Full Access
Insulin deficiency: Effects on fetal growth and development
A. L. FOWDEN,
A. L. FOWDEN
Physiological Laboratory, University of Cambridge, Cambridge, England
Search for more papers by this authorA. L. FOWDEN,
A. L. FOWDEN
Physiological Laboratory, University of Cambridge, Cambridge, England
Search for more papers by this authorA. L. Fowden, Physiological Laboratory, Downing Street, Cambridge CB2 3EG, England.
Abstract
Insulin deficiency in either the mother or foetus has significant effects on fetal growth and development. In the human, maternal insulin deficiency, or diabetes mellitus, leads to macrosomia and increased adiposity of the foetus, while specific fetal hypo-insulinaemia is associated with intra-uterine growth retardation. When maternal diabetes is induced in experimental animals, no consistent increases in fetal bodyweight are observed although the body fat content of the foetus is increased in the majority of species studied. The magnitude of the fetal weight gain during maternal diabetes appears to be determined by the body fat content of the foetus, the severity and duration of the diabetes and by the temporal pattern of maternal hyperglycaemia observed during pregnancy. The latter factors, in particular, influence the level of insulin in the foetus which, in turn, regulates the rate of intra-uterine growth. By contrast, fetal insulin deficiency has a more uniform effect on fetal growth and leads to impaired growth in both experimental and naturally occurring hypo-insulinaemic conditions. Fetal insulin deficiency reduces fetal growth by decreasing nutrient uptake and utilization of the fetal tissues and by altering the circulating concentrations of the insulin-like growth factors. Consequently, deficiencies in either fetal or maternal insulin secretion during pregnancy can alter fetal growth and have important consequences for perinatal survival and postnatal morbidity.
Reference
- 1 Pedersen J. Fetal macrosomia. In A. W. Sutherland, J. M. Stowers ed. Carbohydrate Metabolism in Pregnancy and the Newborn. Churchill Livingstone, London . 1975; 247–73.
- 2 Hill D. E. Effect of insulin on fetal growth. Semin. Perinatol. 1972; 2: 319–28.
- 3 Milner R. D. G. Endocrine control of fetal growth? In B. S. Linblad ed. Perinatal Nutrition. Academic Press, London . 1988; 45–62.
- 4 Osler M., Pedersen J. The body composition of newborn infants of diabetic mothers. Pediatrics 1960; 29: 985–92.
- 5 Naeye R. L. Infants of diabetic mothers: A quantitative morphological study. Pediatrics 1965; 35: 980–8.
- 6 Barash V., Gutman A., Shafrir E. Fetal diabetes in rats and its effect on placental glycogen. Diabetologia 1985; 28: 244–49.
- 7 Gabbe S. G., Quilligan E. J. General obstetric management of diabetic pregnancy. Clin. Obstet. Gynecol. 1981; 24: 91–105.
- 8 Tsang R. C., Ballard J., Braun C. The infant of the diabetic mother. Clin. Obstet. Gynecol. 1981; 24: 125–47.
- 9 Seeds A. E., Knowles H. C. Metabolic control of diabetic pregnancy. Clin. Obstet. Gynecol. 1981; 24: 51–71.
- 10 Greene M. F. Congenital malformations In J. W. Hare ed. Diabetes Complicating Pregnancy. Alan R. Liss, New York . 1989; 147–61.
- 11 Lips J. P., Jongma H. W., Eskes T. K. A. B. Alloxan-induced diabetes mellitus in pregnant sheep and chronic fetal catherization. Lab. Anim. 1988; 22: 16–22.
- 12 Ezekwe M. O., Martin R. J. The effects of maternal alloxan diabetes on body composition, liver enzymes and metabolism and serum metabolite and hormones of fetal pigs. Horm. Metab. Res. 1980; 12: 136–9.
- 13 Cheek D. B., Hill D. E. Changes in somatic growth after ablation of maternal or fetal pancreatic beta cells. In D. B. Cheek ed. Fetal and Postnatal Growth. John Wiley & Sons, New York . 1975; 311–21.
- 14 Mintz D. H., Chez R. A., Hutchinson D. L. Subhuman primate pregnancy complicated by streptozotocin induced diabetes mellitus. J. Clin. Invest. 1972; 51: 837–47.
- 15 Fain J. N., Scow R. O. Fatty acid synthesis in vivo in maternal and fetal tissues in the rat. Am. J. Physiol. 1966; 210: 19–25.
- 16 Verhaege J., Peeters T. L., Vandeputte M., Rombauts W., Bouilton R., Van Assche F. A. Maternal and fetal endocrine pancreas in spontaneously diabetic BB rats. Biol. Neonate 1989; 55: 298–308.
- 17 Rerup C. C. Drugs producing diabetes through damage of insulin secreting cells. Pharm. Rev. 1970; 22: 485–518.
- 18 Jackson H. D., Van Dewark S. D., Van Vleet J. F. Blood chemical and pancreatic histological alterations in alloxan-diabetic ewes and their fetuses. Am. J. Vet. Res. 1970; 31: 1577–87.
- 19 Kervran A., Guillaume M., Jost A. The endocrine pancreas of the fetus from diabetic pregnant rats. Diabetologia 1978; 15: 387–93.
- 20 Lips J. P., Jongma H. W., Crevels J., Eskes T. K. A. B. Chronic hyperglycaemia and insulin concentrations in fetal lambs. Am. J. Obstet. Gynecol. 1988; 159: 247–51.
- 21
Hoet J. J.
Normal and abnormal fetal weight gain. In Fetal Autonomy. Ciba Foundation Symposium, Wolstenhome,
London
. 1969; 186–93.
10.1002/9780470719688.ch12 Google Scholar
- 22 Sybulski S., Maughan J. Use of streptozotocin as a diabetic agent in pregnant rats. Endocrinology 1971; 89: 1537–40.
- 23 Crandell S. S., Fisher D. J., Morriss F. H. Effects of ovine maternal hyperglycaemia on fetal regional blood flows and metabolism. Am. J. Physiol. 1985; 249: E454–60.
- 24 Reid R. L., Hinks N. T., Mills S. C. Alloxan diabetes in pregnant ewes. J. Endocrinol. 1963; 27: 1–19.
- 25 Picon L. Effect of insulin on growth and biochemical composition of the rat fetus. Endocrinology 1967; 87: 1419–21.
- 26 Susa J. B., McCormick K. L., Widness J. A. et al. Chronic hyperinsulinaemia in the fetal rhesus monkey: Effects on fetal growth and composition. Diabetes 1979; 14: 573–8.
- 27 Stevens D., Alexander G., Bell A. W. Effect of prolonged glucose infusion into fetal sheep on body growth, fat deposition and gestation length. J. Dev. Physiol. 1990; 13: 277–81.
- 28 Ktorza A., Nurijhan N., Girard J., Picon L. Hyperglycaemia induced by glucose infusion in the unrestrained pregnant rat: Effect on bodyweight and lipid synthesis in postmature fetuses. Diabetologia 1983; 24: 128–30.
- 29 Milley J. R. The effect of chronic hyperinsulinaemia on ovine fetal growth. Growth 1986; 50: 390–401.
- 30 Fowden A. L. The role of insulin in prenatal growth. J. Dev. Physiol. 1989; 12: 178–82.
- 31 Leturque A., Revelli J. P., Haugel S., Kand J., Girard J. Hyperglycaemia and hyperinsulinaemia increase glucose utilization in fetal rat tissues. Am. J. Physiol. 1987; 253: E616–20.
- 32 Hay W. W., Meznarich H. K. The effect of hyperinsulinaemia on glucose utilization and oxidation and on oxygen consumption in the fetal lamb. Q. J. Exp. Physiol. 1986; 71: 689–98.
- 33 Garssen G. J., Spencer G. S. G., Colenbrander B., Macdonald A. A., Hill D. J. Lack of effect of chronic hyperinsulinaemia on growth and body composition in the fetal pig. Biol. Neonate 1983; 44: 234–42.
- 34 Hill D. J., Milner R. D. G. Increased somatomedin and cartilage metabolic activity in rabbit fetuses injected with insulin in utero. Diabetologia 1980; 19: 143–7.
- 35 Heinze E., Nguyen Thi C., Vetter U., Fussganger R. D. Interrelationship of insulin and somatomedin activity in fetal rats. Biol. Neonate 1982; 41: 240–5.
- 36 Susa J. B., Widness J. A., Hintz R., Liu R., Sehgal P., Schwartz R. Somatomedin and insulin in diabetic pregnancy: Effects on fetal macrosomia in the human and rhesus monkey. J. Clin. Endocrinol. Metab. 1984; 58: 1099–105.
- 37 Brinsmead M. W., Thorburn G. D. Effect of streptozotocin in foetal lambs in mid-pregnancy. Aust. J. Biol. Sci. 1982; 35: 417–525.
- 38 Fowden A. L., Comline R. S. The effects of pancreatectomy on the sheep fetus in utero. Q. J. Exp. Physiol. 1984; 69: 319–30.
- 39
Fletcher J. M.,
Bassett J. M.
Effects of streptozotocin injection into fetal rabbits on their subsequent growth in utero.
Biol. Neonate
1980; 49: 51–9.
10.1159/000242509 Google Scholar
- 40 Harding S., Yeung A., Possmayer F. The effect of hypoinsulinaemia on the fetus. Clin. Res. 1975; 23: 611A.
- 41 Felix J. M., Jacquot R. L. Effect of subtotal gastrointestinal pancreatectomy of the rat fetus. J. Endocrinol. 1976; 69: 77–83.
- 42 Fowden A. L., Mao X. L., Comline R. S. The effects of pancreatectomy on the growth and metabolite concentrations of the sheep fetus. J. Endocrinol. 1986; 110: 225–31.
- 43 Fowden A. L., Hughes P., Comline R. S. The effects of insulin on the growth rate of the sheep fetus during late gestation. Q. J. Exp. Physiol. 1989; 74: 703–14.
- 44 Hay W. W., Meznarich H. K., Fowden A. L. The effects of streptozotocin on the rates of glucose utilization, oxidation and production in the sheep fetus. Metabolism 1989; 38: 30–7.
- 45 Fowden A. L., Hay W. W. The effects of pancreatectomy on the rates of glucose utilization, oxidation and production in the sheep fetus. Q. J. Exp. Physiol. 1988; 73: 973–84.
- 46 Fowden A. L. The endocrine regulation of fetal metabolism and growth. Res. Perinat. Med. 1989; Vill: 229–43.
- 47 Blethen S. L., White N. H., Santiago J. V., Daughaday W. H. Plasma somatomedin, endogenous insulin secretion and growth in transient diabetes mellitus. J. Clin. Endocrinol. Metab. 1981; 52: 144–7.
- 48 Gluckman P. D. The role of pituitary hormones, growth factors and insulin in the regulation of fetal growth. Ox. Rev. Reprod. Biol. 1986; 8: 1–60.
- 49 Gluckman P. D., Butler J., Comline R. S., Fowden A. L. The effects of pancreatectomy on the plasma concentrations of insulin-like growth factors 1 and 2 in the sheep fetus. J. Dev. Physiol. 1987; 9: 79–88.
- 50 Hill D. J. Growth factors and their cellular actions. J. Reprod. Fertil. 1989; 85: 723–34.
Citing Literature
