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RESEARCH ARTICLE

Protein synthesis rates in skin components and skeletal muscle of sheep selected for divergent clean fleece weight in response to below- and above-maintenance nutrition

L. Li A C D , S. M. Liu B , V. H. Oddy A and J. V. Nolan A C
+ Author Affiliations
- Author Affiliations

A School of Rural Science and Agriculture, University of New England, Armidale, NSW 2351, Australia.

B CSIRO Livestock Industries, Private Bag 5, PO Wembley, WA 6913, Australia.

C The Australian Sheep Industry CRC, Chiswick, New England Highway, Locked Bag 1, Armidale, NSW 2350, Australia.

D Corresponding author. Email: lli@une.edu.au

Australian Journal of Agricultural Research 58(11) 1031-1039 https://doi.org/10.1071/AR06373
Submitted: 27 November 2006  Accepted: 2 July 2007   Published: 26 November 2007

Abstract

Protein metabolism in skin and muscle was studied in Merino wethers selected for high (F+, n = 10) or low (F–, n = 10) estimated breeding values for clean fleece weight, but with similar estimated breeding values for liveweight and fibre diameter, raised to 20 months of age under the same conditions, and then offered two levels of nutrition (0.8 or 1.8 × maintenance) for 37 days.

Over 37 days, F+ sheep had greater rate of wool production, liveweight gain, and had greater eye-muscle and fat depth than F– sheep (P < 0.05).

Fractional synthesis rates of protein (%/day) in the epidermis, dermis, whole skin and muscle were affected by both feeding level (P < 0.05) and genotype (P < 0.05). The fractional synthesis rates of protein were greater (P < 0.05) in F+ sheep at both levels of intake. There was an interaction (P < 0.01) between genotype and feeding level for the protein fractional synthesis rate in muscle, where F+ sheep were more responsive to higher feed intake. Muscle of F– sheep responded to increased amino acid supply by reducing the rate of protein degradation without altering synthesis rate; whereas muscle of F+ sheep responded by increasing the rates of both protein synthesis and degradation. The overall muscle fractional synthesis rate (1.6%/day) was ~7-times lower than the skin fractional synthesis rate (10.8%/day) in these animals (P < 0.01).

F+ sheep had a higher rate of protein synthesis in dermis and whole skin to support their higher wool protein accretion at both levels of feed intake. Muscle protein synthesis rate was greater in F+ sheep offered above-maintenance metabolisable energy (ME) intake than those given below-maintenance ME intake but was unaffected by ME intake in F– sheep. The results indicate that selection for wool growth not only affects production of wool and the wool follicle, but also affects the rate of protein turnover in components of the skin and skeletal muscle.


Acknowledgments

Financial support for this project was provided by the Australian Sheep Industry CRC. We also thank Mr Simon Stachiw, Mrs Jenny Hegarty, Mr David Creed and Dr Ian Godwin for technical assistance.


References


Adams NR, Briegel JR, Greeff JC, Bermingham EN (2006) Feed intake, body composition, and plasma metabolic hormones in Merino sheep that differ genetically in fleece weight or fibre diameter. Australian Journal of Agricultural Research 57, 27–32.
Crossref | GoogleScholarGoogle Scholar | [Verified 4 November 2007].

Hynd PI , Masters DG (2002) Nutrition and wool growth. In ‘Sheep nutrition’. (Eds M Freer, H Dove) pp. 165–187. (CABI Publishing/CSIRO Publishing: Melbourne, Vic.)

IAEA (1997) ‘Estimation of rumen microbial protein production from purine derivatives in urine. A laboratory manual for the FAO/IAEA co-ordinated research programme on development, standardization and validation of nuclear based technologies for measuring microbial protein supply in ruminant livestock for improving productivity.’ (IAEA: Vienna, Austria) Available at: www.iaea.org/programmes/nafa/d3/public/tecdoc-945.pdf

Kahn LP (1996) Differences between Merino selection lines in microbial yield from the rumen and utilisation of protein for wool growth. PhD thesis, University of New England, Australia.

Li L, Godwin I, Oddy VH, Nolan JV (2006) Skin characteristics and skin protein composition of Merinos differing in estimated breeding values for wool growth and fed at above and below maintenance. Australian Journal of Experimental Agriculture 46, 937–941.
Crossref | GoogleScholarGoogle Scholar | open url image1

Liu SM, Mata G, O’Donoghue H, Masters DG (1998) The influence of live weight, live-weight change and diet on protein synthesis in the skin and skeletal muscle in young Merino sheep. The British Journal of Nutrition 79, 267–274.
Crossref | GoogleScholarGoogle Scholar | PubMed | open url image1

Lobley GE, Harris PM, Skene PA, Brown D, Milne E, Calder AG, Anderson SE, Garlick PJ, Nevison I, Connell A (1992) Responses in tissue protein synthesis to sub- and supra-maintenance intake in young growing sheep: comparison of large-dose and continuous-infusion techniques. The British Journal of Nutrition 68, 373–388.
Crossref | GoogleScholarGoogle Scholar | PubMed | open url image1

Lush JM, Gooden JM, Annison EF (1991) The uptake of nitrogenous compounds from the gut of sheep genetically different in wool production. Proceedings of the Nutrition Society of Australia 16, 144. open url image1

MacRae JC, Walker A, Brown D, Lobley GE (1993) Accretion of total protein and individual amino acids by organs and tissues of growing lambs and the ability of nitrogen balance techniques to quantitate protein retention. Animal Production 57, 237–245. open url image1

Masters DG, Mata G, Liu SM (1999) The influence of type and timing of protein supplementation on wool growth and protein synthesis in the skin of young Merino sheep. Australian Journal of Agricultural Research 50, 497–502.
Crossref | GoogleScholarGoogle Scholar | open url image1

McCloghry CE (1997) Alternative dye banding method for measuring the length growth rate of wool in sheep. New Zealand Journal of Agricultural Research 40, 569–571. open url image1

MGS (2004) Merino Genetics Service: A guide to using EBVs. Available at: www.sheepgenetics.org.au/merinoselect/

Nancarrow MJ , Nagorcka BN , Purvis IW (1998) Skin and follicle attributes contribute to differences in clean fleece weight in superfine Merino sheep. In ‘Animal production in Australia’. pp. 253–256. (Australian Society of Animal Production: Armidale, NSW)

Oddy VH (1993) Regulation of muscle protein metabolism in sheep and lambs: nutritional, endocrine and genetic aspects. Australian Journal of Agricultural Research 44, 901–913.
Crossref | GoogleScholarGoogle Scholar | open url image1

Oddy VH, Speck PA, Warren HM, Wynn PC (1995) Protein metabolism in lambs from lines divergently selected for weaning weight. Journal of Agricultural Science, Cambridge 124, 129–137. open url image1

Pell JM, Bates PC (1987) Collagen and non-collagen protein turnover in skeletal muscle of growth hormone-treated lambs. The Journal of Endocrinology 115, R1–R4.
PubMed |
open url image1

SheepExplorer (2003) The excel spreadsheet SheepExplorer. In ‘GrazPlan’. (CSIRO Plant Industry, Canberra) Available at: www.pi.csiro.au/grazplan/

Slater C, Preston T, McMillan DC, Falconer JS, Fearon KCH (1995) GC/MS analysis of [2H5]phenylalanine at very low enrichment: measurement of protein synthesis in health and disease. Journal of Mass Spectrometry 30, 1325–1332.
Crossref | GoogleScholarGoogle Scholar | open url image1

van der Werf JHJ (2006) Optimal development of Australian sheep genetic resources. Wool meets meat-tools for a modern sheep enterprise. In ‘Proceedings of the 2006 Australian Sheep Industry CRC Conference’. Orange, NSW. (Eds PB Cronjé, D Maxwell) pp. 30–35. (The Australian Sheep Industry CRC: Armidale, NSW)

Williams AJ (1978) Speculation on the biological mechanisms responsible for genetic variation in the rate of wool growth. In ‘Physiological and environmental limitations to wool growth. Proceedings of a National Workshop’. Leura, NSW. (Eds JL Black, PJ Reis) pp. 337–354. (The University of New England: Armidale, NSW)

Williams AJ (1987) Physiological consequences of selection for increased fleece weight. In ‘Merino improvement programs in Australia’. (Ed. BJ McGuirk) pp. 481–494. (Australian Wool Corporation: Melbourne)

Williams AJ, Winston RJ (1987) A study of the characteristic of wool follicle and fibre in Merino sheep genetically different in wool production. Australian Journal of Agricultural Research 38, 743–755.
Crossref | GoogleScholarGoogle Scholar | open url image1