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Non-genetic sources of variation of milk production and reproduction and interactions between both classes of traits in Sicilo-Sarde dairy sheep

Published online by Cambridge University Press:  09 June 2014

A. Meraï
Affiliation:
Animal Science Unit, National Agronomic Institute of Tunisia, University of Carthage, Tunis, Tunisia
N. Gengler
Affiliation:
Animal Science Unit, Gembloux Agro-Bio Tech, University of Liège, Gembloux, Belgium
H. Hammami
Affiliation:
Animal Science Unit, Gembloux Agro-Bio Tech, University of Liège, Gembloux, Belgium National Fund for Scientific Research (F.R.S.-FNRS), Brussels, Belgium
M. Rekik
Affiliation:
International Centre for Agricultural Research in the Dry Areas (ICARDA), P.O. Box, 950764 Amman 11195, Jordan
C. Bastin*
Affiliation:
Animal Science Unit, Gembloux Agro-Bio Tech, University of Liège, Gembloux, Belgium
*
E-mail: [email protected]
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Abstract

This work aimed to study the sources of variation in productive and reproductive traits of the dairy Sicilo-Sarde ewes and to further investigate the interaction between both classes of traits. After edits, a database containing 5935 lactation records collected during 6 successive years in eight dairy flocks in the North of Tunisia was used. Total milked milk (TMM) in the milking-only period was retained as productive trait. The interval from the start of the mating period to the subsequent lambing (IML) and the lambing status (LS) were designed as reproductive traits. Sicilo-Sarde ewes had an average TMM of 60.93 l (±44.12) during 132.8 days (±46.6) after a suckling period of 100.4 days (±24.9). Average IML was 165.7 days. In a first step, the major factors influencing milk production and reproductive traits were determined. The significant sources of variation identified for TMM were: flock, month of lambing, year of lambing, parity, suckling length, litter size and milking-only length. Flock×month of the start of the mating period, parity, year of mating and litter size were identified as significant factors of variation for IML, while flock×month of the start of the mating period, parity and year of mating were identified as significant sources of variation for LS. In a second step, variance components were estimated using a three traits threshold mixed model, which combined LS as categorical trait and TMM and IML as continuous traits. Repeatability estimates were 0.21 (±0.03) for TMM, 0.09 (±0.02) for IML, and 0.10 (±0.05) for LS. Moreover, TMM and IML were found to be favorably associated for the flock× year of lambing effect (−0.45±0.18) but unfavorably associated for the animal effect (0.20±0.09).

Type
Research Article
Copyright
© The Animal Consortium 2014 

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References

Anel, L, Alvarez, M, Martinez-Pastor, F, Garcia-Macias, V and Anel, E 2006. Improvement strategies in ovine artificial insemination. Reproduction in Domestic Animals 41, 3042.Google Scholar
Anel, L, Kaabi, M, Abroug, B, Alvarez, M, Anel, E, Boixo, JC, de la Fuente, LF and de Paz, P 2005. Factors influencing the success of vaginal and laparoscopic artificial insemination in churra ewes: a field assay. Theriogenology 63, 12351247.Google Scholar
Atti, N 2011. Système optimum de conduite des ovins: cas des conditions alimentaires améliorées du sud de la Méditerranée. Options Méditerranéennes 97, 5160.Google Scholar
Atti, N, Thériez, M and Abdennebi, L 2001. Relationship between body condition at mating and reproductive performance in the fat-tailed Barbarine breed. Animal Research 50, 135144.Google Scholar
Barillet, F 2007. Genetic improvement for dairy production in sheep and goats. Small Ruminant Research 70, 6075.CrossRefGoogle Scholar
Carta, A, Casu, S and Salaris, S 2009. Invited review: current state of genetic improvement in dairy sheep. Journal of Dairy Science 92, 58145833.Google Scholar
David, I, Robert-Granié, E, Manfredi, G, Lagriffoul, E and Bodin, L 2008. Environmental and genetic variation factors of artificial insemination success in French Dairy Sheep. Animal 2, 979986.Google Scholar
Djemali, M and Kayouli, C 2000. L’élevage laitier en Tunisie. Proceedings of the joint EAAP-CIHEAM-FAO symposium on prospects for a sustainable dairy sector in the Mediterranean, 26 to 28 October 2000, Hammamet, Tunisia, pp. 96–105.Google Scholar
Djemali, M, Ben M’Sallem, I and Bourawi, R 1995. Effet du mois, mode et âge d’agnelage sur la production laitière des brebis Sicilo-Sarde en Tunisie. Cahiers Options Méditerranéennes 6, 111117.Google Scholar
Djemali, M, Bedhiaf-Romdhani, S, Iniguez, L and Inounou, I 2009. Saving threatened native breeds by autonomous production, involvement of farmers’ organization, research and policy makers: the case of the Sicilo-Sarde breed in Tunisia, North Africa. Livestock Science 120, 213217.Google Scholar
Eyal, E, Lawi, A, Folman, Y and Morag, M 1978. Lamb and milk production of a flock of dairy ewes under an accelerated breeding regime. The Journal of Agricultural Science 91, 6979.Google Scholar
Grimmard, B, Freret, S, Chevallier, A, Pinto, A and Ponsart, C 2006. Genetic and environmental factors influencing first service conception rate and late embryonic/foetal mortality in low fertility dairy herds. Animal Reproduction Science 91, 3144.Google Scholar
Kassem, R, Owen, JB and Fedel, I 1989. Rebreeding activity in milking Awassi under semi-arid conditions. Animal Production 49, 8993.Google Scholar
Khaldi, G and Farid, M 1981. Encyclopédie des productions animales dans le monde arabe. Cas de la République Tunisienne. Arab Center for the Studies of Arid zones and Dry lands (ACSAD), Damascus, Syria.Google Scholar
Lassoued, N, Rekik, M, Khenissi, S and Merai, A 2014. Seasonality of oestrus, ovulation and ovulation rate of Sicilo-Sarde sheep. Journal of Animal Physiology and Animal Nutrition, published online 12 September 2013, doi:10.1111/jpn.12123.Google Scholar
Macciotta, NPP, Cappio-Borlino, A and Pulina, G 1999. Analysis of environmental effects on test day milk yields on Sarda dairy ewes. Journal of Dairy Science 82, 22122217.Google Scholar
Misztal, I, Tsuruta, S, Strabel, T, Auvray, B, Druet, T and Lee, DH 2002. BLUPF90 and related programs (BGF90). Proceedings of 7th World Congress on Genetics Applied to Livestock Production, 19 to 23 August, Montpellier, France, pp. 743–744.Google Scholar
Moujahed, N, Jounaidi, A, Kayouli, C and Damergi, C 2009. Effects of management system on performances of the Sicilo-Sarde ewes farmed in Northern Tunisia. Options Méditerranéennes 85, 393397.Google Scholar
Nettleton, PF, Gilray, JA, Russo, P and Dlissi, E 1998. Border disease of sheep and goats. Veterinary Research 29, 327340.Google Scholar
Office de l’Elevage et des Pâturages (OEP) 2012. Données sectorielles 2011-effectifs du cheptel. Retrieved December 10, 2012, from http/www.oep.nat.tnGoogle Scholar
Osinowo, OA, Abubakar, BY and Trimnel, AR 1993. Genetic and phenotypic relationships between gestation length, litter size and litter birth weight in Yankasa sheep. Animal Reproduction Science 34, 111118.Google Scholar
Pollot, GE and Gootwine, E 2000. Factors affecting milk production in improved Awassi dairy ewes. Animal Science 71 (3), 607616.Google Scholar
Pollot, GE and Gootwine, E 2004. Reproductive performance and milk production of Assaf sheep in an intensive management system. Journal of Dairy Science 87, 36903703.Google Scholar
Rekik, M, Aloulou, R and Ben Hammouda, M 2005. Small Ruminant Breeds of Tunisia. In Characterization of small ruminant breeds in West Asia and North Africa, 2: North Africa (ed. L Iňiguez), pp. 91140. International Center for Agricultural Research in the Dry Areas (ICARDA), Aleppo, Syria.Google Scholar
Rouissi, H, Rekik, B, Selmi, H, Hammami, M and Ben Gara, A 2008. Performances laitières de la brebis Sicilo-Sarde Tunisienne complémentée par un concentré local. Livestock Research for Rural Development 20, 102108.Google Scholar
Rouissi, H, Ben Souissi, N, Dridi, S, Chaieb, K, Tlili, S and Ridene, J 2001. Performances zootechniques de la race ovine Sicilo-Sarde. Options Méditerranéennes 46, 231236.Google Scholar
Saadoun, L, Romdhani, SB, Darej, C and Djemali, M 2004. The Sicilo Sarde dairy sheep in Tunisia: threats and strength. Proceedings of the 34th Biennial Session of the International Committee for Animal Recording, 28 May to 3 June 2004, Sousse, Tunisia, pp. 109–114.Google Scholar