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Intestinal microflora, morphology and enzyme activity in zinc-deficient and Zn-supplemented rats

Published online by Cambridge University Press:  09 March 2007

Susan Southon ,
Jennifer M. Gee ,
Catherine E. Bayliss ,
G. M. Wyatt ,
Nikki Horn  and
I. T. Johnson
Susan Southon
Affiliation:
AFRC Food Research Institute Norwich, Colney Lane, Norwich NR4 7UA
Jennifer M. Gee
Affiliation:
AFRC Food Research Institute Norwich, Colney Lane, Norwich NR4 7UA
Catherine E. Bayliss
Affiliation:
AFRC Food Research Institute Norwich, Colney Lane, Norwich NR4 7UA
G. M. Wyatt
Affiliation:
AFRC Food Research Institute Norwich, Colney Lane, Norwich NR4 7UA
Nikki Horn
Affiliation:
AFRC Food Research Institute Norwich, Colney Lane, Norwich NR4 7UA
I. T. Johnson
Affiliation:
AFRC Food Research Institute Norwich, Colney Lane, Norwich NR4 7UA
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Abstract

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1. Immature, male Wistar rats were given a low-zinc diet (2 mg/kg) for 22–24 d. Control groups received a similar diet supplemented with 58 mg Zn/kg either ad lib., or in amounts matched to the consumption of the Zn-deficient group. Food consumption, rate of growth and food conversion efficiency were markedly lower in the Zn-deficient group of rats compared with controls. Appetite, growth rate and food utilization improved dramatically over a subsequent 4 d period of Zn supplementation.

2. Morphological examination of samples of jejunum and ileum confirmed that Zn deficiency in the rat is accompanied by a reduction in villous dimensions and increase in villous density. After a short period of Zn supplementation, villous density and the basal width and maximum height of individual villi in the jejunum returned to normal. Similar changes occurred in the ileum but to a lesser extent.

3. Mucosal alkaline phosphatase (EC 3.1.3.1) activity was significantly lower in the small intestine of Zn-deficient rats compared with Zn-supplemented rats. Disaccharidase activities were lower in the Zn-deficient group, compared with their feed-restricted counterparts, but were similar to values for ad lib.-fed controls. Tissue alkaline phosphatase and disaccharidase activitities were consistently higher after a 4 d period of Zn supplementation, compared with non-supplemented animals, but this increase was only significant for alkaline phosphatase.

4. Although there were striking similarities in the mucosal characteristics of gnotobiotic and Zn-deficient rats, there was no indication that even severe dietary Zn depletion reduced the numbers of viable bacteria present in either the small or large intestine. Changes in intestinal structure and function resulting from variation in dietary Zn intake appear, therefore, to be unrelated to changes in the intestinal flora.

Type
Papers on General Nutrition
Information
British Journal of Nutrition , Volume 55 , Issue 3 , May 1986 , pp. 603 - 611
Copyright
Copyright © The Nutrition Society 1986

References

REFERENCES

Abrams, G. D. (1977). American Journal of Clinical Nutrition 30, 18801886.CrossRefGoogle Scholar
Abrams, G. D., Bauer, H. & Sprinz, H. (1963). Laboratory Investigation 12, 355364.Google Scholar
Abrams, G. D. & Bishop, J. E. (1967). Proceedings of fhe Society of Experimental and Biological Medicine 126, 301304.CrossRefGoogle Scholar
Bryant, M. P. & Burkey, L. A. (1953). Journal of Dairy Science 36, 205217.CrossRefGoogle Scholar
Clarke, R. M. (1970). Journal of Anatomy 107, 519529.Google Scholar
Croucher, S. C., Houston, A. P., Bayliss, C. E. & Turner, R. J. (1983). Applied and Environmental Microbiology 45, 10251033.CrossRefGoogle Scholar
Davies, N. T. (1980). British Journal of Nurrition 45, 189203.CrossRefGoogle Scholar
de Both, N. J., van Dongen, J. M., van Hofwegen, B., Keuleman, J., Visser, W. J. & Galjaard, H. (1974). Developmental Biology 38, 119137.CrossRefGoogle Scholar
Gordon, H. A. & Bruckner-Kardoss, E. (1961). American Journal of Physiology 201, 175178.CrossRefGoogle Scholar
Harris, A. B. (1969). Journal of General Microbiology 52, 2733.CrossRefGoogle Scholar
Heneghan, J. B. (1963). American Journal of Physiology 205, 417420.CrossRefGoogle Scholar
Jackson, M. J., Jones, D. A. & Edwards, R. H. (1981). British Journal of Nutrition 52, 477487.Google Scholar
Johnson, I. T., Gee, J. M. & Mahoney, R. R. (1984). British Journal of Nuirition 52, 477487.CrossRefGoogle Scholar
Luecke, R. W., Olman, M. E. & Baltzer, B. V. (1968). Journal of Nutrition 94, 344350.CrossRefGoogle Scholar
Reddy, B. S. & Wostmann, B. S. (1966). Archives of Biochemistry 113, 609616.CrossRefGoogle Scholar
Southon, S., Gee, J. M. & Johnson, I. T. (1984). British Journal of Nutrition 52, 371380.CrossRefGoogle Scholar
Southon, S., Gee, J. M. & Johnson, I. T. (1986). British Journal ofNutrition 55, 193200.CrossRefGoogle Scholar
Southon, S., Johnson, I. T., Gee, J. M. & Gee, M. G. (1982). Proceedings ofthe Nutrition Society 41, 134A.Google Scholar
Southon, S., Livesey, G., Gee, J. M. & Johnson, I. T. (1985). British Journal of Nutrition 53, 595603.CrossRefGoogle Scholar
Summers, R. J. & Scrinivasan, V. R. (1979). Applied and Environmental Microbiology 37, 10791084.CrossRefGoogle Scholar
Thompson, G. R. & Trexler, P. C. (1971). Gut 12, 230235.CrossRefGoogle Scholar
Valle, B. L. & Falchuk, K. H. (1981). Philosophical Transactions of the Royal Society 294, 185197.Google Scholar
Williams, R. B. (1972). British Journal of Nutrition 27, 121130.CrossRefGoogle Scholar