Hostname: page-component-8448b6f56d-gtxcr Total loading time: 0 Render date: 2024-04-25T01:07:34.171Z Has data issue: false hasContentIssue false
  • English
  • Français

Growth, morphology and biological nitrogen fixation potential of perennial ryegrass-white clover swards throughout the grazing season

Published online by Cambridge University Press:  05 April 2018

C. Guy ,
D. Hennessy ,
T. J. Gilliland ,
F. Coughlan  and
B. McCarthy
C. Guy*
Affiliation:
Teagasc, Animal and Grassland Research and Innovation Centre, Moorepark, Fermoy, Co. Cork, Ireland The Institute for Global Food Security, Queen's University Belfast, Belfast, Ireland
D. Hennessy
Affiliation:
Teagasc, Animal and Grassland Research and Innovation Centre, Moorepark, Fermoy, Co. Cork, Ireland
T. J. Gilliland
Affiliation:
The Institute for Global Food Security, Queen's University Belfast, Belfast, Ireland Agri-food and Biosciences Institute, Large Park, Hillsborough, BT26 6DR, Ireland
F. Coughlan
Affiliation:
Teagasc, Animal and Grassland Research and Innovation Centre, Moorepark, Fermoy, Co. Cork, Ireland
B. McCarthy
Affiliation:
Teagasc, Animal and Grassland Research and Innovation Centre, Moorepark, Fermoy, Co. Cork, Ireland
*
Author for correspondence: C. Guy, E-mail: clare.guy@teagasc.ie
Get access Rights & Permissions [Opens in a new window]

Abstract

Sustainable ruminant production systems depend on the ability of livestock to utilize increased quantities of grazed herbage. The current study aimed to compare the effect of white clover (WC) inclusion and perennial ryegrass (PRG) ploidy on herbage dry matter (DM) production, plant morphology, nutritive value and biological nitrogen (N) fixation (BNF) under high N fertilizer use (250 kg N/ha) and high stocking rates (2.75 livestock units/ha). Four sward treatments (diploid-only, tetraploid-only, diploid-WC, tetraploid-WC) were evaluated over a full grazing season at a farmlet scale. White clover inclusion had a significant effect on herbage DM production, herbage growth rate, tiller density, organic matter digestibility, crude protein and BNF. Tetraploid swards had a lower tiller density, lower sward WC content and post-grazing sward height and increased organic matter digestibility and crude protein than diploid swards. White clover inclusion improved herbage DM production and nutritive value across a full grazing season, with tetraploid and diploid swards producing similar herbage DM yields across the year. Perennial ryegrass ploidy had an effect on WC morphology as plants in diploid-WC swards had narrower, longer stolons, fewer branches and more petioles than tetraploid-WC swards. The current study highlights the benefit of including WC in grass-based systems under a high N fertilizer regime and high stocking rate.

Keywords

Herbage DM productionherbage nutritive valueLolium perenne L.perennial ryegrass ploidystolon morphologyTrifolium repens L.
Type
Crops and Soils Research Paper
Information
The Journal of Agricultural Science , Volume 156 , Issue 2 , March 2018 , pp. 188 - 199
Check for updates
Copyright
Copyright © Cambridge University Press 2018 

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

AOAC (1990) Official Methods of Analysis, 15th ed. Method 990–03. Volume 1. Arlington, VA, USA: Association of Official Analytical Chemists.Google Scholar
Arsenault, N, Tyedmers, P and Fredeen, A (2009) Comparing the environmental impacts of pasture-based and confinement-based dairy systems in Nova Scotia (Canada) using life cycle assessment. International Journal of Agricultural Sustainability 7, 1941.Google Scholar
Ayres, JF, Nandra, KS and Turner, AD (1998) A study of the nutritive value of white clover (Trifolium repens L.) in relation to different stages of phenological maturity in the primary growth phase in spring. Grass and Forage Science 53, 250259.CrossRefGoogle Scholar
Baker, M and Williams, W (1987) White Clover. Wallingford, UK: CAB International.Google Scholar
Balocchi, OA and López, IF (2009) Herbage production, nutritive value and grazing preference of diploid and tetraploid perennial ryegrass cultivars (Lolium perenne L.). Chilean Journal of Agricultural Research 69, 331339.Google Scholar
Barrett, PD, Laidlaw, AS, Mayne, CS and Christie, H (2001) Pattern of herbage intake rate and bite dimensions of rotationally grazed dairy cows as sward height declines. Grass and Forage Science 56, 362373.Google Scholar
Beever, DE and Thorp, C (1996) Advances in the understanding of factors influencing the nutritive value of legumes. In Younie, D (ed.). Legumes in Sustainable Farming Systems, British Grassland Society Occasional Symposium no. 30. Reading, UK: British Grassland Society, pp. 194207.Google Scholar
Beever, DE, Dhanoa, MS, Losada, HR, Evans, RT, Cammell, SB and France, J (1986) The effect of forage species and stage of harvest on the processes of digestion occurring in the rumen of cattle. British Journal of Nutrition 56, 439454.CrossRefGoogle ScholarPubMed
Bleken, MA, Steinshamn, H and Hansen, S (2005) High nitrogen costs of dairy production in Europe: worsened by intensification. AMBIO: A Journal of the Human Environment 34, 598606.Google Scholar
Brereton, A. J. (1995) Regional and year-to-year variation in yield. In Jeffrey, DW, Jones, MB and McAdam, JH (eds). Irish Grasslands: Their Biology and Management, Dublin, Ireland: Dublin Royal Irish Academy, pp. 1222.Google Scholar
Brock, JL, Hay, MJM, Thomas, VJ and Sedcole, JR (1988) Morphology of white clover (Trifolium repens L.) plants in pastures under intensive sheep grazing. Journal of Agricultural Science, Cambridge 111, 273283.Google Scholar
Buxton, DR (1996) Quality-related characteristics of forages as influenced by plant environment and agronomic factors. Animal Feed Science and Technology 59, 3749.Google Scholar
Byrne, N, Gilliland, TJ, McHugh, N, Delaby, L, Geoghegan, A and O'Donovan, M (2017) Establishing phenotypic performance of grass varieties on Irish grassland farms. Journal of Agricultural Science, Cambridge 155, 16331645.Google Scholar
Caradus, JR and Williams, WM (1981) Breeding for improved white clover production in New Zealand hill country. In Wright, CE (ed.). Plant Physiology and Herbage Production. British Grassland Society Occasional Symposium, Notingham, UK: Nottingham University, pp. 163168.Google Scholar
Caradus, JR, Hay, RJM and Woodfield, DR (1996) The positioning of white clover cultivars in New Zealand. In Woodfield, DR (ed.). White Clover: New Zealand's Competitive Edge, Agronomy Society of New Zealand Special Publication 11, Grassland Research and Practice Series no. 6. Palmerston North, New Zealand: New Zealand Grassland Association, pp. 4550.Google Scholar
Carlsson, G and Huss-Danell, K (2003) Nitrogen fixation in perennial forage legumes in the field. Plant and Soil 253, 353372.Google Scholar
Cashman, PA (2014) Differential productivity and persistency responses to simulated and animal grazing of perennial ryegrass genotypes. PhD Thesis, Queen's University Belfast.Google Scholar
Cashman, PA, McEvoy, M, Gilliland, TJ and O'Donovan, M (2016) A comparison between cutting and animal grazing for dry-matter yield, quality and tiller density of perennial ryegrass cultivars. Grass and Forage Science 71, 112122.Google Scholar
Castle, ME (1976) A simple disc instrument for estimating herbage yield. Grass and Forage Science 31, 3740.Google Scholar
Chaves, AV, Waghorn, GC, Brookes, IM and Woodfield, DR (2006) Effect of maturation and initial harvest dates on the nutritive characteristics of ryegrass (Lolium perenne L.). Animal Feed Science and Technology 127, 293318.Google Scholar
Connolly, V (2001) Breeding Improved Varieties of Perennial Ryegrass. End of Project Report. Oak Park, Carlow, Ireland: Teagasc.Google Scholar
Cosgrove, GP, Burke, JL, Death, AF, Lane, GA, Fraser, K and Pacheco, D (2006) The effect of clover-rich diets on cows in mid lactation: production, behaviour and nutrient use. Proceedings of the New Zealand Grassland Association 68, 267273.Google Scholar
Creighton, P, Kennedy, E, Shalloo, L, Boland, TM and O'Donovan, M (2011) A survey analysis of grassland dairy farming in Ireland, investigating grassland management, technology adoption and sward renewal. Grass and Forage Science 66, 251264.Google Scholar
Creighton, P, Gilliland, TJ, Delaby, L, Kennedy, E, Boland, TM and O'Donovan, M (2012) Effect of Lolium perenne sward density on productivity under simulated and actual cattle grazing. Grass and Forage Science 67, 526534.Google Scholar
Curll, ML and Wilkins, RJ (1982) Frequency and severity of defoliation of grass and clover by sheep at different stocking rates. Grass and Forage Science 37, 291297.Google Scholar
Davies, A (1992) White clover. Biologist 39, 129133.Google Scholar
Davies, A and Thomas, H (1983) Rates of leaf and tiller production in young spaced perennial ryegrass plants in relation to soil temperature and solar radiation. Annals of Botany 57, 591597.Google Scholar
Delaby, L, Peyraud, J-L, Bouttier, A and Peccatte, JR (1998) Effet d'une réduction simultanée de la fertilisation azotée et du chargement sur les performances des vaches laitières et la valorisation du pâturage. Annales de Zootechnie 47, 1739.CrossRefGoogle Scholar
Egan, M (2015) Strategies to increase white clover in intensive dairy production systems. PhD Thesis, University College Dublin.Google Scholar
Egan, M, Galvin, N and Hennessy, D (2018) Incorporating white clover (Trifolium repens L.) into perennial ryegrass (Lolium perenne L.) swards receiving varying levels of nitrogen fertilizer: effects on milk and herbage production. Journal of Dairy Science (in press). doi: 10.3168/jds.2017-13233.Google Scholar
Elgersma, A, Schlepers, H and Nassiri, M (2000) Interactions between perennial ryegrass (Lolium perenne L.) and white clover (Trifolium repens L.) under contrasting nitrogen availability: productivity, seasonal patterns of species composition, N2 fixation, N transfer and N recovery. Plant and Soil 221, 281299.Google Scholar
Enriquez-Hidalgo, D (2014) Strategies to optimise white clover (Trifolium repens L.) content in grass white clover swards to consistently replace inorganic nitrogen in grazing systems. PhD Thesis, Queen's University Belfast.Google Scholar
Enriquez-Hidalgo, D, Gilliland, T, Deighton, MH, O'Donovan, M and Hennessy, D (2014) Milk production and enteric methane emissions by dairy cows grazing fertilized perennial ryegrass pasture with or without inclusion of white clover. Journal of Dairy Science 97, 14001412.Google Scholar
Enriquez-Hidalgo, D, Gilliland, TJ and Hennessy, D (2016) Herbage and nitrogen yields, fixation and transfer by white clover to companion grasses in grazed swards under different rates of nitrogen fertilization. Grass and Forage Science 71, 559574.Google Scholar
Evans, DR, Williams, TA, Jones, S and Evans, SA (1998) The effect of cutting and intensive grazing managements on sward components of contrasting ryegrass and white clover types when grown in mixtures. Journal of Agricultural Science, Cambridge 130, 317322.Google Scholar
Frame, J and Newbould, P (1986) Agronomy of white clover. Advances in Agronomy 40, 188.Google Scholar
Fulkerson, WJ and Donaghy, DJ (2001) Plant-soluble carbohydrate reserves and senescence-key criteria for developing an effective grazing management system for ryegrass-based pastures: a review. Australian Journal of Experimental Agriculture 41, 261275.Google Scholar
Gilliland, TJ, Barrett, PD, Mann, RL, Agnew, RL and Fearon, AM (2002) Canopy morphology and nutritional quality traits as potential grazing value indicators for Lolium perenne varieties. Journal of Agricultural Science, Cambridge 139, 257273.CrossRefGoogle Scholar
Godfray, HCJ, Beddington, JR, Crute, IR, Haddad, L, Lawrence, D, Muir, JF, Pretty, J, Robinson, S, Thomas, SM and Toulmin, C (2010) Food security: the challenge of feeding 9 billion people. Science 327, 812818.Google Scholar
Gooding, RF, Frame, J and Thomas, C (1996) Effects of sward type and rest periods from sheep grazing on white clover presence in perennial ryegrass/white clover associations. Grass and Forage Science 51, 180189.Google Scholar
Gowen, N, O'Donovan, M, Casey, I, Rath, M, Delaby, L and Stakelum, G (2003) The effect of grass cultivars differing in heading date and ploidy on the performance and dry matter intake of spring calving dairy cows at pasture. Animal Research 52, 321336.Google Scholar
Grant, SA, Barthram, GT and Torvell, L (1981) Components of regrowth in grazed and cut Lolium perenne swards. Grass and Forage Science 36, 155168.Google Scholar
Hanrahan, L, Geoghegan, A, O'Donovan, M, Griffith, V, Ruelle, E, Wallace, M and Shalloo, L (2017) Pasturebase Ireland: a grassland decision support system and national database. Computers and Electronics in Agriculture 136, 193201.Google Scholar
Harris, SL and Clark, DA (1996) Effect of high rates of nitrogen fertiliser on white clover growth, morphology, and nitrogen fixation activity in grazed dairy pasture in northern New Zealand. New Zealand Journal of Agricultural Research 39, 149158.Google Scholar
Harris, SL, Clark, DA, Auldist, MJ, Waugh, CD and Laboyrie, PG (1997) Optimum white clover content for dairy pastures. Proceedings of the New Zealand Grassland Association 59, 2934.Google Scholar
Harris, W (1987) Population dynamics and competition. In Baker, MJ and Williams, WM (eds). White Clover, Wallingford, UK: CAB International, pp. 203297.Google Scholar
Hay, MJM, Chapman, DF, Hay, RJM, Pennell, CGL, Woods, PW and Fletcher, RH (1987) Seasonal variation in the vertical distribution of white clover stolons in grazed swards. New Zealand Journal of Agricultural Research 30, 18.Google Scholar
Høgh-Jensen, H, Loges, R, Jørgensen, FV, Vinther, FP and Jensen, ES (2004) An empirical model for quantification of symbiotic nitrogen fixation in grass-clover mixtures. Agricultural Systems 82, 181194.Google Scholar
Humphreys, J, Casey, IA and Laidlaw, AS (2009) Comparison of milk production from clover-based and fertilizer-N-based grassland on a clay-loam soil under moist temperate climatic conditions. Irish Journal of Agricultural and Food Research 48, 189207.Google Scholar
Jarvis, SC (1992) Nitrogen cycling and losses in clover based pastures. Herba 5, 5659.Google Scholar
Jenquip (2016) Rising Plate Pasture Meters. New Zealand: Jenquip. Available at http://jenquip.co.nz/categories/rising-plate-pasture-meters (Accessed 9 February 2018).Google Scholar
Jorgensen, FV and Ledgard, SF (1997) Contribution from stolons and roots to estimates of the total amount of N2 fixed by white clover (Trifolium repens L.). Annals of Botany 80, 641648.Google Scholar
Laidlaw, AS, Teuber, NG and Withers, JA (1992) Out-of-season management of grass/clover swards to manipulate clover content. Grass and Forage Science 47, 220229.CrossRefGoogle Scholar
Lantinga, EA and Groot, JC (1996) Optimization of grassland production and herbage feed quality in an ecological context. In Groen, AF and van Bruchem, J (eds). Utilization of Local Feed Resources by Dairy Cattle, Wageningen, The Netherlands: Wageningen Press, pp. 5866.Google Scholar
Leach, KA, Bax, JA, Roberts, DJ and Thomas, C (2000) The establishment and performance of a dairy system based on perennial ryegrass – white clover swards compared with a system based on nitrogen fertilized grass. Biological Agriculture and Horticulture 17, 207227.Google Scholar
Ledgard, S, Schils, R, Eriksen, J and Luo, J (2009) Environmental impacts of grazed clover/grass pastures. Irish Journal of Agricultural and Food Research 48, 209226.Google Scholar
Ledgard, SF (2001) Nitrogen cycling in low input legume-based agriculture, with emphasis on legume/ grass pastures. Plant and Soil 228, 4359.Google Scholar
Ledgard, SF and Steele, KW (1992) Biological nitrogen fixation in mixed legume/grass pastures. Plant and Soil 141, 137153.Google Scholar
Ledgard, SF, Sprosen, MS, Penno, JW and Rajendram, GS (2001) Nitrogen fixation by white clover in pastures grazed by dairy cows: temporal variation and effects of nitrogen fertilization. Plant and Soil 229, 177187.Google Scholar
Lüscher, A, Mueller-Harvey, I, Soussana, JF, Rees, RM and Peyraud, JL (2014) Potential of legume-based grassland-livestock systems in Europe: a review. Grass and Forage Science 69, 206228.Google Scholar
McCarthy, B, Pierce, KM, Delaby, L, Brennan, A, Fleming, C and Horan, B (2013) The effect of stocking rate and calving date on grass production, utilization and nutritive value of the sward during the grazing season. Grass and Forage Science 68, 364377.Google Scholar
Morgan, DJ, Stakelum, G and O'Dwyer, J (1989) Modified neutral detergent cellulase digestibility of herbage by dairy cows. Irish Journal of Agricultural and Food Research 26, 2324.Google Scholar
Munro, JMM and Davies, DA (1974) Potential pasture production in the uplands of Wales. 5. The nitrogen contribution of white clover. Grass and Forage Science 29, 213213.Google Scholar
O'Donovan, M (2000) The relationship between the performance of dairy cows and grassland management on intensive dairy farms in Ireland. PhD Thesis, University College Dublin.Google Scholar
O'Donovan, M and Delaby, L (2005) A comparison of perennial ryegrass cultivars differing in heading date and grass ploidy with spring calving dairy cows grazed at two different stocking rates. Animal Research 54, 337350.Google Scholar
O'Donovan, M, Lewis, E and O'Kiely, P (2011) Requirements of future grass-based ruminant production systems in Ireland. Irish Journal of Agricultural and Food Research 50, 121.Google Scholar
O'Riordan, EG, O'Kiely, P and Keane, MG (1998) Efficient Beef Production From Grazed Pasture. End of Project Report. Oak Park, Ireland: Teagasc.Google Scholar
Phelan, P (2013) Aspects of grazing management to improve productivity and persistence of white clover in Irish grassland. PhD Thesis, Waterford Institute of Technology.Google Scholar
Pinxterhuis, JB (2000) White clover dynamics in New Zealand pastures. PhD Thesis, Wageningen University.Google Scholar
Prince, AJ, Apostolopoulou, E and Simonova, M (2009) Nitrogen Fertiliser Supply and Demand: Balances, Outlook and Drivers of Change. Proceedings of the International Fertiliser Society. Colchester, UK: International Fertiliser Society.Google Scholar
Ribeiro Filho, HMN, Delagarde, R and Peyraud, JL (2003) Inclusion of white clover in strip-grazed perennial ryegrass swards: herbage intake and milk yield of dairy cows at different ages of sward regrowth. Animal Science 77, 499510.Google Scholar
Ribeiro Filho, HMN, Delagarde, R and Peyraud, JL (2005) Herbage intake and milk yield of dairy cows grazing perennial ryegrass swards or white clover/perennial ryegrass swards at low-and medium-herbage allowances. Animal Feed Science and Technology 119, 1327.Google Scholar
SAS (2011) SAS version 9.3. Cary, North Carolina: SAS Institute.Google Scholar
Shalloo, L, Dillon, P, O'Loughlin, J, Rath, M and Wallace, M (2004) Comparison of a pasture-based system of milk production on a high rainfall, heavy-clay soil with that on a lower rainfall, free-draining soil. Grass and Forage Science 59, 157168.Google Scholar
Smith, KF, Simpson, RJ, Culvenor, RA, Humphreys, MO, Prud'Homme, MP and Oram, RN (2001) The effects of ploidy and a phenotype conferring a high water-soluble carbohydrate concentration on carbohydrate accumulation, nutritive value and morphology of perennial ryegrass (Lolium perenne L.). Journal of Agricultural Science, Cambridge 136, 6574.Google Scholar
Søegaard, K (1993) Nutritive value of white clover. In Frame, J (ed.). White Clover in Europe: State of the Art, 17A23. REUR Technical Series 29. Rome, Italy: FAO.Google Scholar
Stewart, A and Hayes, R (2011) Ryegrass breeding-balancing trait priorities. Irish Journal of Agricultural and Food Research 50, 3146.Google Scholar
Thomas, VJ (1973) Competition among pasture plants. III. Effects of frequency and height of cutting on competition between white clover and two ryegrass cultivars. New Zealand Journal of Agricultural Research 16, 4958.Google Scholar
Thomson, DJ (1984) The nutritive value of white clover. In Thomson, DJ (ed.). Forage Legumes, Occasional Symposium no. 16. Berkshire, UK: British Grassland Society, pp. 7892.Google Scholar
Ulyatt, MJ (1980) The feeding value of temperate pastures. In Morley, FHW (ed.). Grazing Animals, Amsterdam, The Netherlands: Elsevier Scientific Publishing Company, pp. 125141.Google Scholar
Ulyatt, MJ, Lancashire, JA and Jones, WT (1977) The nutritive value of legumes. Proceedings of the New Zealand Grassland Association 38, 107118.Google Scholar
Ulyatt, MJ, Lassey, KR, Shelton, ID and Walker, CF (2002) Seasonal variation in methane emission from dairy cows and breeding ewes grazing ryegrass/white clover pasture in New Zealand. New Zealand Journal of Agricultural Research 45, 217226.Google Scholar
Unkovich, M (2012) Nitrogen fixation in Australian dairy systems: review and prospect. Crop and Pasture Science 63, 787804.Google Scholar
Van Soest, PJ (1963) Use of detergents in the analysis of fibrous feeds. 2. A rapid method for the determination of fiber and lignin. Journal of the Association of Official Agricultural Chemists 46, 829835.Google Scholar
Wilkins, PW and Humphreys, MO (2003) Progress in breeding perennial forage grasses for temperate agriculture. Journal of Agricultural Science, Cambridge 140, 129150.Google Scholar
Wims, CM, McEvoy, M, Delaby, L, Boland, TM and O'Donovan, M (2013) Effect of perennial ryegrass (Lolium perenne L.) cultivars on the milk yield of grazing dairy cows. Animal 7, 410421.CrossRefGoogle ScholarPubMed