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Riboflavin deficiency in the rat: effects on iron utilization and loss

Published online by Cambridge University Press:  09 March 2007

Hilary J. Powers ,
L. T. Weaver ,
S. Austin ,
A. J. A. Wright  and
Susan J. Fairweather-Tait
Hilary J. Powers
Affiliation:
MRC Dunn Nutrition Unit, Milton Road, Cambridge CB4 IXJ
L. T. Weaver
Affiliation:
MRC Dunn Nutrition Unit, Milton Road, Cambridge CB4 IXJ
S. Austin
Affiliation:
MRC Dunn Nutrition Unit, Milton Road, Cambridge CB4 IXJ
A. J. A. Wright
Affiliation:
AFRC Institute of Food Research, Norwich Laboratory, Colney Lane, Norwich NR4 7UA
Susan J. Fairweather-Tait
Affiliation:
AFRC Institute of Food Research, Norwich Laboratory, Colney Lane, Norwich NR4 7UA
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Abstract

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Iron absorption and daily loss of Fe were measured in riboflavin-deficient (B2-) Norwegian hooded rats and controls (B2+). Animals were fed on a test meal extrinsically labelled with 59Fe and whole-body radioactivity measured for 15 d. Riboflavin deficiency led to a reduction in the percentage of the 59Fe dose absorbed and an increased rate of 59Fe loss. All post-absorption 59Fe loss could be accounted for by faecal 59Fe, confirming that the loss was gastrointestinal. Fe concentrations and 59Fe as a percentage of retained whole-body 59Fe were higher in the small intestine of riboflavin-deficient animals than their controls, 14 d after the test meal. A separate experiment demonstrated that riboflavin deficiency was associated with a significant proliferative response of the duodenal crypts of the small intestine. These observations may explain the enhanced Fe loss in riboflavin deficiency.

Keywords

IronCrypt cell proliferationRat
Type
Effects of Altered Vitamin Status
Information
British Journal of Nutrition , Volume 65 , Issue 3 , May 1991 , pp. 487 - 496
Copyright
Copyright © The Nutrition Society 1991

References

REFERENCES

Adelekan, D. A. & Thurnham, D. I. (1986) A longitudinal study of the effect of riboflavin status on aspects of iron storage in the liver of growing rats. British Journal of Nutrition 56, 171179.CrossRefGoogle Scholar
Björn-Rasmussen, E., Carneskog, J. & Cederblad, A. (1980). Losses of ingested iron temporarily retained in the gastrointestinal tract. Scandinavian Journal of Haematology 25, 124126.CrossRefGoogle ScholarPubMed
Buzina, R., Jusic, M., Milanovic, N., Sapunar, J. & Brubacher, G. (1979). The effects of riboflavin administration on iron metabolism parameters in a school-going population. International Journal of Vitamin and Nutrition Research 49, 136143.Google Scholar
Duerden, J. M. & Bates, C. J. (1985). Effect of riboflavin deficiency on reproductive performance and on biochemical indices of riboflavin status in the rat. British Journal of Nutrition 53, 97105.CrossRefGoogle ScholarPubMed
Fairweather-Tait, S. J., Swindell, T. E. & Wright, A. J. A. (1985). Further studies in rats on the influence of previous iron intake on the estimation of bioavailability of iron. British Journal of Nutrition 54, 7986.CrossRefGoogle Scholar
Fairweather-Tait, S. J. & Wright, A. J. A. (1984). The influence of previous iron intake on the estimation of bioavailability of Fe from a test meal given to rats. British Journal of Nutrition 51, 185191.CrossRefGoogle ScholarPubMed
Green, R., Charlton, R., Seftel, H., Bothwell, T., Mayet, F., Adams, B., Finch, C. & Layrisse, M. (1968). Body iron excretion in man. American Journal of Medicine 45, 336353.CrossRefGoogle ScholarPubMed
Guy, M. J. & Schachter, D. (1975). Active transport of iron to mucosal surface of rat jejunum. American Journal of Physiology 229, 790796.CrossRefGoogle ScholarPubMed
Johnson, P. E. (1984). Stable isotopes of iron, zinc and copper used to study mineral absorption in humans. In Stable Isotopes in Nutrition, ACS Symposium Series no. 258, pp. 139155 [Turnlund, J. R. and Johnson, P. E., editors]. Washington DC: American Chemical Society.CrossRefGoogle Scholar
Linder, M. & Munro, H. M. (1977). The mechanism of iron absorption and its regulation. Federation Proceedings 36, 20172023.Google ScholarPubMed
Miyaji, K. & Hala, Y. (1965). Effect of riboflavin or iron deficiency on the cell renewal rate of intestinal mucosa. Vitamins 31, 185191.Google Scholar
Powers, H. J. (1986). Investigation into the relative effects of riboflavin deprivation on iron economy in the weaning rat and the adult. Annals of Nutrition and Metabolism 30, 308315.CrossRefGoogle Scholar
Powers, H. J. (1987). A study of maternofetal iron transfer in the riboflavin-deficient rat. Journal of Nutrition 117, 852856.CrossRefGoogle ScholarPubMed
Powers, H. J., Bates, C. J. & Duerden, J. M. (1983 a). Effects of riboflavin deficiency in rats on some aspects of iron metabolism. International Journal of Vitamin and Nutrition Research 53, 371376.Google ScholarPubMed
Powers, H. J., Bates, C. J., Prentice, A. M., Lamb, W. H., Jepson, M. & Bowman, H. (1983 b). The relative effectiveness of iron and iron with riboflavin in correcting a microcytic anaemia in men and children in rural Gambia. Human Nutrition: Clinical Nutrition 37C, 413425.Google Scholar
Powers, H. J., Wright, A. J. A. & Fairweather-Tait, S. J. (1988). The effect of riboflavin deficiency in rats on the absorption and distribution of iron. British Journal of Nutrition 59, 381387.CrossRefGoogle Scholar
Refsum, S. B. & Schreiner, B. (1980). Iron excretion from the goblet cells of the small intestine in man. Journal of Gastroenterology 15, 10131020.Google ScholarPubMed
Schreiner, B. & Refsum, S. B. (1983). Letter. Lancet i, 1385.Google Scholar
Sirivech, S., Driskell, J. & Frieden, E. (1977). NADH:FMN oxidoreductase activity and iron content of rat organs from riboflavin-deficient and iron-deficient rats. Journal of Nutrition 107, 739745.CrossRefGoogle ScholarPubMed
Ulvik, R. J. & Romslo, I. (1981). Reduction of exogenous FMN by isolated rat liver mitochondria. Significance to the mobilization of iron from ferritin. Biochimica et Biophysica Acta 635, 457469.CrossRefGoogle Scholar
Wright, N. A. & Appleton, D. R. (1980). The metaphase arrest technique: a critical review. Cell Tissue Kinetics 13, 643663.Google ScholarPubMed
Wright, N. A. & Irwin, M. (1982). The kinetics of villus cell populations in the mouse small intestine. Cell Tissue Kinetics 15, 596609.Google ScholarPubMed
Zaman, S. & Verwilghen, R. L. (1977). Effect of riboflavin deficiency on activity of NADH-FMN oxidoreductase (ferriductase) and iron content of rat liver. Biochemical Society Transactions 5, 306.CrossRefGoogle ScholarPubMed