ABSTRACT. We studied a genetically determined diabetes in pregnancy, the heterozygous diabetes (db/+) mouse. We found that fetal mice from these pregnancies are macrosomic with increased body, lung, and placenta wt, have altered organ protein, DNA and phospholipid content, and exhibit abnormal carbohydrate metabolism with increased liver and glycogen content. We further studied the effect of increased substrate availability and utilization on lung growth and maturation in (db/+) fetal mice, by measuring lung phospholipid synthesis as represented by the incorporation of the radiolabeled precursors, [3H] The increased synthesis of lung disaturated phosphatidylcholine in diabetic fetal mice may reflect the enhancement of body and lung growth in these macrosomic fetuses. Lung maturation, as represented by phosphatidylglycerol synthesis, the phosphatidylglycerol/phosphatidylinositol ratio, and morphologic indices, was abnormal in diabetic fetuses. The diabetic mouse is a useful model for studying the mechanisms resulting in enhanced growth and concomitant alterations in lung maturation in the infant of a diabetic mother. (Pediatr Res 25:173-179, 1989) Abbreviations RDS, respiratory distress syndrome PC, phosphatidylcholine SPC, disaturated phosphatidylcholine S, sphingomyelin PI, phosphatidylinositol PE, phosphatidylethanolamine PS, phosphatidylserine PG, phosphatidylglycerol Human fetal development during maternal diabetes is abnormal, frequently resulting in obese, macrosomic newborns with delayed maturation of various organ systems. Infants of diabetic mothers whose hyperglycemia is inadequately controlled late in gestation appear to have an increased risk of lung immaturity, as manifested by RDS at birth (I). Animal models in which maternal glucose intolerance and consequent fetal hyperglycemia are artificially induced have been developed to study this phenomenon (2). However, important questions concerning maternal-fetal interactions in diabetes and the consequent effects on fetal organ growth and development might be more appropriately addressed by using a model in which the diabetes is genetically determined, therefore occuning spontaneously in the mother (2).The diabetic mouse (db/db) is a well-described model of genetic diabetes transferred as an autosomal recessive trait. Homozygous (db/db) animals exhibit visible obesity in infancy with marked hyperglycemia and insulin resistance, followed later by hypoinsulinemia and profound diabetes at 3-4 mo of age (3). As the adult (db/db) mouse is infertile, heterozygous animals must be bred to produce offspring. The heterozygous female (db/ +) exhibits normal glucose tolerance except during pregnancy, when abnormal glucose tolerance, postprandial hyperglycemia and elevated Hb A 1C levels are present (4,5).We have studied the fetus of the pregnant heterozygous (db/ +) female to learn more about growth and the development during pregnancy complicated by abnormal glucose metabolism. In this report, we describe our results in characterizing abnormal fetal growth duri...
