Abstract
Two groups of growing posthatching Cornish x Rock cross chickens were fed with either a carbohydrate-containing (52.5%) or a carbohydrate-free diet. At 36 days after hatching some of the chicks in each group were shifted to the opposite diet. Chickens fed on a carbohydrate-containing diet grew faster and achieved higher asymptotic masses than chickens fed on a carbohydrate-free diet. Chickens fed on a carbohydrate-free diet had longer intestines and larger intestinal areas than chickens of the same mass fed on a carbohydrate-containing diet. In both groups sucrase and maltase activity (standardized by either intestinal area or mass) increased from day 1 to approximately day 17. After day 17, chickens fed on a carbohydrate-containing diet exhibited 1.8 and 1.9 times higher sucrase and maltase activities per unit intestinal area, respectively, than chickens fed on a carbohydrate-free diet. Analysis of covariance was used to estimate the contribution of sucrase and the sucrase-independent maltases to maltase activity, and to estimate the effect of diet on the sucrase-independent maltases. Sucrase contributed 80% and 75% of the maltase activity in carbohydrate and carbohydrate-free fed chickens, respectively. Chickens shifted from a carbohydrate-free to a carbohydrate diet converged in gross intestinal morphology and intestinal sucrase and maltase levels with carbohydrate-fed chickens within 8 days. Chickens shifted from carbohydrate to carbohydrate-free diets, in contrast, did not show appreciable changes in intestinal length and after 8 days had not reduced levels of sucrase and maltase to those of chickens fed on the carbohydrate-free diet. A comparison of integrated maltase intestinal activity with published data on glucose uptake showed that the ratio of maltose hydrolysis to glucose uptake seemed to be about 7 and to remain relatively invariant during ontogeny. Because so little is known about the interaction between hydrolysis and uptake in vivo, it is difficult to determine if this relatively high ratio represents excess hydrolytic capacity or if it is needed to provide high lumenal glucose concentrations that maximize uptake.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
Abbreviations
- m:
-
body mass
- K m :
-
Michaelis constant
- K *m :
-
apparent Michaelis constant
- GI:
-
gastro-intestinal
References
Alpers DH, Tedesco FJ (1975) The possible role of pancreatic proteases in the turnover of intestinal brush border proteins. Biochim Biophys Acta 401:28–40
Auricchio S, Ciccimarra F, Starace E, Vegnete A, Giliberti P, Provenzale L (1971) Glucoamylase activity of human intestinal mucosa. Rend R Gastroenterol 3:1–8
Buddington RK, Diamond JM (1989a) Ontogenetic development of intestinal nutrient transporters. Annu Rev Physiol 51:601–619
Buddington RK, Diamond JM (1989b) Ontogenetic development of monosaccharide and amino acid transporters in rabbit intestine. Am J Physiol 259:G544-G555
Burghardt RK (1990) Chemically mediated predation in vertebrates: diversity, ontogeny, and information. In: McDonald et al (eds) Chemical signals in vertebrates, vol 5. Oxford University Press, Oxford, UK, pp 475–499
Dahlqvist A (1959) Studies on the heat inactivation of intestinal invertase, maltase, and trehalase. Acta Chim Scand 13:945–953
Dahlqvist A (1961a) Specificity of the human intestinal disaccharidases and implications for hereditary disaccharidase intolerance. J Clin Invest 41:463–470
Dahlqvist A (1961b) The location of carbohydrases in the digestive tract of the pig. Biochem J 78:282–287
Dahlqvist A (1963) Rat intestinal dextranase, localization and relation to other carbohydrases of the digestive tract. Biochem J 86:72–76
Dahlqvist A (1984) Assay of intestinal disaccharidases. Scand J Clin Lab Invest 44:69–172
Deren JJ, Broitman SA, Zamcheck N (1967) Effect of diet upon intestinal disaccharidases and disaccharidase absorption. J Clin Invest 46:186–195
Diamond JM (1991) Evolutionary design of intestinal nutrient absorption: enough but not too much. NIPS 6:92–96
Diamond JM, Hammond K (1992) The matches, achieved by natural selection, between biological capacities and their natural loads. Experientia 48:551–556
Dykstra CR, Karasov WH (1992) Changes in gut structure and function of house wrens (Troglodytes aedon) in response to increased energy demands. Physiol Zool 65:422–442
Galand G (1989) Brush border membrane sucrase-isomaltase, maltase, glucoamylase and trehalase in mammals: comparative development, effects of glucocorticoids, molecular mechanisms, and phylogenetic implication. Comp Biochem Physiol 94B:1–11
Goda T, Raul F, Gossé F, Koldovky O (1988) Effects of a high-protein, low carbohydrate diet on degradation of sucrase-isomaltase in rat jejunoileum. Am J Physiol 254:G907-G912
Gray GM, Ingelfinger FJ (1965) Intestinal absorption of sucrose in man: the site of hydrolysis and absorption. J Clin Invest 44:390–399
Gray GM, Ingelfinger FJ (1966) Intestinal absorption of sucrose in man: interrelation of hydrolysis and monosaccharide product absorption. J Clin Invest 45:388–398
Graybill FA (1976) Theory and application of the linear model. Duxbury Press, Boston, Mass., USA
Hammond KA, Diamond J (1992) An experimental test for a ceiling on sustained metabolic rate in lactating mice. Physiol Zool 65:952–977
Henning SJ (1981) Postnatal development: coordination of feeding, digestion, and metabolism. Am J Physiol 241:G199–214
Henning SJ, (1985) Ontogeny of enzymes in the small intestine. Am J Physiol 47:231–245
Hu C, Spiess M, Semenza G (1987) The mode of anchoring and precursor forms of sucrase-isomaltase and maltase-glucoamylase in chicken intestinal brush-border membrane: phylogenetic implications. Biochim Biophys Acta 896:275–286
James WPT, Alpers DG, Gerber JE, Isselbacher KJ (1971) The turnover of disaccharidases and brush-border proteins in rat intestine. Biochim Biophys Acta 230:194–203
Jarvis LG, Morgan G, Smith MW, Wooding FBP (1977) Cell replacement and changing transport function in the neonatal pig colon. J Physiol (Lond) 273:717–729
Karasov WH (1988) Nutrient transport across vertebrate intestine. In: Gilles R (ed) Advances in comparative and environmental physiology, vol 2. Springer, Berlin, pp 131–173
Karasov WH, Diamond JM (1989) Interplay between physiology and ecology in digestion. BioScience 38:602–611
Karasov WH, Levey DJ (1990) Digestive system trade-offs and adaptations of frugivorous passerine birds. Physiol Zool 63:1248–1270
Karasov WH, Pond RS III, Solberg D, Diamond JM (1983) Regulation of proline and glucose transport in mouse intestine by dietary substrate levels. Proc Natl Acad Sci USA 80:7674–7677
Karasov WH, Solberg DH, Diamond JM (1985) What transport adaptations enable mammals to absorb sugars faster than reptiles? Am J Physiol 249:G271–283
Koldovsky O (1981) Developmental, dietary and hormonal control of intestinal disaccharidases in mammals (including man). In: Randle PJ et al (eds) Carbohydrate metabolism and its disorders. Academic Press, New York, pp 481–521
Kwong LK, Tsuboi KK, Koldovsky O, Yamada Y, Sunshine P (1982) Dietary carbohydrate as a determinant of disaccharidase synthesis in rat intestine. Pediatr Res 16:169A
Lebenthal E, Sunshine P, Kretchmer N (1972) Effect of prolonged nursing on the activity of intestinal lactase in rats. Gastroenterology 64: 1136–1141
Lilja C (1982) Postnatal growth and organ development in the quail (Coturnix coturnix japonica). Growth 46:88–99
Lilja C (1983) A comparative study of postnatal growth and organ development in some species of birds. Growth 47:317–399
Martínez del Rio C (1990) Dietary, phylogenetic, and ecological correlates of intestinal sucrase and maltase activity in birds. Physiol Zool 63:987–1011
Martínez del Rio C, Stevens BR (1989) Physiological constraints on feeding behavior: intestinal membrane disaccharidases of the starling. Science 243:794–796
McCarthy M, Nicholson JA, Kim YS (1980) Intestinal enzyme adaptation to normal diets of different composition. Am J Physiol 239:G445-G451
Messer M, Kerry KR (1966) Intestinal digestion of maltotriose in man. Biochim Biophys Acta 132:432–443
Morrill JS, Kwong LK, Sunshine P, Briggs GM, Castillo R, Tsuboi KK (1988) Dietary CHO and stimulation of carbohydrases along villus column of fasted jejunum. Am J Physiol 256:G158-G165
National Research Council (1984) Nutrient requirements of poultry, 8th revised edn. Washington D.C., National Academy Press
Obst BS, Diamond JM (1992) Ontogenesis of intestinal nutrient transport in the domestic chicken (Gallus gallus) and its relation to growth. Auk 109:451–464
Raheja KL, Tepperman J, Tepperman L (1977) The effect of age on intestinal glucose transport in the chick (Gallus domesticus). Comp Biochem Physiol 58A:245–248
Reiss MJ (1989) The allometry of growth and reproduction. Cambridge University Press, Cambridge, UK
Riby JE, Kretchmer N (1984) Effect of dietary sucrose on synthesis and degradation of intestinal sucrase. Am J Physiol 246:G757-G763
Sell JL, Koldovsky O, Reid BL (1989) Intestinal disaccharidases of young turkeys: temporal development and influence of diet composition. Poultry Sci 68:265–277
Semenza G, Auricchio S (1989) Small-intestinal disaccharidases. In: Scribner CR et al (eds) The metabolic basis of inherited disease. McGraw Hill, New York, pp 2975–2997
Siddons RC (1969) Intestinal disaccharidase activities in the chick. Biochem J 112:51–59
Siddons RC (1970) Heat inactivation and sephadex chromatography of the small-intestine disaccharidases of the chick. Biochem J 116:71–78
Siddons RC (1972) Effect of diet on disaccharidase activity in the chick. Br J Nutr 27:343–352
Swaminathan N, Radhakrishan AN (1965) Distribution of α-glucosidase activities in human and monkey small intestine. Indian J Biochem Biophys 2:159–163
Tarvid I (1991) Early development of peptide hydrolysis in chicks and guinea pigs. Comp Biochem Physiol 99A:441–447
Taylor CR, Weibel ER (1981) Design of the mammalian respiratory system. I. Problem and strategy. Respir Physiol 44:1–10
Toloza EM, Diamond JM (1990) Ontogenetic development of nutrient transporters in bullfrog intestine. Am J Physiol 258:G760-G769
Triadou N, Bataille J, Schmitz J (1983) Longitudinal study of the human intestinal brush border membrane proteins: distribution of the main disaccharidases and peptidases. Gastroenterology 85:1326–1332
Tsuboi KK, Kwong LK, Burrill PH, Sunshine P (1979) Sugar hydrolases and their arrangement on the rat intestinal microvillus membrane. J Membr Biol 50:101–122
Tsuboi KK, Kwong LK, Yamada K, Sunshine P, Koldovsky O (1985) Nature of elevated rat intestinal carbohydrase activities after high-carbohydrate diet feeding. Am J Physiol 249:G510-G517
Tur JA, Rial RV, Rayó JM, Tarraga SA, Dameto CM (1988) Developmental study of digestive motor response to dietary patterns in young broilers. Comp Biochem Physiol 90A:241–247
Weibel ER, Taylor CR (1981) Design of the mammalian respiratory system. Respir physiol 44:1–164
Weibel ER, Taylor CR, Hoppeler H (1991) The concept of symmorphosis: a testable hypothesis of structure-function relationships. Proc Natl Acad Sci 88:10357–10361
Yamada K, Bustamante S, Koldovsky O (1981) Dietary-induced rapid increase of rat jejunal sucrase and lactase activity in all regions of the villus. FEBS Lett 129:89–92
Yeh KY, Holt PR (1986) Ontogenetic timing mechanism initiates the expression of rat intestinal sucrase activity. Gastroenterology 90:520–526
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Biviano, A.B., Martínez del Rio, C. & Phillips, D.L. Ontogenesis of intestine morphology and intestinal disaccharidases in chickens (Gallus gallus) fed contrasting purified diets. J Comp Physiol B 163, 508–518 (1993). https://doi.org/10.1007/BF00346936
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00346936