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RESEARCH ARTICLE

Productive and reproductive consequences of crossbreeding Dohne Merino with Corriedale in Uruguayan sheep production systems

I. De Barbieri https://orcid.org/0000-0003-0799-424X A * , C. Viñoles B , F. Montossi A , S. Luzardo A and G. Ciappesoni C
+ Author Affiliations
- Author Affiliations

A Instituto Nacional de Investigación Agropecuaria (INIA Tacuarembó), Ruta 5 km 386, 45000 Tacuarembó, Uruguay.

B Polo Agroforestal, Estación Experimental Bernardo Rosengurtt, Universidad de la República, Ruta 26 km 408, 37000 Cerro Largo, Uruguay.

C Instituto Nacional de Investigación Agropecuaria (INIA Las Brujas), Ruta 48 km 10, 90100 Canelones, Uruguay.

* Correspondence to: idebarbieri@inia.org.uy

Handling Editor: Suzanne Mortimer

Animal Production Science 62(1) 29-39 https://doi.org/10.1071/AN20490
Submitted: 27 August 2020  Accepted: 26 July 2021   Published: 4 November 2021

© 2022 The Author(s) (or their employer(s)). Published by CSIRO Publishing

Abstract

Context: For extensive production systems, crossbreeding may be a tool that can be used to achieve production of quality wool and meat to suit market specifications.

Aims: To evaluate two levels of crossbreeding of Dohne Merino (DM) sires with Corriedale (C) ewes on productive and reproductive traits of the crossbreed progeny in comparison with purebred C progeny.

Methods: Two studies using three genotypes – 100% C (100C), 50% DM × 50% C (50DM) and 75% DM × 25% C (75DM) – were carried out. In Study 1, growth, wool production and nematode resistance were evaluated (n = 1652). In wethers, carcass weight, subcutaneous tissue thickness, weight of high value cuts, meat shear force and fresh meat colour were also evaluated. Before first mating, the presence and number of corpus luteum was recorded to evaluate puberty and ovulation rate, respectively, in 380 18-month-old hoggets. In Study 2, fertility, prolificacy and lambing percentages were measured in 382 ewes.

Key results: Increasing the percentage of DM was associated with heavier animals (P < 0.01). The heaviest fleece weight, broadest fibre diameter and longest staple length were recorded in 100C, and the lowest in 75DM (P < 0.001). Crossbred animals had heavier carcasses, boneless legs and French racks than 100C (P < 0.001). Subcutaneous tissue thickness GR adjusted for carcass weight was thicker in 100C, intermediate in 50DM and lowest in 75DM (P < 0.001). Meat quality and nematode resistance traits were not affected by crossbreeding. Genotype affected the proportion of hoggets cyclic at first mating (P < 0.05), being greater in 50DM than in C hoggets, although both proportions were similar to 75DM. Fertility was not affected (P > 0.05) by genotype, whereas prolificacy and lambing percentage were greater in the animals of the 50DM vs 100C and 75DM (P < 0.05).

Conclusions: Wool quality, animal growth, carcass weight and composition, and onset of puberty were improved by crossbreeding C ewes with DM sires. A reduction in wool production, and minor influences on prolificacy and lambing percentage were detected.

Implications: Crossbreeding C ewes with DM sires can benefit wool and meat production in comparison with purebred C production systems.

Keywords: Corriedale, crossbreeding parameters, Dohne Merino, fertility, fibre diameter, fleece weight, lamb meat, puberty.


References

American Meat Science Association (AMSA) (2016) ‘Research guidelines for cookery, sensory evaluation, and instrumental tenderness measurements of meat, version 1.02.’ 2nd edn. (AMSA: Champaign, IL, USA)

Australian Wool Testing Authority (AWTA) (2020) Micron profile data for the Australian wool clip. Available at https://www.awtawooltesting.com.au/index.php/en/statistics/volume-and-trends. [Verified 5 February 2021]

Barlow R (1981) Experimental evidence for interaction between heterosis and environment in animals. Animal Breeding Abstract 49, 715–737.

Bervejillo J, Bottaro M (2020) Situation and outlook of meat sheep. In ‘Anuario 2019 Opypa’. (Ed. MGAP) pp. 63–74. (MGAP: Montevideo, Uruguay)

Blache D, Chagas L, Martin G (2007) Nutritional inputs into the reproductive neuroendocrine control system – a multidimensional perspective. In ‘Reproduction in domestic ruminants VI’. (Eds J Juengel, J Murray, M Smith) pp. 123–139. (Nottingham University Press: Nottingham, UK)

Brash LD, Fogarty NM, Gilmour AR (1994) Genetic parameters for Australian maternal and dual-purpose meatsheep breeds. II. Liveweight, wool and reproduction in Corriedale sheep. Australian Journal of Agricultural Research 45, 469–480.
Genetic parameters for Australian maternal and dual-purpose meatsheep breeds. II. Liveweight, wool and reproduction in Corriedale sheep.Crossref | GoogleScholarGoogle Scholar |

Butler LG, Horton BJ, Williams PM, Banks RG (1993) Wool production and heterosis by the Merino, the Polwarth, and their reciprocal crosses. Australian Journal of Experimental Agriculture 33, 397–402.
Wool production and heterosis by the Merino, the Polwarth, and their reciprocal crosses.Crossref | GoogleScholarGoogle Scholar |

Cardellino R (2016) The Dohne in South America. In ‘Global Dohne Conference, Dubbo, New South Wales, Australia’. Available at https://dohne.com.au/wp-content/uploads/2016/08/THE-DOHNE-IN-SOUTH-AMERICA.pdf. [Verified 22 June 2021]

Casey AE, Wilson BCD (2016) The Dohne in Australia. In ‘Global Dohne conference, Dubbo, New South Wales, Australia’. Available at http://dohne.com.au/wp-content/uploads/2016/08/THE-DOHNE-IN-AUSTRALIA.pdf. [Verified 22 June 2021]

Ciappesoni G, Gimeno D, Coronel F (2014) Genetic progress in sheep evaluation in Uruguay. Archivos Latinoamericanos de Producción Animal 22, 73–80.

Cottle D (2010) World sheep and wool production. In ‘International sheep and wool handbook’. (Ed. D Cottle) pp. 1–48. (Nottingham University Press: Nottingham, UK)

Cloete SWP, Cloete JJE (2015) Production performance of Merino and Dohne Merino ewes and lambs in pure or crossbreeding systems. Proceedings of the Association for the Advancement of Animal Breeding and Genetics 21, 217–220.

Cloete SWP, Scholtz AJ, Aucamp BB (1998) Environmental effects, heritability estimates and genetic trends in a Western Cape Dohne Merino nucleus flock. South African Journal of Animal Science 28, 185–195.
Environmental effects, heritability estimates and genetic trends in a Western Cape Dohne Merino nucleus flock.Crossref | GoogleScholarGoogle Scholar |

Cloete SWP, Coetzee J, Schoeman SJ, Morris J, Ten Hoope JM (1999) Production parameters for Merino, Dohne Merino and South African Mutton Merino sheep. Proceedings of the Association for the Advancement of Animal Breeding and Genetics 13, 181–184.

Cloete SWP, Schoeman SJ, Coetzee J, Morris J de V (2001) Genetic variances for liveweight and fleece traits in Merino, Dohne Merino and South African Meat Merino sheep. Australian Journal of Experimental Agriculture 41, 145–153.
Genetic variances for liveweight and fleece traits in Merino, Dohne Merino and South African Meat Merino sheep.Crossref | GoogleScholarGoogle Scholar |

Cloete JJE, Hoffman LC, Cloete SWP (2012) A comparison between slaughter traits and meat quality of various sheep breeds: wool, dual-purpose and mutton. Meat Science 91, 318–324.
A comparison between slaughter traits and meat quality of various sheep breeds: wool, dual-purpose and mutton.Crossref | GoogleScholarGoogle Scholar |

de Graaf SP (2010) Reproduction. In ‘International sheep and wool handbook’. (Ed. D Cottle) pp. 189–222. (Nottingham University Press: Nottingham, UK)

Dickerson G (1969) Experimental approaches to utilizing breed resources. Animal Breeding Abstract 37, 191–202.

Edwards JW, Cannell RC, Garrett RP, Savell JW, Cross HR, Longnecker MT (1989) Using ultrasound, linear measurements and live fat thickness estimates to determine the carcass composition of market lambs. Journal of Animal Science 67, 3322
Using ultrasound, linear measurements and live fat thickness estimates to determine the carcass composition of market lambs.Crossref | GoogleScholarGoogle Scholar |

Fernández Abella D (2006) Comparison of ovarian activity in Dohne Merino × Corriedale and Corriedale sheep. Producción Ovina 18, 123–126.

Font i Furnols M, Realini C, Montossi F, Sañudo C, Campo MM, Oliver MA, Nute GR, Guerrero L (2011) Consumer’s purchasing intention for lamb meat affected by country of origin, feeding system and meat price: a conjoint study in Spain, France and United Kingdom. Food Quality and Preference 22, 443–451.
Consumer’s purchasing intention for lamb meat affected by country of origin, feeding system and meat price: a conjoint study in Spain, France and United Kingdom.Crossref | GoogleScholarGoogle Scholar |

Fourie A, Cloete SWP (1993) Reproductive performance of commercial Merino, Dohne Merino and SA Mutton Merino flocks in the Southern Cape. South African Journal of Animal Sciences 23, 104–110.

Greeff J, Kinghorn B, Brown D (2010) Breeding and selection. In ‘International sheep and wool handbook’. (Ed. D Cottle) pp. 165–188. (Nottingham University Press: Nottingham, UK)

Hoffman LC, Muller M, Cloete SWP, Schmidt D (2003) Comparison of six crossbred lamb types: sensory, physical and nutritional meat quality characteristics. Meat Science 65, 1265–1274.
Comparison of six crossbred lamb types: sensory, physical and nutritional meat quality characteristics.Crossref | GoogleScholarGoogle Scholar | 22063769PubMed |

Hohenboken W, Cochran PE (1976) Heterosis for ewe lamb productivity. Journal of Animal Science 42, 819–823.
Heterosis for ewe lamb productivity.Crossref | GoogleScholarGoogle Scholar |

Hopkins DL, Fogarty NM, Mortimer SI (2011) Genetic related effects on sheep meat quality. Small Ruminant Research 101, 160–172.
Genetic related effects on sheep meat quality.Crossref | GoogleScholarGoogle Scholar |

Iwan LG, Jeffries BC, Turner HN (1971) Estimation of heterosis in Merino × Corriedale crosses with sheep. Australian Journal of Agricultural Research 22, 521–535.
Estimation of heterosis in Merino × Corriedale crosses with sheep.Crossref | GoogleScholarGoogle Scholar |

International Wool Textile Organisation (IWTO) (2006) ‘IWTO-52: conditioning procedures for testing textiles.’ (IWTO: Brussels, Belgium)

International Wool Textile Organisation (IWTO) (2012) ‘IWTO-12: measurement of the mean and distribution of fibre diameter using the Sirolan-Laserscan fibre diameter analyser.’ (IWTO: Brussels, Belgium)

International Wool Textile Organisation (IWTO) (2014) ‘IWTO-56: method for the measurement of color of raw wool.’ (IWTO: Brussels, Belgium)

Jefferies B (1961) Body condition scoring and its use in management. Tasmanian Journal of Agriculture 32, 19–21.

Kenyon PR, Maloney SK, Blache D (2014) Review of sheep body condition score in relation to production characteristics. New Zealand Journal of Agricultural Research 57, 38–64.
Review of sheep body condition score in relation to production characteristics.Crossref | GoogleScholarGoogle Scholar |

Kirton AH, Johnson DL (1979) Interrelationships between GR and other lamb carcass fatness measurement. Proceedings of the New Zealand Society of Animal Production 39, 194–201.

Koch RM (1972) The role of maternal effects in animal breeding: VI. Maternal effects in beef cattle. Journal of Animal Science 35, 1316–1323.
The role of maternal effects in animal breeding: VI. Maternal effects in beef cattle.Crossref | GoogleScholarGoogle Scholar | 4567219PubMed |

Kotzé J (1951) The development of a mutton-woolled sheep for the sour-grassveld area. Farming in South Africa 28, 110–113.

Kremer R, Barbato G, Rista L, Rosés L, Perdigón F (2010) Reproduction rate, milk and wool production of Corriedale and East Friesian × Corriedale F1 ewes grazing on natural pastures. Small Ruminant Research 90, 27–33.
Reproduction rate, milk and wool production of Corriedale and East Friesian × Corriedale F1 ewes grazing on natural pastures.Crossref | GoogleScholarGoogle Scholar |

Li L, Brown DJ, Gill JS (2013) Genetic parameters for body weight, carcass and wool traits in Dohne Merino. Proceedings of the Association for the Advancement of Animal Breeding and Genetics 20, 241–244.

Marshall F (1905) Fertility in Scottish sheep. Proceedings of the Royal Society of London 77, 58–62.

Menchaca A, Pinczak A, González-Pensado S (2005) Ovulatory rate of Dohne sheep and its crosses in Uruguay. In ‘VI Simposio Internacional de Reproducción animal, Córdoba, Argentina’. p. 475. (Instituto de reproducción animal: Córdoba, Argentina)

Montossi F, De Barbieri I, Ciappesoni G, Ganzábal A, Banchero G, Luzardo S, San Julián R (2013a) Intensification, diversification, and specialization to improve the competitiveness of sheep production systems under pastoral conditions: Uruguay’s case. Animal Frontiers 3, 28–35.
Intensification, diversification, and specialization to improve the competitiveness of sheep production systems under pastoral conditions: Uruguay’s case.Crossref | GoogleScholarGoogle Scholar |

Montossi F, Font-i-Furnols M, del Campo M, San Julián R, Brito G, Sañudo C (2013b) Sustainable sheep production and consumer preference trends: compatibilities, contradictions, and unresolved dilemmas. Meat Science 95, 772–789.
Sustainable sheep production and consumer preference trends: compatibilities, contradictions, and unresolved dilemmas.Crossref | GoogleScholarGoogle Scholar | 23769133PubMed |

Mueller JP, Elvira MG, Sacchero DM (2013) Animal fibers in Argentina: production and research. In ‘6th Symposium on South American Camelids and 2nd European meeting on Fiber Animals. 64th EAAP Annual Meeting, 25–30 August, Nantes, France. Session 43’. (Ed. D Allain) p. 10. (Wageningen Academic Publishers: The Netherlands). http://www.eaap.org/Previous_Annual_Meetings/2013Nantes/Papers/Published/S43_12.pdf

Nolan E, Farrell T, Ryan M, Gibbon C, Ahmadi-Esfahani FZ (2014) Valuing quality attributes of Australian merino wool. Australian Journal of Agricultural and Resource Economics 58, 314–335.
Valuing quality attributes of Australian merino wool.Crossref | GoogleScholarGoogle Scholar |

Nolte JVE, Ferreira AV (2004) Energy and nitrogen retention of Merino and Dohne Merino lambs receiving a feedlot diet. South African Journal of Animal Science 34, 1995–1997.
Energy and nitrogen retention of Merino and Dohne Merino lambs receiving a feedlot diet.Crossref | GoogleScholarGoogle Scholar |

Notter DR (1987) The crossbred sire: theory. Journal of Animal Science 65, 99–109.

Pattinson R, Wilcox C, Williams S, Curtis K (2015) Trends and drivers for the global and Australian wool industry. Available at https://www.dpi.nsw.gov.au/__data/assets/pdf_file/0010/543547/Paper-1-global-supply-and-demand.pdf. [Verified 5 February 2021]

Phocas F, Belloc C, Bidanel J, Delaby L, Dourmad JY, Dumont B, Ezanno P, Fortun-Lamothe L, Foucras G, Frappat B, González-García E, Hazard D, Larzul C, Lubac S, Mignon-Grasteau S, Moreno CR, Tixier-Boichard M, Brochard M (2016) Review: Towards the agroecological management of ruminants, pigs and poultry through the development of sustainable breeding programmes: I-selection goals and criteria. Animal 10, 1749–1759.
Review: Towards the agroecological management of ruminants, pigs and poultry through the development of sustainable breeding programmes: I-selection goals and criteria.Crossref | GoogleScholarGoogle Scholar | 27170506PubMed |

Ransom K, Brien F, Pitchford W (2015) A commercial comparison of ewe breeds for reproduction, wool and lamb growth. Proceedings of the Association for the Advancement of Animal Breeding and Genetics 21, 286–289.

Robison OW, McDaniel BT, Rincon EJ (1981) Estimation of direct and maternal additive and heterotic effects from crossbreeding experiments in animals. Journal of Animal Science 52, 44–50.
Estimation of direct and maternal additive and heterotic effects from crossbreeding experiments in animals.Crossref | GoogleScholarGoogle Scholar | 7240038PubMed |

SAS Institute (2012) ‘SAS/STAT user’s guide. Version 9.4.’ (SAS Institute: Cary, NC, USA)

Sölkner J, James JW (1990) Optimum design of crossbreeding experiments. Journal of Animal Breeding and Genetics 107, 61–67.
Optimum design of crossbreeding experiments.Crossref | GoogleScholarGoogle Scholar |

Teixeira A, Matos S, Rodrigues S, Delfa R, Cadavez V (2006) In vivo estimation of lamb carcass composition by real-time ultrasonography. Meat Science 74, 289–295.
In vivo estimation of lamb carcass composition by real-time ultrasonography.Crossref | GoogleScholarGoogle Scholar | 22062838PubMed |

Van Beem D, Wellington D, Paganoni BL, Vercoe PE, Milton JTB (2008) Feed efficiency for meat and wool production by Merino and F1 Dohne × Merino lambs fed pelleted diets of different nutritive value. Australian Journal of Experimental Agriculture 48, 879–884.
Feed efficiency for meat and wool production by Merino and F1 Dohne × Merino lambs fed pelleted diets of different nutritive value.Crossref | GoogleScholarGoogle Scholar |

van Wyk JB, Swanepoel JW, Cloete SW, Olivier JJ, Delport GJ (2008) Across flock genetic parameter estimation for yearling body weight and fleece traits in the South African Dohne Merino population. South African Journal of Animal Sciences 38, 31–37.
Across flock genetic parameter estimation for yearling body weight and fleece traits in the South African Dohne Merino population.Crossref | GoogleScholarGoogle Scholar |

Viñoles C, Gonzalez‐Bulnes A, Martin GB, Sales F, Sale S (2010) Sheep and goats. In ‘Practical atlas of ruminant and camelid reproductive ultrasonography’. (Eds L DesCôteaux, J Colloton, G Gnemmi) pp. 181–210. (Wiley‐Blackwell: Ames, IA, USA)

Whitlock HV (1948) Some modifications of the McMaster helminth egg-counting technique and apparatus. Journal of the Council for Scientific and Industrial Research in Australia 21, 177–180.