestation day 12, but the multiplicity of neurogenic tumors increased steadily thereafter and was greatest with treatment on day 20, followed by a decline in sensitivity for the last three days of gestation. Similarly, a transplacental study of ENU in the Syrian hamster [B.A. Diwan, S. Rehm, J.M. Rice, Age- and dose-dependent transplacental carcinogenesis by N-nitrosoethylurea in Syrian golden hamsters, J. Cancer Res. Clin. Oncol. 122 (1996) 643-652] found that the numbers of tumors induced were greatest after exposure of late fetal stages. While these observations suggested that embryonic cells are refractory to carcinogenesis, an alternative explanation could be that a significant tumor yield was not observed because too few target cells were present in the embryo. I have resolved this issue by combining these published data with others on the numbers of neuroectodermal cells in the developing BD IX rat brain [R. Müller, M.F. Rajewsky, Elimination of O6-ethylguanine from the DNA of brain, liver, and other rat tissues exposed to ethylnitrosourea at different stages of prenatal development, Cancer Res. 43 (1983) 2897-2904] and total cell counts of successive developmental stages of the Syrian hamster fetus [P.J. Donovan, G.T. Smith, Cell sensitivity to transplacental mutagenesis by N-ethyl-N-nitrosourea is greatest during early gestation in the Syrian hamster, Mutation Res., 1999, this issue], allowing the risk per cell at different stages of gestation to be calculated. Sensitivity to carcinogenesis was found to be greatest early in gestation and to decrease as gestation proceeds. For the rat model, tumor frequency per cell changed from 1.3x10(-6) at day 12 exposure to 2.6x10(-8) at day 23 exposure, a 50-fold decrease. For the hamster model, the tumor-initiation rate decreased 1250-fold from 1.2x10(-5) at day 7 exposure to 9.6x10(-9) at day 13 exposure. Thus, two independent experiments with different rodent species demonstrate that sensitivity of individual cells to damage leading to transplacental carcinogenesis is greatest in the early fetus and lessens markedly as gestation proceeds, in parallel with changing sensitivity to mutation (Donovan et al., Mutat. Res., this issue).