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RESEARCH ARTICLE

Use of part records in Merino breeding programs — the inheritance of wool growth and fibre traits during different times of the year to determine their value in Merino breeding programs

J. C. Greeff A C , B. Paganoni A and R. P. Lewer B
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- Author Affiliations

A Department of Agriculture Western Australia, 10 Dore Street, Katanning, WA 6317, Australia.

B Queensland Department of Primary Industries, Locked Bag 4, Moorooka, Qld 4105, Australia.

C Corresponding author. Email: JGreeff@agric.wa.gov.au

Australian Journal of Experimental Agriculture 45(4) 347-356 https://doi.org/10.1071/EA03122
Submitted: 16 June 2003  Accepted: 10 May 2004   Published: 23 May 2005

Abstract

Fibre diameter can vary dramatically along a wool staple, especially in the Mediterranean environment of southern Australia with its dry summers and abundance of green feed in spring. Other research results have shown a very low phenotypic correlation between fibre diameter grown between seasons. Many breeders use short staples to measure fibre diameter for breeding purposes and also to promote animals for sale. The effectiveness of this practice is determined by the relative response to selection by measuring fibre traits on a full 12 months wool staple as compared to measuring them only on part of a staple. If a high genetic correlation exists between the part record and the full record, then using part records may be acceptable to identify genetically superior animals. No information is available on the effectiveness of part records. This paper investigated whether wool growth and fibre diameter traits of Merino wool grown at different times of the year in a Mediterranean environment, are genetically the same trait, respectively. The work was carried out on about 7 dyebanded wool sections/animal.year, on ewes from weaning to hogget age, in the Katanning Merino resource flocks over 6 years.

Relative clean wool growth of the different sections had very low heritability estimates of less than 0.10, and they were phenotypically and genetically poorly correlated with 6 or 12 months wool growth. This indicates that part record measurement of clean wool growth of these sections will be ineffective as indirect selection criteria to improve wool growth genetically. Staple length growth as measured by the length between dyebands, would be more effective with heritability estimates of between 0.20 and 0.30. However, these measurements were shown to have a low genetic correlation with wool grown for 12 months which implies that these staple length measurements would only be half as efficient as the wool weight for 6 or 12 months to improve total clean wool weight. Heritability estimates of fibre diameter, coefficient of variation of fibre diameter and fibre curvature were relatively high and were genetically and phenotypically highly correlated across sections. High positive phenotypic and genetic correlations were also found between fibre diameter, coefficient of variation of fibre diameter and fibre curvature of the different sections and similar measurements for wool grown over 6 or 12 months. Coefficient of variation of fibre diameter of the sections also had a moderate negative phenotypic and genetic correlation with staple strength of wool staples grown over 6 months indicating that coefficient of variation of fibre diameter of any section would be as good an indirect selection criterion to improve stable strength as coefficient of variation of fibre diameter for wool grown over 6 or 12 months. The results indicate that fibre diameter, coefficient of variation of fibre diameter and fibre curvature of wool grown over short periods of time have virtually the same heritability as that of wool grown over 12 months, and that the genetic correlation between fibre diameter, coefficient of variation of fibre diameter and fibre curvature on part and on full records is very high (rg >0.85). This indicates that fibre diameter, coefficient of variation of fibre diameter and fibre curvature on part records can be used as selection criteria to improve these traits. However, part records of greasy and clean wool growth would be much less efficient than fleece weight for wool grown over 6 or 12 months because of the low heritability of part records and the low genetic correlation between these traits on part records and on wool grown for 12 months.


Acknowledgments

This project was partly funded by Australian Wool Innovation (Ltd) and is gratefully acknowledged. Vince Lambert and Jenny Taylor are particularly thanked for dyebanding, recording and measuring the animals.


References


Adams NR, Greeff JC, Kelly RW, Peter DW (1996) Repeatability of the rate of wool growth across seasons in a Mediterranean environment. Proceedings of the Australian Society of Animal Production 21, 127–130. open url image1

Briegel JR, Adams NR, O’Dea T (1998) Relationship between staple length growth and wool growth in three Merino strains in a Mediterranean environment. Proceedings of Animal Production in Australia 2, 424. open url image1

Brims M (1997) Along fibre diameter and cleanliness measurement using OFDA. International Wool Textile Organisation Technical and Standing Committee, Meeting May 1997, Report No. 23, Boston.

Ellis M (1986) ‘Research techniques training course: dyebanding.’ (Sheep and Wool Branch, Department of Agriculture of Western Australia: Perth)

Greeff JC, Lewer RP, Ponzoni RW, Purvis I (1995) Staple strength: progress towards elucidating its place in Merino breeding. Proceedings of the Australian Association of Animal Breeding and Genetics 11, 595–599. open url image1

Gilmour AR, Cullis BR, Welham SJ, Thompson R (1999) ASREML reference manual. NSW Agriculture, Biometric Bulletin No. 3, Orange, NSW.

Hatcher S, Atkins KD (2000) Breeding objectives which include fleece weight and fibre diameter do not need fibre curvature. In ‘Proceedings of the 23rd biennial conference of the Australian society of animal production. Vol. A’. (Ed. GM Stone) p. 293. (University of New South Wales: Sydney, Australia)

IWTO (1996) International wool textile organisation, 1996, IWTO-52-96: Conditioning procedures for textile testing. Nice, France.

Lynch M, Walsh B (1998) ‘Genetics and analysis of quantitative traits.’ (Sinauer Associates Inc.: Sunderland, MA, USA)

Mortimer SI (1987) Australian estimates of genetic parameters for wool production and quality traits. In ‘Merino improvement programs in Australia. Proceedings of a national symposium’. (Ed. BJ McGuirk) pp. 159–173. (Australian Wool Corporation: Leura)

Schlink AC, Mata G, Lea JM, Ritchie AJM (1999) Seasonal variation in fibre diameter and length in wool of grazing Merino sheep with low or high staple strength. Australian Journal of Experimental Agriculture 39, 507–517.
Crossref | GoogleScholarGoogle Scholar | open url image1

Turner HN, Young SSY (1969) ‘Quantitative genetics in sheep breeding.’ (MacMillan: Melbourne, Vic.)

Wheeler JL, Hedges DA, Mulcahy C (1977) The use of dyebanding for measuring wool production and fleece tip wear in rugged and unrugged sheep. Australian Journal of Agricultural Research 28, 721–735.
Crossref | GoogleScholarGoogle Scholar | open url image1