Abstract
The effect of maternal nicotine exposure on fetal and neonatal lung metabolism was investigated. Nicotine (0.25 and l.0 mg/kg body weight/day) administered subcutaneously to the mother animal from day 7 of gestation until weaning led to retarded glycogenolysis of fetal lung. This was due to an inhibition of lung glycogen phosphorlyase. Exposure until 2 weeks after birth had no effect on the in vitro oxygen consumption of lung tissue, but the total glucose turnover of rat neonates exposed to 0.25 and 1.0 mg nicotine/kg body weight per day was increased to 78.96±3.92 and 121.09±7.36 μmol/g per h, respectively, as compared to controls (64.95±4.56 μmol/g per h). In contrast to the marked increase in total glucose turnover, the in vitro lactate production was significantly lowered, suggesting an inhibition of the glycolytic pathway. The lung lecithin content of control neonates (day 1 post-partum) was 1.94±0.30 mg/g wet tissue mass. Nicotine administration to the mother resulted in a 92% higher lung lecithin content (3.72±0.06 mg/g). The results suggest that although nicotine will have no effect on the incidence of respiratory distress syndrome due to a lack of lecithin, it may have a detrimental effect on the functional development of the lung as a result of its inhibitory effect on glucose oxidation via the glycolytic pathway.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Agranoff BW, Hajra AK (1971) The acyl dihydroxyacetone phosphate pathway for glycerolipid biosynthesis in mouse liver and Ehrlich ascites tumor cells. Proc Nat Acad Sci 68: 411–415
Bassett DJP, Fisher AB (1976) Metabolic response to carbon monoxide by isolated rat lung. Am J Physiol 230: 658–663
Benowitz NL, Jacob P (1984) Daily intake of nicotine during cigarette smoking. Clin Pharmacol Ther 35: 499–504
Boughton K, Gandy G, Gairdner D (1970) Hyaline membrane disease II: Lung lecithin. Arch Dis Child 45: 311–320
Bourbon JR, Jost A (1982) Control of glycogen metabolism in the developing fetal lung. Pediatr Res 16: 50–56
Bourbon JR, Rieutort M, Engle MJ, Farrell PM (1982) Utilization of glycogen for phospholipid synthesis in fetal rat lung. Biochim Biophys Acta 712: 382–389
Entman ML, Kaniike K, Goldstein MA, Nelson TE, Barnett EP, Futch TW, Schwartz A (1976) Association of glycogenolysis with cardiac sarcoplasmic reticulum. J Biol Chem 251: 3140–3146
Gennser G, Marsal K, Brantmark (1974) Maternal smoking and fetal breathing movements. Am J Obstet Gynecol 123: 861–865
Gleason MN, Gosselin RE, Hodge HC (1963) Clinical toxicology of commercial products. 2nd ed Baltimore. The Williams and Williams Company, p 115
Greenberg RA, Haley NJ, Etzel RA, Loda FA (1984) Measuring the exposure of infants to tobacco smoke: nicotine and cotinine in urine and saliva. N Engl J Med 310: 1075–1107
Hamosh M, Shechter Y, Hamosh P (1978) Metabolic activity of developing rabbit lung. Pediatr Res 12: 95–100
Higgins TJC, Allsopp D, Bailey PJ, O'Sonza EDA (1981) The relationship between glycolysis, fatty acid metabolism and membrane integrity in neonatal myocytes. J Mol Cell Cardiol 13: 599–615
Kerr JS, Baker NJ, Basset DJP, Fisher AB (1979) Effect of perfusate glucose concentration on rat lung glycolysis. Am J Physiol 236: E229-E233
Lo S, Russel JC, Taylor AW (1970) Determination of glycogen in small tissue samples. J Appl Physiol 28: 234–236
Luck W, Nau H (1984) Nicotine and cotinine concentrations in serum and milk of nursing smokers. Br J Clin Pharmacol 18: 1–15
Maritz GS (1983) Die invloed van nikotien op die intermediêre koolhidraatmetabolisme van longweefsel (The influence of nicotine on the intermediary carbohydrate metabolism of lung tissue) (PhD thesis): University of Stellenbosch
Massaro GD, Gail DB, Massaro D (1975) Lung oxygen consumption and mitochondria of alveolar epithelial cells. J Appl Physiol 38: 588–592
O'Neill JJ, Tierney DF (1974) Rat lung metabolism: Glucose utilization by isolated perfused lung and tissue slices. Am J Physiol 226: 867–873
Paul RJ (1983) Functional compartmentalization of oxidative and glycolytic metabolism in vascular smooth muscle. Am J Physiol 244: C399-C409
Perelman RH, Engle MJ, Kemnitz JW, Kotas RV, Farrell PM (1982) Biochemical and physiological development of fetal rhesus lung. J Appl Physiol 53: 230–235
Rabinowitz JL, Cardwell T, Bassett DJP (1981) Reutilization of fatty acid carbons for lung lipid synthesis. Am J Physiol 240: E435-E440
Rhoades RA, Shaw ME, Eskew ML, Wali S (1978) Lactate metabolism in perfused rat lung. Am J Physiol 235: E619-E623
Rinaudo MT, Ponzetto C, Tavormina V, Gombola P (1976) Lung denervation in rats. A histochemical and biochemical study. Rassegme Geriatrica 12: 41–48
Salisbury-Murphy S, Rubinstein D, Beck JC (1966) Lipid metabolism in lung slices. Am J Physiol 211: 988–992
Turner DM, Leonard SL (1966) Glycogen phosphorylase in rat levator ani: activity related to testosterone, epinephrine and actinomycin D. Endocrinology 84: 589–594
Van Vunakis H, Lagone JJ, Mikinsky A (1974) Nicotine and cotinine in the amniotic fluid of smokers in the second trimester of pregnancy. Am J Obstet Gynecol 120: 64–66
Warshaw JB, Terry ML, Ranis MB (1980) Metabolic adaptation in developing lung. Pediatr Res 145: 296–299
Williams CM, Kanagasabai T (1984) Maternal adipose tissue response to nicotine administration in the pregnant rat: effects on fetal body fat and cellularity. Br J Nutr 51: 7–13
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Maritz, G. Pre- and postnatal carbohydrate metabolism of rat lung tissue. Arch Toxicol 59, 89–93 (1986). https://doi.org/10.1007/BF00286729
Received:
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00286729