Abstract
We previously demonstrated in intact house sparrows substantial absorption in vivo of L-glucose, the stereoisomer of D-glucose that is assumed not to interact with the intestine’s D-glucose transporter. Results of some studies challenge this assumption for other species. Therefore, we tested it in vitro and in vivo, based on the principle that if absorption of a compound (L-glucose) is mediated, then absorption of its tracer will be competitively inhibited by high concentrations of either the compound itself or other compounds (e.g., D-glucose) whose absorption is mediated by the same mechanism. An alternative hypothesis that L-glucose absorption is primarily paracellular predicts that its absorption in vivo will be increased (not decreased) in the presence of D-glucose, because the permeability of this pathway is supposedly enhanced when Na+-coupled glucose absorption occurs. First, using intact tissue in vitro, we found that uptake of tracer-radiolabeled L-glucose was not significantly inhibited by high concentrations (100 mM) of either L-glucose or 3-O-methyl-D-glucose, a non-metabolizable but actively transported D-glucose analogue. Second, using intact house sparrows, we found that fractional absorption of the L-glucose tracer was significantly increased, not reduced, when gavaged along with 200 mM 3-O-methyl-D-glucose. This result was confirmed in another experiment where L-glucose fractional absorption was significantly higher in the presence vs. absence of food in the gut. The greater absorption was apparently not due simply to longer retention time of digesta, because no significant difference was found among retention times. Our results are consistent with the idea that L-glucose is absorbed in a non-mediated fashion, largely via the paracellular pathway in vivo.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
Abbreviations
- AUC :
-
area under the curve
- 3OMD-glucose :
-
3-O-methyl-D-glucose
References
Afik D, McWilliams SR, Karasov WH (1997) A test for passive absorption of glucose in yellow-rumped warblers and its ecological significance. Physiol Zool 70:370–377
Berliner RW, Kennedy TJ, Hilton JG (1955) Renal clearance of ferrocyanide in the dog. Am J Physiol 160:325–329
Caspary W, Crane RK (1968) Inclusion of L-glucose within the specificity limits of the active sugar transport system of hamster small intestine. Biochim Biophys Acta 163:395–400
Caviedes-Vidal E, Karasov WH (1996) Glucose and amino acid absorption in house sparrow intestine and its dietary modulation. Am J Physiol 271:R561–R568
Chang MH, Karasov WH (2001) Similar extent and rate of absorption of D- and L-glucose in house sparrows, Passer domesticus. FASEB J 15:A830
Chediack JG, Caviedes-Vidal E, Karasov WH, Pestchanker M (2001) Passive absorption of hydrophilic probes by house sparrows, Passer domesticus. J Exp Biol 204:723–731
Chediack JG, Caviedes-Vidal E, Fasulo V, Yamin LJ, Karasov WH (2003) Intestinal passive absorption of water soluble compounds by sparrows: effect of molecular size and luminal nutrients. J Comp Physiol B 173:187–197
Ferraris RP, Yasharpour S, Lloyd KCK, Mirzayan R, Diamond JM (1990) Luminal glucose concentrations in the gut under normal conditions. Am J Physiol 259:G822–G837
Karasov WH (1996) Digestive plasticity in avian energetics and feeding ecology. In: Carey C (ed) Avian energetics and nutritional ecology. Chapman and Hall, New York, pp 61–84
Karasov WH, Cork SJ (1994) Glucose absorption by a nectarivorous bird: the passive pathway is paramount. Am J Physiol 267:G18–G26
Karasov WH, Diamond JM (1983) A simple method for measuring solute uptake in vitro. J Comp Physiol B152:105–116
Kellett GL (2001) The facilitated component of intestinal glucose transport. J Physiol 531:585–595
Lennernas H (1995) Does fluid flow across the intestinal mucosa affect quantitative oral drug absorption? Is it time for a reevaluation? Pharm Res 12:1573–1582
Levey DJ, Cipollini ML (1996) Is most glucose absorbed passively in northern bobwhite? Comp Biochem Physiol A 113:225–231
Madara JL, Pappenheimer JR (1987) Structural basis for physiological regulation of paracellular pathways in intestinal epithelia. J Membr Biol 100:149–164
Malo C, Berteloot A (1991) Analysis of kinetic data in transport studies: new insights from kinetic studies of Na+ -D-glucose cotransport in human intestinal brush-border membrane vesicles using a fast sampling, rapid filtration apparatus. J Membr Biol 122:127–141
McWilliams SR, Karasov WH (1998) Test of a digestion optimization model: effects of costs of feeding on digestive parameters. Physiol Zool 71:168–178
Meddings JB, Westergaard H (1989) Intestinal glucose transport using perfused rat jejunum in vivo: model analysis and derivation of corrected kinetic constants. Clin Sci 76:403–414
Pappenheimer JR (1987) Physiological regulation of transepithelial impedance in the intestinal mucosa of rats and hamsters. J Membr Biol 100:137–148
Pappenheimer JR, Reiss KZ (1987) Contribution of solvent drag through intercellular junctions to absorption of nutrients by the small intestine of the rat. J Membr Biol 100:123–136
Pappenheimer JR, Volpp K (1992) Transmucosal impedance of small intestine: correlation with transport of sugars and amino acids. Am J Physiol 263:C480–C493
Restrepo D, Kimmich GA (1985) Kinetic analysis of mechanisms of intestinal Na+-dependent sugar transport. Am J Physiol 248:C498–C509
Sadowski DC, Meddings JB (1993) Luminal nutrients alter tight-junction permeability in the rat jejunum: an in vivo perfusion model. Can J Physiol Pharmacol 71:835–839
Schwartz RM, Furner JK, Levitt MD (1995) Paracellular intestinal transport of six-carbon sugars is negligible in the rat. Gastroenterol 109:1206–1213
See NA, Bass P (1993) Nutrient-induced changes in the permeability of the rat jejunal mucosa. J Pharm Sci 82:721–724
Solberg DH, Diamond JM (1987) Comparison of different dietary sugars as inducers of intestinal sugar transporters. Am J Physiol 252:G574–G584
Stangel PW (1986) Lack of effects from sampling blood from small birds. Condor 88:244–245
Starck JM, Karasov WH, Afik D (2000) Intestinal nutrient uptake measurements and tissue damage. Validating the everted sleeves method. Physiol Biochem Zool 73:454–460
Steil GM, Richey J, Kim JK, Wi JK, Rebrin K, Bergman RN, Youn JH (1996) Extracellular glucose distribution is not altered by inulin:analysis of plasma and interstitial L-glucose kinetics. Am J Physiol 271:E855–E864
Thomson ABR, Hotke CA, Weinstein WM (1982) Comparison of kinetic constants of hexose uptake in four animal species and man. Comp Biochem Physiol A 72:225–236
Turner JR, Madara JL (1995) Physiological regulation of intestinal epithelial tight junctions as a consequence of Na+-coupled nutrient transport. Gastroenterology 109:1391–1396
Uhing MR, Kimura RE (1995) Active transport of 3-O-methyl-glucose by the small intestine in chronically catheterized rats. J Clin Invest 95:2799–2805
Warner ACI (1981) Rate of passage of digesta through the gut of mammals and birds. Nutr Abstr Rev 51:789–820
Welling PG (1986) Pharmacokinetics: processes and mathematics. Am Chem Soc, Washington, D.C.
Wilkinson L (1992) Systat for windows: statistics, version 5. Systat, Evanston, Ill.
Yemm EW, Willis AJ (1954) The estimation of carbohydrates in plant extracts by anthrone. Biochem J 57:508–514
Yu LX, Amidon GL (1998) Saturable small intestinal drug absorption in humans: modeling and interpretation of cefaatrizine data. Eur J Pharm Biopharm 45:199–203
Yuasa H, Numata W, Ozeki S, Watanabe J (1995) Effect of dosing volume on gastrointestinal absorption in rats: analysis of the gastrointestinal disposition of L-glucose and estimation of in vivo intestinal membrane permeability. J Pharm Sci 84:476–481
Acknowledgements
We thank Dr. Ronald Burnette at the Department of Pharmacy, University of Wisconsin–Madison for providing logistic help, and Arijana Barun and Bruce Darken for their help during the experiment. The work was supported by FONCYT (01-03101) to E. Caviedes-Vidal, and NSF IBN-9723793, IBN-0216709 and the Max McGraw Wildlife Foundation to W.H. Karasov. The routine animal care procedures and experimental protocol used in this study were reviewed and approved by the University of Wisconsin Research Animal Resources Center.
Author information
Authors and Affiliations
Corresponding author
Additional information
Communicated by I.D. Hume
Rights and permissions
About this article
Cite this article
Chang, MH., Chediack, J.G., Caviedes-Vidal, E. et al. L-glucose absorption in house sparrows (Passer domesticus) is nonmediated. J Comp Physiol B 174, 181–188 (2004). https://doi.org/10.1007/s00360-003-0403-3
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00360-003-0403-3