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Nutritional limitations to increased production on pasture-based systems

Published online by Cambridge University Press:  05 March 2007

Eric S. Kolver*
Affiliation:
Dexcel (formerly Dairying Research Corporation), Private Bag 3221, Hamilton, New Zealand
*
Corresponding author: Dr Eric S. Kolver, fax +64 7 858 3751, [email protected]
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Abstract

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The constraints to high levels of milk production imposed by a high-quality-pasture diet, and development of feeding strategies to overcome these limitations, were examined by modelling the nutritional status of New Zealand Friesian and North American Holstein–Friesian dairy cows grazing high-quality pasture. The Cornell Net Carbohydrate and Protein System (CNCPS) was used to predict sensitivity of milk production to a 10 % change in the composition of pasture nutrients. The rate at which fibre and protein were degraded in the rumen and the value given to effective fibre and lignin content significantly affected the supply of metabolisable energy and protein, and the profile of amino acid supply. The first limiting factor in milk production when only high-quality pasture was fed was metabolisable energy supply, while specific amino acids, particularly methionine and lysine, limited milk production when > 20 g/kg diet consisted of a grain supplement. Compared with cows fed a total mixed ration in confinement, North American Holstein–Friesians grazing all pasture produced less milk (29.6 v. 44.1 kg/d). Of the difference in milk production 61 % could be attributed to a lower DM intake (19 kg/d v. 23.4 kg/d). Predictions using the CNCPS indicated that supply of metabolisable energy was the first-limiting factor for milk production from high-quality pasture (251 g crude protein (N× 6.25)/kg, 432 g neutraldetergent fibre/kg, 77 % in vitro DM digestibility), rather than metabolisable protein or amino acids. In addition, these nutritional limitations imposed by pasture diets will be greater for dairy cow genotypes that have not been selected for high performance within a pasture system.

Type
Symposium on ‘Nutrition of farm animals outdoors’
Copyright
Copyright © The Nutrition Society 2003

References

Arriaga-Jordan, CM & Holmes, W (1986) The effect of concentrate supplementation on high-yielding dairy cows under two systems of grazing Journal of Agricultural Science, Cambridge 107, 453461CrossRefGoogle Scholar
Bargo, F, Muller, LD, Kolver, ES & Delahoy, JE (2002) Invited review: Supplementation for high producing dairy cows on pasture. Journal of Dairy Science 85, 29482963CrossRefGoogle Scholar
Beever, DE & Siddons, RC (1986) Digestion and metabolism in the grazing ruminant Control of Digestion and Metabolism in Ruminants 479497 Milligan LP Grovum WL Dobson AA Englewood Cliffs, NJ Prentice-HallGoogle Scholar
Beever, DE & Thorpe, CL (1997) Supplementation of forage diets Milk Composition, Production and Biotechnology 419440 Welch RAS Burns DJW Davis SR Popay AI Prosser CG Cambridge Cambridge University PressGoogle Scholar
Berzaghi, P, Herbein, JH & Polan, CE (1996) Intake, site, and extent of nutrient digestion of lactating cows grazing pasture. Journal of Dairy Science 79, 15811589CrossRefGoogle ScholarPubMed
Carruthers, VR, Neil, PG & Dalley, DE (1996) Microbial protein synthesis and milk production in cows offered pasture diets differing in soluble:structural carbohydrate ratio. Proceedings of the New Zealand Society of Animal Production 56, 255259Google Scholar
Clark, DA, Penno, JW & Neil, PG (1997) Nutritional Merits and problems of pasture Milk Composition, Production and Biotechnology 397418 Welch RAS Burns DJW Davis SR Popay AI Prosser CG Cambridge Cambridge University PressGoogle Scholar
Clark, JH, Klusmeyer, TH & Cameron, MR (1992) Microbial protein synthesis and flows of nitrogen fractions to the duodenum of dairy cows. Journal of Dairy Science 75, 23042323CrossRefGoogle Scholar
Fox, DG, Barry, MC, Pitt, RE, Roseler, DK & Stone, WC (1995) Application of the Cornell Net Carbohydrate and Protein Model for cattle consuming forages. Journal of Animal Science 73, 267277CrossRefGoogle ScholarPubMed
Fox, DG, Sniffen, CJ, O'Connor, JD, Russell, JB, Van, Soest PJ (1992) A Net Carbohydrate and Protein System for evaluating cattle diets: III. Cattle requirements and diet adequacy. Journal of Animal Science 70, 35783596CrossRefGoogle ScholarPubMed
Gordon, FJ (1984) The effect of level of concentrate supplementation given with grass silage during winter on the total lactation performance of autumn-calving dairy cows Journal of Agricultural Science, Cambridge 102, 163179CrossRefGoogle Scholar
Grainger, C & Mathews, GL (1989) Positive relation between substitution rate and pasture allowance for cows receiving concentrates. Australian Journal of Experimental Agriculture 29, 355360CrossRefGoogle Scholar
Harris, BL & Kolver, ES (2001) A review of Holsteinization on intensive pastoral dairy farming in New Zealand. Journal of Dairy Science 84 E56 – E61CrossRefGoogle Scholar
Harris, BL & Winkelman, AM (2000) Influence of North American Holstein genetics on dairy cattle performance in New Zealand. Proceedings of the Australian Large Herds Conference 6, 122136Google Scholar
Hoden, A, Peyraud, JL, Muller, A, Delaby, L & Faverdin, P (1991) Simplified rotational grazing management of dairy cows: effects of rates of stocking and concentrate Journal of Agricultural Science, Cambridge 116, 417428CrossRefGoogle Scholar
Holden, LA, Muller, LD & Fales, SL (1994) Estimation of intake in high producing Holstein cows grazing grass pasture. Journal of Dairy Science 77, 23322340CrossRefGoogle ScholarPubMed
Holden, LA, Muller, LD, Lykos, T & Cassidy, TW (1995) Effect of corn silage supplementation on intake and milk production in cows grazing grass pasture. Journal of Dairy Science 78, 154162CrossRefGoogle ScholarPubMed
Holmes, CW (1987) Pastures for dairy cows Livestock Feeding on Pasture. New Zealand Society of Animal Production Occasional Publication no. 10 133143 Nicol AM Hamilton, New Zealand Ruakura Agriculture CentreGoogle Scholar
Holmes, CW (1995) Genotype × environment interactions in dairy cattle: a New Zealand perspective Breeding and Feeding the High Genetic Merit. British Society of Animal Science Cow Occasional Publication no. 19 5158 Edinburgh British Society of Animal ScienceCrossRefGoogle Scholar
Holmes, CW & Wilson, GF (1984) Milk Production from Pasture Wellington, New Zealand ButterworthsGoogle Scholar
Hongerholt, DD (1995) Grain supplementation strategies for dairy cows grazing grass pastures and their effects on milk production and microbial fermentation. PhD Dissertation, Pennsylvania State University, University Park, PA, USA.Google Scholar
Kellaway, RC & Porta, S (1993) Feeding Concentrates: Supplements for Dairy Cows Hopkins E Melbourne, Australia AgmediaGoogle Scholar
Kolver, ES (1997) Supplemental Feeding Strategies to Increase the Utilization of Pasture Nitrogen by High Producing Dairy Cows. PhD Dissertation, Pennsylvania State University, University Park, PA, USA.Google Scholar
Kolver, ES, Carruthers, VR, Neil, PG, de, Veth, MJ, Jansen, EBL, Phipps DE (1999) Amino acid supply to the small intestine of dairy cows fed pasture. Proceedings of the New Zealand Society of Animal Production 59, 180183Google Scholar
Kolver, ES, de, Veth MJ (2002) Prediction of ruminal pH of dairy cows fed pasture Journal of Dairy ScienceGoogle Scholar
Kolver, ES & Muller, LD (1998) Performance and nutrient intake of high producing Holstein cows consuming pasture or a total mixed ration. Journal of Dairy Science 81, 14031411CrossRefGoogle ScholarPubMed
Kolver, ES, Muller, LD, Barry, MC & Penno, JW (1998a) Evaluation and application of the Cornell Net Carbohydrate and Protein System for dairy cows fed diets based on pasture. Journal of Dairy Science 81, 20292039CrossRefGoogle ScholarPubMed
Kolver, ES, Muller, LD, Varga, GA & Cassidy, TW (1998b) Synchronization of ruminal degradation of supplemental carbohydrate with pasture nitrogen in lactating dairy cows. Journal of Dairy Science 81, 20172028CrossRefGoogle ScholarPubMed
Kolver, ES, Roche, JR, Thorne, PL, de, Veth, MJ, Napper AR (2002) Total mixed rations versus pasture diets: Evidence for a genotype × diet interaction in dairy cow performance. Proceedings of the New Zealand Society of Animal Production 62, 246251Google Scholar
Leaver, JD (1985) Milk production from grazed temperate grasslands. Journal of Dairy Research 52, 313334CrossRefGoogle Scholar
Leaver, JD (1986) Effects of supplements on herbage intake and performance Grazing. British Grasslands Society, Occasional Symposium no. 19 7988 Frame J Reading, Berks University of ReadingGoogle Scholar
McGilloway, DA & Mayne, CS (1996) The importance of grass availability for the high genetic merit dairy cow Recent Advances in Animal Nutrition 135169 Garnsworthy PC Wiseman J Haresign W Nottingham Nottingham University PressGoogle Scholar
Mackle, TR, Parr, CR & Bryant, AM (1996) Nitrogen fertiliser effects on milk yield and composition, pasture intake, nitrogen and energy partitioning, and rumen fermentation variables of dairy cows in early lactation. New Zealand Journal of Agricultural Research 39, 341356CrossRefGoogle Scholar
Mayne, CS & Gordon, FJ (1995) Implications of genotype × nutrition interactions for efficiency of milk production systems Breeding and Feeding the High Genetic Merit Cow. British Society of Animal Science Occasional Publication no. 19 6777 Edinburgh British Society of Animal ScienceCrossRefGoogle Scholar
Mayne, CS & Wright, IA (1988) Herbage intake and utilization by the grazing dairy cow Nutrition and Lactation in the Dairy Cow 280293 Garnsworthy PC London ButterworthCrossRefGoogle Scholar
Meijs, JAC & Hoekstra, JA (1984) Concentrate supplementation of dairy cows. 1. Effects of concentrate intake and herbage allowance on herbage intakes. Grass and Forage Science 39, 5966CrossRefGoogle Scholar
Minson, DJ (1990) Forage in Ruminant Nutrition New York Academic PressGoogle Scholar
Muller, LD, Kolver, ES & Holden, LA (1995) Nutritional needs of high producing cows on pasture. Proceedings of the Cornell Nutrition Conference for Feed Manufacturers 57, 106120Google Scholar
Mwansa, P & Peterson, R (1998) Estimates of G×E effects for longevity among daughters of Canadian and New Zealand sires in Canadian and New Zealand dairy herds. Interbull Bulletin 17, 110114Google Scholar
National, Research Council (1989) Nutrient Requirements of Dairy Cattle, 6th revised ed Washington, DC National Academy of ScienceGoogle Scholar
National, Research Council (2001) Nutrient Requirements of Dairy Cattle, 7th revised ed Washington, DC National Academy of ScienceGoogle Scholar
Pacheco-Rios, D, McNabb, WC, Hill, JP, Barry, TN & Mackenzie, DDS (1997) The effects of methionine supplementation on milk production of dairy cows in mid-lactation. Proceedings of the New Zealand Society of Animal Production 57, 147150Google Scholar
Peterson, R (1991) Evidence of a genotype/environment interaction between Canadian Holstein and New Zealand Friesian cattle under Canadian and New Zealand management systems. Proceedings of the 42nd Annual Meeting of the European Association for Animal Production 1 49Google Scholar
Rusdi, & van Houtert, MFJ (1997) Responses to protected amino acids or protected protein in dairy cows grazing ryegrass pastures in early lactation. Proceedings of the New Zealand Society of Animal Production 57, 120125Google Scholar
Russell, JB, O'Connor, JD, Fox, DG, Van, Soest, PJ, Sniffen CJ (1992) A Net Carbohydrate and Protein System for evaluating cattle diets. I. Ruminal fermentation. Journal of Animal Science 70, 35513561CrossRefGoogle Scholar
Sniffen, CJ, O'Connor, JD, Van, Soest, PJ, Fox, DG, Russell JB (1992) A Net Carbohydrate and Protein System for evaluating cattle diets. II. Carbohydrate and protein availability. Journal of Animal Science 70, 35623577CrossRefGoogle ScholarPubMed
Stakelum, G (1986) Herbage intake of grazing dairy cows. 2. Effect of herbage allowance, herbage mass and concentrate feeding on the intake of cows grazing primarily spring grass. Irish Journal of Agricultural Research 25, 4151Google Scholar
Stakelum, G (1993) Achieving high performance from dairy cows on grazed pastures. Irish Grassland and Animal Production Association Journal 27, 918Google Scholar
Stockdale, CR (2000) Levels of pasture substitution when concentrates are fed to grazing dairy cows in northern Victoria. Australian Journal of Experimental Agriculture 40, 913921CrossRefGoogle Scholar
Ulyatt, MJ & Waghorn, GC (1993) Limitations to high levels of dairy production from New Zealand pastures Improving the Quality and Intake of Pasture-based Diets for Lactating Cows. Occasional Publication no. 1 1132 Edwards NJ Parker WJ Palmerston North, New Zealand Department of Agricultural and Horticultural Systems Management, Massey UniversityGoogle Scholar
van, Vuuren, AM, Krol-Dramer, F, van der, Lee, RA & Corbijn, H (1992) Protein digestion and intestinal amino acids in dairy cows fed fresh Lolium perenne with different nitrogen contents. Journal of Dairy Science 75, 22152225Google Scholar
van, Vuuren, AM, van der, Koelen, CJ, Vroons-de, Bruin J (1993) Ryegrass versus corn starch or beet pulp fiber diet effects on digestion and intestinal amino acids in dairy cows. Journal of Dairy Science 76, 26922700Google Scholar
Waghorn, GS & Barry, TN (1986) Pasture as a nutrient source In Livestock Feeding on Pasture. New Zealand Society of Animal Production Occasional Publication no. 10 2138 Nicol AM Hamilton, New Zealand Ruakura Agriculture CentreGoogle Scholar
Wu, Z, Polan, CJ & Fisher, RJ (1997) Adequacy of amino acids in diets fed to lactating dairy cows. Journal of Dairy Science 80, 17131721CrossRefGoogle ScholarPubMed
Younge, BA (1997) Amino acid and protein nutrition of dairy cows. PhD Dissertation, University College Dublin, Republic of Ireland.Google Scholar