Morphological analysis of neural tube defects: Chlorambucil-induced exencephaly in mice

Exencephaly has been induced in mouse embryos by chlorambucil (CA), a cytotoxic agent. To understand the course of development of this malformation, open neural tube defects in CA-treated mice were examined using light and scanning electron microscopes (SEM). CA was given to the pregnant mice on day 7.4 of gestation. Embryos were removed and fixed on gestational days 9.3–9.4, 9.7–9.8 and 10.4, and compared to control embryos from untreated mice. By gestational day 9.4, all control embryos had closed neural tubes, except for the posterior neuropores, and well developed brain vesicles. By contrast, in the experimental embryos the frequencies of open neural tube were 26/33 (78.8%), 32/ 40 (80.0%) and 23/66 (34.8%) on each day examined, respectively. Open neural tube defects were classified into six patterns according to the location and magnitude of the open area. The patterns of open neural tube on day 9.7–9.8 were diverse; however, in almost all cases on day 10.4 the open neural tube appeared in a region from the caudal forebrain to the rostral hindbrain. It was evident that an unusual pattern of closure of the neural tube was involved in forming the cranial neural tube. The present study shows that failure of closure of the cranial neural tube in the CA-treated mouse embryos can be defined as a primary neural tube defect (NTD), which can be, in part, repaired by unusual closure of the neural tube. At high magnifications of SEM, the neuroectodermal surfaces of the 9.0-day affected embryos often had a number of slender processes projecting from the neuroepithelial cells. “Ruffles” and “blebs” at the lateral edges of the neural folds were observed in both control and affected embryos.