Persistence of Phalaris aquatica in grazed pastures 2. Regenerative bud and tiller development
B. R. Cullen A B C , D. F. Chapman A and P. E. Quigley BA School of Agriculture and Food Systems, Institute of Land and Food Resources, The University of Melbourne, Vic. 3010, Australia.
B Primary Industries Research Victoria, Department of Primary Industries, Private Bag 105, Hamilton, Vic. 3300, Australia.
C Present address and corresponding author. CSIRO Sustainable Ecosystems, Queensland Bioscience Precinct, 306 Carmody Road, St Lucia, Qld 4067, Australia. Email: brendan.cullen@csiro.au
Australian Journal of Experimental Agriculture 45(1) 49-58 https://doi.org/10.1071/EA03228
Submitted: 9 November 2003 Accepted: 28 March 2004 Published: 21 February 2005
Abstract
The summer survival, regeneration and tillering characteristics of phalaris (Phalaris aquatica cv. Australian) were examined in pastures using 4 grazing management systems in a grazing trial in south-western Victoria over 2 consecutive seasons. The grazing treatments tested covered a range of management intensities from a set-stocked with low phosphate input system to an intensive rotation with high phosphate. The soil fertility and grazing methods tested had no effect on the plant developmental characteristics measured in the field. The phalaris tiller population regenerated exclusively from dormant buds, as no vegetative tillers formed in the late spring/early summer survived through to the autumn break. On average, 3.7 regenerative buds were formed on each reproductive tiller. Half of these regenerative buds grew out in the field during the following growing season forming a new tiller. Of the new tillers formed, 71% produced at least 1 secondary tiller, with the average total number of secondary and higher tillers produced per new tiller being 4.5. Across both seasons, an average of 6.7% of the maximum vegetative tiller density became reproductive, and these reproductive tillers each contributed 3.7 buds to the population’s regenerative capacity in the following season. A simple model of bud development and tiller turnover showed that each regenerative bud at the start of the growing season was replaced by 0.54 buds at the start of the following season, indicating a substantial population decline. Reproductive tiller density was identified as a key limitation to phalaris persistence in this experiment. It is proposed that lowering grazing intensity during spring will increase the proportion of tillers that become reproductive and enhance phalaris persistence.
Acknowledgments
We acknowledge the assistance of the Sustainable Grazing Systems team at the Pastoral and Veterinary Institute, Hamilton, in setting up and maintaining the trial site, and Gavin Kearney for statistical advice. The Australian Research Council provided a scholarship to the senior author during this study.
Archer KA
(1990) The effects of moisture supply and defoliation during flowering on seed production and hardseededness of Trifolium subterraneum L. Australian Journal of Experimental Agriculture 30, 515–522.
| Crossref |
Biddiscombe EF,
Rogers AL, Maller RA
(1977) Summer dormancy, regeneration and persistence of perennial grasses in south-western Australia. Australian Journal of Experimental Agriculture and Animal Husbandry 17, 795–801.
| Crossref |
Busso CA,
Mueller RJ, Richards JH
(1989) Effects of drought and defoliation on bud viability in two caespitose grasses. Annals of Botany 63, 477–485.
Butler JL, Briske DD
(1988) Population structure and tiller demography of the bunchgrass Schizachyrium scoparium in response to herbivory. Oikos 51, 306–312.
Chapman DF, Clark DA
(1984) Pasture responses to grazing management in hill country. Proceedings of the New Zealand Grassland Association 45, 168–176.
Chapman DF,
Clark DA,
Land CA, Dymock N
(1983) Leaf and tiller growth of Lolium perenne and Agrostis spp. and leaf appearance rates of Trifolium repens in set-stocked and rotationally grazed hill pastures. New Zealand Journal of Agricultural Research 26, 159–168.
Chapman DF,
McCaskill MR,
Quigley PE,
Thompson AN,
Graham JF,
Borg D,
Lamb J,
Kearney GA,
Saul GR, Clark SG
(2003) Effects of grazing method and fertilizer inputs on the productivity and sustainability of phalaris-based pastures in Western Victoria. Australian Journal of Experimental Agriculture 43, 785–798.
Cooper JP, McWilliam JR
(1966) Climatic variation in forage grasses. 2. Germination, flowering and leaf development in Mediterranean populations of Phalaris tuberosa. Journal of Applied Ecology 3, 191–212.
Cullen BR,
Chapman DF, Quigley PE
(2005) Persistence of Phalaris aquatica in grazed pastures. 1. Plant and tiller population characteristics. Australian Journal of Experimental Agriculture 45, 41–48.
| Crossref |
Culvenor RA
(1993) Effect of cutting during reproductive development on the regrowth and regenerative capacity of the perennial grass, Phalaris aquatica L., in a controlled environment. Annals of Botany 72, 559–568.
| Crossref | GoogleScholarGoogle Scholar |
Culvenor RA
(1994) The persistence of five cultivars of phalaris after cutting during reproductive development in spring. Australian Journal of Agricultural Research 45, 945–962.
| Crossref | GoogleScholarGoogle Scholar |
Culvenor RA
(1997) Observations on tillering in cultivars of phalaris under rotational grazing in a year with summer–autumn drought. Australian Journal of Agricultural Research 48, 467–476.
| Crossref | GoogleScholarGoogle Scholar |
Culvenor RA, Oram RN
(1996) Comparison of winter-active phalaris with the Australian cultivar under rotational grazing. 1. Basal area and plant density. Australian Journal of Experimental Agriculture 36, 287–297.
| Crossref |
Hendrickson JR, Briske DD
(1997) Axillary bud banks of two semiarid perennial grasses: occurrence, longevity, and contribution to population persistence. Oecologia 110, 584–591.
| Crossref | GoogleScholarGoogle Scholar |
Hill MJ
(1989) The effect of differences in the intensity and frequency of defoliation on the growth of Phalaris aquatica L. and Dactylis glomerata L. Australian Journal of Agricultural Research 40, 333–343.
Hoen K
(1968) Summer dormancy in Phalaris tuberosa L. Australian Journal of Agricultural Research 19, 227–239.
| Crossref | GoogleScholarGoogle Scholar |
Hume DE, Barker DJ
(1991) Natural reseeding of five grass species in summer dry hill country. Proceedings of the New Zealand Grasslands Association 53, 97–104.
Johnson IR, Parsons AJ
(1985) Use of a model to analyse the effects of continuous grazing managements on seasonal patterns of grass production. Grass and Forage Science 40, 449–458.
Kemp DR,
Michalk DL, Virgona JM
(2000) Towards more sustainable pastures: lessons learnt. Australian Journal of Experimental Agriculture 40, 343–356.
| Crossref | GoogleScholarGoogle Scholar |
Laude HM
(1953) The nature of summer dormancy in perennial grasses. Botanical Gazette (Chicago, Ill.) 114, 284–296.
| Crossref | GoogleScholarGoogle Scholar |
Lodge GM,
Murphy SR, Harden S
(2003) Effects of continuous and seasonal grazing strategies on the herbage mass, persistence, animal productivity and soil water content of a Sirosa phalaris–subterranean clover pasture, North-West Slopes, New South Wales. Australian Journal of Experimental Agriculture 43, 539–552.
| Crossref | GoogleScholarGoogle Scholar |
McCallum DA,
Thomson NA, Judd TG
(1991) Experiences with deferred grazing at the Taranaki Agricultural Research Station. Proceedings of the New Zealand Grasslands Association 53, 79–83.
McIntyre GI
(1972) Studies on bud development in the rhizome of Agropyron repens. II. The effect of nitrogen supply. Canadian Journal of Botany 50, 393–401.
McWilliam JR
(1968) The nature of the perennial response in Mediterranean grasses. 2. Senescence, summer dormancy and survival in Phalaris. Australian Journal of Agricultural Research 19, 397–409.
| Crossref | GoogleScholarGoogle Scholar |
McWilliam JR, Kramer PJ
(1968) The nature of the perennial response in Mediterranean grasses. 1. Water relations and summer survival in Phalaris. Australian Journal of Agricultural Research 19, 381–395.
| Crossref | GoogleScholarGoogle Scholar |
Mitchell KJ
(1953) Influence of light and temperature on the growth of ryegrass (Lolium spp.). 2. The control of lateral bud development. Physiologia Plantarum 6, 425–443.
Mueller RJ, Richards JH
(1986) Morphological analysis of tillering in Agropyron spicatum and Agropyron desertorum. Annals of Botany 58, 911–921.
Murphy JS, Briske DD
(1992) Regulation of tillering by apical dominance: chronology, interpretive value, and current perspectives. Journal of Range Management 45, 419–429.
Newton PCD, Hay MJM
(1996) Clonal growth of white clover: factors influencing the viability of axillary buds and the outgrowth of a viable bud to form a branch. Annals of Botany 78, 111–115.
| Crossref | GoogleScholarGoogle Scholar |
Novoplansky A
(1996) Hierarchy establishment among potentially similar buds. Plant, Cell and Environment 19, 781–786.
Sharman BC
(1947) The biology and developmental morphology of the shoot apex in the Gramineae. The New Phytologist 46, 20–34.
Silsbury JH
(1964) Tiller dynamics, growth, and persistency of Lolium perenne L. and of Lolium rigidum Gaud. Australian Journal of Agricultural Research 15, 9–20.
| Crossref | GoogleScholarGoogle Scholar |
Skinner RH, Nelson CJ
(1994) Effect of tiller trimming on phyllochron and tillering regulation during tall fescue development. Crop Science 34, 1267–1273.
Virgona JM,
Avery AL,
Graham JF, Orchard BA
(2000) Effects of grazing management on phalaris herbage mass and persistence in summer-dry environments. Australian Journal of Experimental Agriculture 40, 171–184.
| Crossref | GoogleScholarGoogle Scholar |