Hostname: page-component-586b7cd67f-rcrh6 Total loading time: 0 Render date: 2024-11-30T23:25:58.453Z Has data issue: false hasContentIssue false

Changes in skin and fleece characteristics of Scottish cashmere goats following selection for increased annual production and decreased fibre diameter

Published online by Cambridge University Press:  18 August 2016

Get access

Abstract

The aim of this experiment was to determine the mechanisms involved in changes in the production of cashmere as a consequence of genetic selection. Skin follicle parameters and pattern of cashmere growth were compared in two selected lines of Scottish cashmere goats and a randomly bred control line. One line, the fine line, had been selected for low fibre diameter, and this had resulted in lower fibre diameter, but the weight of cashmere produced had also been reduced. Selection for fibre quantity and quality to give maximum financial return (the value line) had increased cashmere weight without a significant increase in cashmere diameter.

Skin follicle density and the ratio of secondary to primary follicles (S/P ratio) were measured at 5 months of age in 25 female kids from each line. The density of follicles in the value line was greater (P · 0.05) than that in the fine or control lines (means were 21·8, 19·8 and 20·1 follicles per mm2 respectively, s.e.d. 0.73). S/P ratio increased (P · 0.001) from control to fine to value lines (means were 6.5, 7.7 and 8.4 respectively, s.e.d. = 0.30).

The rate of cashmere growth (length), peak cashmere length, the duration of the cashmere growing period and dates of initiation and cessation of growth were measured in the same 25 goats from each line between 2 and 3 years of age. These traits were estimated from the regression of measurements of staple length taken at approximately 6-weekly intervals from the start of the growing period until peak staple length was reached. Measurements were made on the shoulder, mid side and hip. There was no difference in cashmere growth rate between the selection lines (average 0·29 (s.e. 0.006) mm/day). Cashmere growth started earliest in the value line and latest in the fine line but the date of cessation of growth was not different. This affected the duration of the growing period which was 183, 163 and 214 days (s.e.d. 9.6, P · 0.001) for the control, fine and value lines respectively. Peak staple length of cashmere was longest in the value line.

Increased weight of cashmere in the value line was brought about through an increase in the number of secondary follicles and by an increase in the length of cashmere due to an increase in the duration of the growing period.

Type
Ruminant nutrition, behaviour and production
Copyright
Copyright © British Society of Animal Science 2003

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

Bishop, S. C. and Russel, A. J. F. 1994. Cashmere production from feral and imported cashmere goat kids. Animal Production 58: 135144.Google Scholar
Bishop, S. C. and Russel, A. J. F. 1996. The inheritance of fibre traits in a crossbred population of cashmere goats. Animal Science 63: 429436.CrossRefGoogle Scholar
Bishop, S. C. and Russel, A. J. F. 1998. Cashmere goat breeding in Scotland. In European fine fibre network report no. 2 (ed. Souchet, C.) pp. 49.Google Scholar
Henderson, M. and Sabine, J. R. 1991. Secondary follicle development in Australian cashmere goats. Small Ruminant Research 4: 349363.CrossRefGoogle Scholar
International Wool Textile Organisation. 1995. Specification IWTO-47-95. International Wool Secretariat, Ilkley, UK.Google Scholar
Jonen, Von M., Meyer, W., Schwarz, R. and Davies, A. S. 1994. [Comparative investigations into the structure of hair-follicle groups in New Zealand cashmere Angora and cashgora goats.] Journal of Animal Breeding and Genetics 111: 391403.CrossRefGoogle Scholar
Klören, W. R. L. and Norton, B. W. 1993. Fleece growth in Australian cashmere goats. 2. The effect of pregnancy and lactation. Australian Journal of Agricultural Research 44: 10231034.CrossRefGoogle Scholar
Lambert, A., Restall, B. J., Norton, B. W. and Winter, J. D. 1984. The post natal development of hair follicle groups in the skin of the Australian feral goat. Animal Production in Australia 15: 420423.Google Scholar
Lawes Agricultural Trust. 2000. Genstat 4·2, fifth edition. Rothamsted Experimental Station, Harpenden.Google Scholar
McCloghry, C. E. 1997. Histological technique for the determination of wool follicle density. Wool Technology and Sheep Breeding 45: 129145.Google Scholar
Maddocks, I. G. and Jackson, N. 1988. Structural studies of sheep, cattle and goat skin. CSIRO Division of Animal Production, NSW, Australia.Google Scholar
Merchant, M. and Riach, D. J. 1996. Changes in the coat of cashmere goat kids of two different genotypes from birth to 13 months of age. Animal Science 62: 317323.CrossRefGoogle Scholar
Merchant, M. and Riach, D. J. 1999. Changes in fibre traits in Scottish Cashmere and Siberian goat kids and their relationships with annual production and diameter of the undercoat. Animal Science 68: 577587.CrossRefGoogle Scholar
Mitchell, R. J., Betteridge, K., Gurnsey, M. P., Welch, R. A. S. and Nixon, A. J. 1991. Fibre growth cycles of cashmere-bearing, reproducing does in Southern Hawkes Bay, New Zealand, over a 30 month period. New Zealand Journal of Agricultural Research 34: 287294.CrossRefGoogle Scholar
Norton, B. W. and Klören, W. R. L. 1995. Measurement of the components of the cashmere growth cycle in Australian cashmere goats. Small Ruminant Research 17: 263268.CrossRefGoogle Scholar
Pattie, W., Restall, B. J. and Smith, G. A. 1989. The inheritance of cashmere in Australian goats. 2. Genetic parameters and breeding values. Livestock Production Science 21: 251261.CrossRefGoogle Scholar
Restall, B. J. and Pattie, W. A. 1989. The inheritance of cashmere in Australian goats. 1. Characteristics of the base population and the effects of environmental factors. Livestock Production Science 21: 157172.CrossRefGoogle Scholar
Rhind, S. M. and McMillen, S. R. 1995. Seasonal patterns of secondary fibre growth and moulting and hair follicle activity in Siberian and Icelandic ✕ Scottish feral goats offered high and low levels of dietary protein. Small Ruminant Research 16: 6976.CrossRefGoogle Scholar
Ryder, M. L. 1970. Structure and seasonal change of the coat in Scottish wild goats. Journal of Zoology, London 161: 355361.CrossRefGoogle Scholar
Sumner, R. M. W. and Bigham, M. L. 1993. Biology of fibre growth and possible genetic and non-genetic means of influencing fibre growth in sheep and goats – a review. Livestock Production Science 33: 129.CrossRefGoogle Scholar
Wildman, A. B. 1954. The microscopy of animal textile fibres. Wool Industries Research Association, Leeds.Google Scholar
Yunnian, Q., Wei, W., Wenbo, G., Guangzhao, M., Feng Jing, G., Jinghuan, C. and Jinghuan, C. 1996. Comparisons of fleece characteristics between Liaoning and Duo cashmere goats. Proceedings of the V1th international conference on goats, Beijing, China, 1996, volume 2, p. 869. International Academic Publishers, China.Google Scholar