Hostname: page-component-586b7cd67f-t7czq Total loading time: 0 Render date: 2024-11-28T15:23:53.200Z Has data issue: false hasContentIssue false
  • English
  • Français

Wool growth of pregnant and lactating Merino ewes

Published online by Cambridge University Press:  27 March 2009

V. H. Oddy
V. H. Oddy
Affiliation:
Nutrition and Feed Evaluation Unit, N.S.W. Department of Agriculture, Glenfield, N.S.W., 2167, Australia
Get access Rights & Permissions [Opens in a new window]

Summary

The wool production of pregnant, lactating and non-pregnant, non-lactating (dry) Merino ewes eating one of three diets: chaffed oaten hay (OH), chaffed lucerne hay (LH), and a 50/50 (w/w) mixture of OH and LH, was determined. Measurements were made for 2 months prior to mating, during pregnancy and for 3 months after lambing, and for the dry ewes over the same period.

Production of clean wool (Y, g/day) by dry ewes was linearly related to digestible organic matter intake (X, g/day):

Y = 0·0301 X - 3·34, r = 0·97.

Clean wool growth was significantly less (P < 0·01) than dry ewes in the 4th and 5th month of pregnancy and throughout lactation. During pregnancy the total deficit in clean wool growth (calculated as the difference between observed wool growth and that expected on the basis of the relationship between feed intake and clean wool growth of dry ewes) was 456 g for ewes bearing a single lamb and 578 g for those bearing twins, with no difference between diets. In lactation the total clean wool growth deficit increased as milk production increased, and for every litre of milk produced there was a deficit of 12 g clean wool.

Wool fibre diameter was reduced during the 1st month of lactation. There was no consistent effect of pregnancy or lactation on the number of wool follicles per mm2, the ratio of primary plus secondary to primary wool follicles, or on the thickness of skin on the midside.

Digestibility of dietary organic matter (DOM) was reduced during the last 3 months of pregnancy, and the first 2 months of lactation. However, this was insufficient to account for the magnitude of the decrease in wool growth seen during pregnancy and lactation.

Wool sulphur content increased during pregnancy (P < 0·001), but not during lactation. The relationship between total plasma cyst(e)ine concentration and DOM intake during pregnancy was similar to that in dry ewes, but during lactation total plasma cyst(e)ine concentration was less than expected. It was calculated that during pregnancy the amount of sulphur saved through reduced wool growth was greater than that deposited in the conceptus, and during lactation the amount of sulphur saved in reduced wool growth matched that excreted as milk.

These results are discussed in relation to control of wool growth during pregnancy and lactation.

Type
Research Article
Information
The Journal of Agricultural Science , Volume 105 , Issue 3 , December 1985 , pp. 613 - 622
Copyright
Copyright © Cambridge University Press 1985

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

REFERENCES

Allden, W. G. (1979). Feed intake, diet composition and wool growth. In Physiological and Environmental Limitations to Wool Growth (ed. Black, J. L. and Beis, P. J.), pp. 6178. Armidale: University of New England Publishing Unit.Google Scholar
Barry, T. N. (1969). The effect of plane of nutrition and feeding formalin-treated casein on the production, fibre diameter and tensile strength of wool. Proceedings of the New Zealand Society of Animal Production 29, 218.Google Scholar
Black, J. L. & Reis, P. J. (1979). Speculation on the control of nutrient partition between wool growth and other body functions. In Physiological and Environmental Limitations to Wool Growth (ed. Black, J. L. and Reis, P. J.), pp. 269293. Armidale: University of New England Publishing Unit.Google Scholar
Black, J. L., Robabds, G. E. & Thomas, R. (1973). Effects of protein and energy intakes on the wool growth of merino wethers. Australian Journal of Agricultural Research 24, 399412.CrossRefGoogle Scholar
Brown, G. H., Turner, H. N., Young, S. S. Y. & Dolling, C. H. S. (1966). Vital statistics for an experimental flock of Merino sheep. III. Factors affecting wool and body characteristics, including the effect of age of ewe and its possible interaction with method of selection. Australian Journal of Agricultural Research 17, 557581.Google Scholar
Carter, H. B. & Clarke, W. H. (1957). The hair follicle group and skin follicle population of Australian Merino sheep. Australian Journal of Agricultural Research 8, 91108.Google Scholar
Corbett, J. L. (1968). Variation in the yield and composition of milk of grazing Merino ewes. Australian Journal of Agricultural Research 19, 283294.CrossRefGoogle Scholar
Corbett, J. L. (1979). Variation in wool growth with physiological state. In Physiological and Environmental Limitations to Wool Growth (ed. Black, J. L. and Reis, P. J.), pp. 7998. Armidale: University of New England Publishing Unit.Google Scholar
Corbett, J. L. & Furnival, E. P. (1976). Early weaning of grazing sheep. 2. Performance of ewes. Australian Journal of Experimental Agriculture and Animal Husbandry 16, 156166.CrossRefGoogle Scholar
Downes, A. M. (1973). A radioisotope method of measuring the mean fibre diameter of wool samples. Wool Technology and Sheep Breeding 20, 2934.Google Scholar
Faichnev, G. J. & Black, J. L. (1979). Factors affecting rumen function and the supply of nutrients. In Physiological and Environmental Limitations to Wool Growth (ed. Black, J. L. and Reis, P. J.), pp. 179192. Armidale: University of New England Publishing Unit.Google Scholar
Ferguson, K. A. (1959). Influence of dietary protein percentage on growth of wool. Nature 184, 907.Google Scholar
Ferguson, K. A. (1972). The nutritional value of diets for wool growth. Proceedings of the Australian Society of Animal Production 9, 314320.Google Scholar
Fowler, D. & Wilkins, J. (1982). The accuracy of ultrasonic imaging with real time scanners in determining litter number in pregnant ewes. Proceedings of the Australian Society of Animal Production 14, 636.Google Scholar
Gaitonde, M. K. (1967). A spectrophotometric method for the direct determination of cysteine in the presence of other naturally occurring amino acids. Biochemical Journal 104, 627633.CrossRefGoogle ScholarPubMed
Gilmour, A. R. (1983). REG, a generalized linear models programme. Miscellaneous Bulletin 1, Now South Wales Department of Agriculture, Sydney, Australia.Google Scholar
Graham, N. Mc. & Williams, A. J. (1962). The effects of pregnancy on the passage of food through the digestive tract of sheep. Australian Journal of Agricultural Research 13, 894900.Google Scholar
Henderson, A. E., Bryden, J. McG., Mazzitelli, F. E. & Milligan, K. E. (1970). Protein supplementation and wool growth. Proceedings of the New Zealand Society of Animal Production 30, 186201.Google Scholar
Langlands, J. P. & Sutherland, H. A. M. (1973). Sulphur as a nutrient for Merino sheep. I. Storage of sulphur in tissues and wool, and its secretion in milk. British Journal of Nutrition 30, 529535.Google Scholar
Leng, R. A. & Stephenson, S. K. (1965). Glucose and acetate metabolism by isolated sheep wool follicles. Archives of Biochemistry and Biophysics 110, 815.CrossRefGoogle ScholarPubMed
Lyne, A. G. (1964). Effect of adverse nutrition on the skin and wool follicles in Merino sheep. Australian Journal of Agricultural Science 15, 788801.CrossRefGoogle Scholar
Malloy, M. H., Rassin, D. K. & Gaull, G. E. (1981). A method for measurement of free and bound plasma cyst(e)ine. Analytical Biochemistry 113, 407415.CrossRefGoogle ScholarPubMed
Marston, H. R. & Robertson, T. B. (1928). The Utilization of Sulphur by Animals. Commonwealth Scientific and Industrial Research Organization Bulletin Number 39.Google Scholar
Mottershead, B. E. (1971). Estimation of sulphur in biological materials using the technicon autoanalyser. Laboratory Practice 20, 483491.Google ScholarPubMed
Oddy, V. H. & Annison, E. F. (1979). Possible mechanisms by which physiological state influences the rate of wool growth. In Physiological and Environmental Limitations to Wool Growth (ed. Black, J. L. and Reis, P. J.), pp. 295309. Armidale: University of New England Publishing Unit.Google Scholar
Oddy, V. H., Gooden, J. M. & Annison, E. F. (1984). Partitioning of nutrients in Merino ewes. I. Contribution of skeletal muscle, the pregnant uterus and the lactating mammary gland to total energy expenditure. Australian Journal of Biological Sciences 37, 375388.CrossRefGoogle Scholar
Oddy, V. H., Gooden, J. M., Hough, G. M., Teleni, E. & Annison, E. F. (1985). Partitioning of nutrients in Merino ewes. II. Glucose utilisation by skeletal muscle, the pregnant uterus and the lactating mammary gland in relation to whole body glucose utilisation. Australian Journal of Biological Sciences 38, 95108.Google Scholar
Oddy, V. H., Robards, G. E. & Low, S. G. (1983). Prediction of in-vivo dry matter digestibility from the fibre and nitrogen content of a feed. In Feed Information and Animal Production (ed. Robards, G. E. and Packham, R. G.), pp. 395398. Farnham Royal: Commonwealth Agricultural Bureaux.Google Scholar
Pethick, D. W. & Lindsay, D. B. (1982). Acetate metabolism in lactating sheep. British Journal of Nutrition 48, 319328.Google Scholar
Reis, P. J. (1979). Effects of amino acids on growth and properties of wool. In Physiological and Environmental Limitations to Wool Growth (ed. Black, J. L. and Reis, P. J.), pp. 223242. Armidale: University of New England Publishing Unit.Google Scholar
Slen, S. B. & Whiting, F. (1956). Wool growth in mature range ewes as affected by stage and type of pregnancy and type of rearing. Canadian Journal of Agricultural Science 36, 813.Google Scholar
Thorburn, G. D., Bassett, J. M. & Smith, I. D. (1969). Progesterone concentration in the peripheral plasma of sheep during an oestrus cycle. Journal of Endocrinology 45, 459469.CrossRefGoogle Scholar
Turner, H. N., Brown, G. H. & Ford, G. H. (1968). The influence of age structure on total productivity in breeding flocks of Merino sheep. I. Flocks with a fixed number of breeding ewes, producing their own replacements. Australian Journal of Agricultural Research 19, 443475.CrossRefGoogle Scholar
Turner, H. N. & Young, S. S. Y. (1969). Quantitative Genetics in Sheep Breeding, p. 215. Australia: Macmillan.Google Scholar
Vernon, R. G., Clegg, R. A. & Flint, D. J. (1981). Metabolism of sheep adipose tissue during pregnancy and lactation. Adaptation and regulation. Biochemical Journal 200, 307314.CrossRefGoogle ScholarPubMed
Weston, R. H. (1979). Digestion during pregnancy and lactation in sheep. Annales de Recherches Vétérinaires 10, 442444.Google Scholar
Williams, A. J. (1979). Speculations on the biological mechanisms responsible for genetic variation in the rate of wool growth. In Physiological and Environmental Limitations to Wool Growth (ed. Black, J. L. and Reis, P. J.), pp. 337354. Armidale: University of New England Publishing Unit.Google Scholar
Williams, A. J., Tyrrell, R. N. & Gilmour, A. R. (1978). Effects on wool production during pregnancy and lactation of twice daily abomasal supplementation with casein or methionine and cystine. Australian Journal of Experimental Agriculture and Animal Husbandry 18, 5257.CrossRefGoogle Scholar