Hostname: page-component-cd9895bd7-mkpzs Total loading time: 0 Render date: 2024-12-27T11:21:39.068Z Has data issue: false hasContentIssue false
  • English
  • Français

Portal vein, hepatic vein and circulating plasma amino acids in rats given diets based on lactalbumin, faba bean (Vicia faba) and chickpea (Cicer arietinum)

Published online by Cambridge University Press:  18 August 2016

L. A. Rubiot
L. A. Rubiot*
Affiliation:
Estación Experimental del Zaidín, Unidad de Nutrición, Profesor Albareda, 1, 18008 Granada, Spain
*
E-mail:lrubio@eez.csic.es
Get access

Abstract

Three experiments were carried out to determine plasma amino acids concentrations in circulating, portal and hepatic blood of growing male Wistar rats given diets containing lactalbumin, faba beans or chickpeas as the only protein source. Diets contained the same amount of digestible energy (15·5 kJ/g) and protein (lactalbumin in controls or legume proteins in the experimental diets; 100 g/kg). Appropriate amounts of essential synthetic amino acids were also added to legume-based diets taking into account their amino acid composition to equalize them to control (lactalbumin) diets. Portal blood flow (8·7±0·3 ml/min) was measured by using a transit-time ultrasound flow probe. Higher (P < 001) plasma concentrations of methionine than of controls were determined in hepatic veins of legume-fed rats. In contrast, lower (P < 001) concentrations of threonine, proline, valine, leucine, phenylalanine and lysine than those of controls were found in faba bean- and chickpea-fed rats. The same result as hepatic was obtained for portal and circulating plasma samples except that alanine and histidine values of legume-fed rats were also lower (P < 001) than controls. Calculated net afferent appearance rates of amino acids to the liver were lower (P < 001) than controls in rats given faba bean and chickpea diets for threonine, alanine, proline, valine, leucine, phenylalanine and lysine. This lower contribution of amino acids to the liver mainly via the portal vein in faba bean or chickpea-fed rats might explain previously reported differences in protein utilization and growth in comparison with animals given other protein sources (lactalbumin).

Keywords

amino acidsCicer arietinumlactalbuminratsVicia faba
Type
Growth, development and meat science
Information
Animal Science , Volume 77 , Issue 1 , August 2003 , pp. 3 - 10
Copyright
Copyright © British Society of Animal Science 2003

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Batterham, E. S., Andersen, L. M., Burnham, B. V. and Taylor, G. A. 1986a. Effect of heat on the antinutritional value of lupin (Lupinus angustifolius)-seed meal for growing pigs. British Journal of Nutrition 55: 169177.Google Scholar
Batterham, E. S., Andersen, L. M., Lowe, R. F. and Darnell, R. E. 1986b. Nutritional value of lupin (Lupinus albus)-seed meal for growing pigs: availability of lysine, effect of autoclaving and net energy content. British Journal of Nutrition 56: 645659.Google Scholar
Benevenga, N. J., Gahl, M. J. and Blemings, K. P. 1993. Role of protein synthesis in amino acid catabolism. Journal of Nutrition 123: 332336.Google Scholar
Broirie, Y., Dangin, M., Gachon, P., Vasson, M. P., Maubois, J. L. and Beaufrère, B. 1997. Slow and fast dietary proteins differently modulate postprandial protein accretion. Proceedings of the National Academy of Sciences of the United States of America 94: 1493014936.Google Scholar
Caillard, I. and Tome, D. 1994. Modulation of beta-lactoglobulin transport in rabbit ileum. American Journal of Physiology 266: G1053-G1059.Google Scholar
D´Almeida, M. S., Gaudin, C. and Lebrec, D. 1995. Validation of 1-, and 2-mm transit-time ultrasound flow probes on mesenteric artery and aorta of rats. American Journal of Physiology 268: H1368-H1372.Google Scholar
Das, T. K. and Waterlow, J. C. 1974. The rate of adaptation of urea cycle enzymes, aminotransferases and glutamic dehydrogenase to changes in dietary protein intake. British Journal of Nutrition 32: 353373.Google Scholar
Fafournoux, P., Rémésy, C. and Demigné, C. 1990. Fluxes, and membrane transport of amino acids in rat liver under different protein diets. American Journal of Physiology 259: E614-E625.Google ScholarPubMed
Fernández-Fígares, I., Lachica, M., Pérez, L., Nieto, R., Aguilera, J. F. and Prieto, C. 1993. The effect of dietary protein quality on free amino acids in plasma, muscle and liver of growing chickens. Animal Production 57: 309318.Google Scholar
Fernández-Fígares, I., Prieto, C., Nieto, R. and Aguilera, J. F. 1997. Free amino acid concentrations in plasma, muscle, and liver as indirect measures of protein adequacy in growing chickens. Animal Science 64: 529539.Google Scholar
Fernández-López, J. A., Casado, J., Rafecas, I., Esteve, M., Argilés, J. M., Remesar, X. and Alemany, M. 1993. Intestinal, and hepatic nitrogen balance in the rat after the administration of an oral protein load. British Journal of Nutrition 69: 733742.Google Scholar
Friedrich, M., Noack, J., Proll, J. and Noack, R. 1984. Absorption of enzymatic protein hydrolysates and equimolar amino acid mixtures in the perfused small intestine of the rat. Biomedica Biochimica Acta 43: 117130.Google Scholar
Galibois, I., Parent, G. and Savoie, L. 1987. Effect of dietary proteins on the time-dependent changes in plasma amino acid levels and on liver protein synthesis in rats. Journal of Nutrition 117: 20272035.Google Scholar
Galibois, I., Simoes Nunes, C., Rérat, A. and Savoie, L. 1989. Net appearance of amino acids in portal blood during the ingestion of casein or rapeseed proteins in the pig. Canadian Journal of Physiology and Pharmacology 67: 14091417.Google Scholar
Gardner, M. L., Lindblad, B. S., Burston, D. and Matthews, D. M. 1983. Trans-mucosal passage of intact peptides in the guinea-pig small intestine in vivo: a reappraisal. Clinical Science 64: 433439.Google Scholar
Goena, M., Santidrián, S., , Cuevillas, F. and Larralde, J. 1988. Muscle and liver protein synthesis and degradation in growing rats fed a raw field bean (Vicia faba L. ) diet. Revista Española de Fisiología 44: 345352.Google Scholar
Grant, G., Dorward, P. and Pusztai, A. 1993. Pancreatic enlargement is evident in rats fed diets containing soybean (Glycine max) or cowpea (Vigna ungiculata) for 800 days but not in those given diets based on kidney bean (Phaseolus vulgaris) or lupin seed (Lupinus angustifolius). Journal of Nutrition 123: 22072215.Google Scholar
Hajós, G., Gelencsér, E., Grant, G., Bardocz, S., Sakhri, M., Duguid, T., Newman, A. M. and Pusztai, A. 1996. Effect of proteolyic modification, and methionine enrichment on the nutritional value of soya albumins for rats. Journal of Nutritional Biochemistry 7: 481487.CrossRefGoogle Scholar
Hartman, W. J. and Prior, R. 1992. Dietary arginine deficiency alters flux of glutamine and urea cycle intermediates across the portal-drained viscera and liver of rats. Journal of Nutrition 122: 14721482.Google Scholar
Ishise, S., Pegram, B. L., Yamamoto, J., Kitamura, Y. and Frohlich, E. D. 1980. Reference sample microsphere method: cardiac output, and blood flows in conscious rat. American Journal of Physiology 239: H443-H449.Google Scholar
Jansman, A. J. M., Hill, G. D., Huisman, J. and Poel, A. F. B. van der. 1998. Recent advances of research in antinutritional factors in legume seeds. Wageningen Pers, Wageningen, The Netherlands.Google Scholar
Kuwahira, I., González, N. C., Heisler, N. and Piper, J. 1993. Regional blood flow in conscious resting rats determined by microsphere distribution. Journal of Applied Physiology 74: 203210.Google Scholar
National Research Council. 1995. Nutrient requirements of laboratory animals. National Academy Press, Washington, DC.Google Scholar
Nielsen, K., Kondrup, J., Elsner, P., Juul, A. and Jensen, E. S. 1994. Casein, and soya-bean protein have different effects on whole body protein turnover at the same nitrogen balance. British Journal of Nutrition 72: 6981.Google Scholar
Nielsen, S. S. 1991. Digestibility of legume proteins. Food Technology 45: 112118.Google Scholar
Prieto, C., Aguilera, J. F., Lachica, M., Fernández-Fígares, I., Pérez, L., Nieto, R. and Ferrando, G. 1994. The use of plasma free amino acids for predicting the limiting amino acid(s) in diets for chickens. Animal Feed Science and Technology 47: 151164.Google Scholar
Prior, R. L. 1993. Time after feeding, and dietary arginine deficiency alter splanchnic, and hepatic amino acid flux in rats. Journal of Nutrition 123: 15381553.Google Scholar
Rémésy, C. and Demigné, C. 1983. Changes in availability of glucogenic, and ketogenic substrates, and liver utilization in fed or starved rats. Annales de Nutrition et Metabolisme 27: 5770.Google Scholar
Rémésy, C., Fafournoux, P. and Demigné, C. 1983. Control of hepatic utilization of serine, glycine, and threonine in fed, and starved rats. Journal of Nutrition 113: 2839.Google Scholar
Rérat, A., Simoes Nunes, C., Mendy, P. and Roger, L. 1987. Absorption kinetics of amino acids from amino acid mixtures of the same composition perfused into the small intestine in the free form or as enzymic milk protein hydrolysates in the conscious pig. Proceedings of the Nutrition Society 46: 104a.Google Scholar
Rérat, A. A. 1985. Intestinal absorption of end products from digestion of carbohydrates and proteins in the pig. Archives of Animal Nutrition 35: 461480.Google ScholarPubMed
Rubio, L. A. 2000. Physiological effects of legume storage proteins. Nutrition Abstracts and Reviews 70: 531538.Google Scholar
Rubio, L. A., Grant, G., Bardocz, S., Dewey, P. and Pusztai, A. 1991. Nutritional response of growing rats to faba beans (Vicia faba), and faba bean fractions. British Journal of Nutrition 66: 533542.Google Scholar
Rubio, L. A., Grant, G., Caballé, C., Martinez-Aragón, A. and Pusztai, A. 1994. High in vivo (rat) digestibility of faba bean (Vicia faba), lupin (Lupinus angustifolius), and soybean (Glycine max) globulins. Journal of the Science of Food and Agriculture 66: 289292.Google Scholar
Rubio, L. A., Grant, G., Daguid, T., Brown, D., Bardocz, S. and Pusztai, A. 1998. The nutritional utilization by rats of chickpea (Cicer arietinum) meal, and its isolated globulin proteins is poorer than that of defatted soybean or lactalbumin. Journal of Nutrition 128: 10421047.Google Scholar
Rubio, L. A., Grant, G., Daguid, T., Brown, D. and Pusztai, A. 1999. Organ relative weights, and plasma amino acid concentrations in rats fed diets based in legume (faba bean, lupin, chickpea, soybean) seed meals or their fractions. Journal of the Science of Food and Agriculture 79: 187194.Google Scholar
Rubio, L. A., Grant, G., Scislowsky, P., Brown, D., Annand, M. and Pusztai, A. 1995. The utilization of lupin (Lupinus angustifolius) and faba bean globulins by rats is poorer than of soybean globulins or lactalbumin but the nutritional value of lupin seed meal is lower only than that of lactalbumin. Journal of Nutrition 125: 21452155.Google Scholar
Rubio, L. A., Muzquiz, M., Burbano, C., Cuadrado, C. and Pedrosa, M. M. 2002. High apparent ileal digestibility of amino acids in raw or germinated faba bean- (Vicia faba) or chickpea- (Cicer arietinum) based diets for rats. Journal of the Science of Food and Agriculture 82: 17021717.Google Scholar
Rubio, L. A. and Seiquer, I. 2002. Transport of amino acids from in vitro digested legume proteins or casein in Caco-2 cell cultures. Journal of Agricultural and Food Chemistry 50: 52025206.Google Scholar
Webb, K. E. 1990. Intestinal absorption of protein hydrolysis products: a review. Journal of Animal Science 68: 30113022.Google Scholar
Wu, G. 1998. Intestinal mucosal amino acid catabolism. Journal of Nutrition 128: 12491252.CrossRefGoogle ScholarPubMed