Developmental defects of coronary vasculature in rat embryos administered bis-diamine.

BACKGROUND: Conotruncal anomalies are often associated with abnormal coronary arteries. Although bis-diamine is known to induce conotruncal defects, its pathological effects on coronary vascular development have not been demonstrated. This study sought to assess the teratogenic effects of bis-diamine on coronary vascular development and the pathogenesis of this anomalous association. METHODS AND RESULTS: A single 200 mg dose of bis-diamine was administered to pregnant Wistar rats at 10.5 days of gestation. Fifty-two embryos from 10 mother rats underwent morphological analysis of the coronary arteries. Three embryos each were removed from four mothers on embryonic days (ED) 14.5, 15.5, 16.5, and 17.5 and used for immunohistochemical studies using the anti-vascular cell adhesion molecule (VCAM)-1 antibody. Conotruncal anomalies were detected in 48 of 52 embryos, and an aplastic or hypoplastic left coronary artery was found in all of them. In control embryos at ED 16.5, VCAM-1-positive epicardial cells were transformed into mesenchymal cells in vascular plexus, which appeared to differentiate into the endothelial cells of coronary vasculature. In the heart at ED 17.5, coronary vasculature was well developed and connected with coronary ostia near the aorta. However, poor epicardial-mesenchymal transformation and subsequent differentiation was revealed in bis-diamine-treated embryos at EDs 16.5 and 17.5, causing abnormal development of the coronary vasculature and incomplete connections with coronary ostia of the aorta. CONCLUSIONS: Anomalous coronary arteries in the bis-diamine-treated embryos are induced by the disruption of epicardial-mesenchymal transformation and subsequent poor development of coronary vasculature. Incomplete hatching of the coronary ostium is associated with abnormal truncal division.

Apoptosis in cerebrum of macular mutant mouse.

Neuronal cell death in the brain of macular mutant mouse, a model of copper metabolism abnormality, has features of both apoptosis and necrosis. Apoptotic cells were morphologically identified by the terminal deoxynucleotidyl transferase nick end-labeling (TUNEL) method and electron microscopy. Numerous TUNEL-positive cells were identified in the cerebral cortex, hippocampus and thalamus of the hemizygotes after postnatal day 11. Ultramicroscopic studies confirmed that a number of cells had apoptotic features characterized by condensation and segregation of the nuclei. Furthermore, genomic DNA gel electrophoresis revealed a laddering pattern in the hemizygous brain. Starvation, which produced a low body weight in normal mice similar to that seen in the hemizygotes, did not result in an increase of TUNEL-positive cells. We also found that there was no increase of apoptotic cells in the brains of heterozygotes and copper-supplemented hemizygotes. Immunocytochemical analysis revealed that the distribution of copper/zinc superoxide dismutase-containing cells differed from that of TUNEL-positive cells. These findings suggest that copper deficiency is a key factor triggering apoptosis in the brain of macular mutant mouse through a mechanism different from suppression of antioxidant action of the dismutase. The improved survival period of the copper-supplemented hemizygotes may be attributed, in part, to inhibition of excessive neuronal apoptosis identified in the late stage of the disease.