Hostname: page-component-7479d7b7d-k7p5g Total loading time: 0 Render date: 2024-07-11T23:49:00.567Z Has data issue: false hasContentIssue false
  • English
  • Français

Plant Development and Seed Biology of Windmillgrass (Chloris truncata) in Southern Australia

Published online by Cambridge University Press:  08 May 2017

The D. Ngo ,
Peter Boutsalis ,
Christopher Preston  and
Gurjeet Gill
The D. Ngo*
Affiliation:
Postgraduate Student, Postdoctoral Fellow, Associate Professor, and Associate Professor, School of Agriculture, Food and Wine, University of Adelaide, PMB 1, Glen Osmond, SA 5064, Australia
Peter Boutsalis
Affiliation:
Postgraduate Student, Postdoctoral Fellow, Associate Professor, and Associate Professor, School of Agriculture, Food and Wine, University of Adelaide, PMB 1, Glen Osmond, SA 5064, Australia
Christopher Preston
Affiliation:
Postgraduate Student, Postdoctoral Fellow, Associate Professor, and Associate Professor, School of Agriculture, Food and Wine, University of Adelaide, PMB 1, Glen Osmond, SA 5064, Australia
Gurjeet Gill
Affiliation:
Postgraduate Student, Postdoctoral Fellow, Associate Professor, and Associate Professor, School of Agriculture, Food and Wine, University of Adelaide, PMB 1, Glen Osmond, SA 5064, Australia
*
*Corresponding author’s E-mail: ducthe.ngo@adelaide.edu.au
Get access Rights & Permissions [Opens in a new window]

Abstract

Windmillgrass is a major weed in agricultural systems in northern Australia, and it has now become more common in southern Australia. Because little information is available on the biology of this weed species in southern Australia, studies were conducted to investigate plant development and seed biology. Under irrigated field conditions in South Australia, windmillgrass required 748 to 786 growing degree days from emergence to mature seed production. Freshly harvested seed had low dormancy with 16% to 40% germination. Seeds required light exposure for germination and less than 2% germination was observed in complete darkness. Seed could germinate over a wide temperature range (10 to 40 C) with maximum germination at 20 to 25 C. At 25 to 30 C, 50% germination occurred within 27.3 to 45.5 h, and the predicted base temperature for germination of the two populations investigated ranged from 9.2 to 11.2 C. The sodium chloride concentration and osmotic potential required to inhibit germination by 50% were 51 to 73 mM and −0.27 MPa, respectively. Seedling emergence was completely inhibited by burial of seed, which is consistent with its absolute requirement for light exposure to begin germination. Under field conditions, there was no clear effect of burial depth on seed viability in the first 2 yr with average rainfall, and seeds were completely nonviable after 12 mo. However, in the third year, with low spring–summer rainfall, buried seeds (37% viability after 14 mo) persisted longer than those left on the soil surface (6% viability after 14 mo). This study provides important information on plant development and seed biology of windmillgrass that will contribute to the development of a management program for this weed species in southern Australia.

Keywords

WindmillgrassChloris truncata R. Br.Base temperaturedormancyemergencegerminationseedbank persistence
Type
Weed Biology and Ecology
Information
Weed Science , Volume 65 , Issue 3 , May 2017 , pp. 395 - 405
Copyright
© Weed Science Society of America, 2017 

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.)

Footnotes

Associate Editor for this paper: J. Anita Dille, Kansas State University.

References

Literature Cited

Adkins, S, Bellairs, S, Loch, D (2002) Seed dormancy mechanisms in warm season grass species. Euphytica 126:1320 Google Scholar
Baskin, CC, Baskin, JM (1998). Seeds: Ecology, Biogeography, and Evolution of Dormancy and Germination (2nd edn, Tokyo: Elsevier. 666 pGoogle Scholar
Batlla, D, Benech‐Arnold, RL (2014) Weed seed germination and the light environment: implications for weed management. Weed Biol Manag 14:7787 Google Scholar
Benvenuti, S (1995) Soil light penetration and dormancy of jimsonweed (Datura stramonium) seeds. Weed Sci 43:389393 Google Scholar
Bhowmik, PC (1997) Weed biology: importance to weed management. Weed Sci 45:349356 Google Scholar
Borger, CPD, Riethmuller, G, Hashem, A (2010) Control of windmill grass over the summer fallow increases wheat yield. Pages 48--51 in Zydenbos SM, ed. 17th Australasian Weeds Conference: New Frontiers in New Zealand: Together We Can Beat the Weeds. September 26–30, 2010. Christchurch, New Zealand: New Zealand Plant Protection SocietyGoogle Scholar
Borger, CPD, Riethmuller, GP, Hashem, A (2011) Emergence, survival, biomass production, and seed production of Chloris truncata (windmill grass) in the Western Australian wheatbelt. Crop Pasture Sci 62:678685 Google Scholar
Boutsalis, P, Gill, GS, Preston, C (2012) Incidence of herbicide resistance in rigid ryegrass (Lolium rigidum) across southeastern Australia. Weed Technol 26:391398 CrossRefGoogle Scholar
Chachalis, D, Reddy, KN (2000) Factors affecting Campsis radicans seed germination and seedling emergence. Weed Sci 48:212216 Google Scholar
Chauhan, BS, Gill, G, Preston, C (2006a) Factors affecting seed germination of annual sowthistle (Sonchus oleraceus) in southern Australia. Weed Sci 54:854860 Google Scholar
Chauhan, BS, Gill, G, Preston, C (2006b) Influence of environmental factors on seed germination and seedling emergence of rigid ryegrass (Lolium rigidum). Weed Sci 54:10041012 Google Scholar
Cousens, R, Mortimer, M (1995) Dynamics of Weed Populations. Cambridge, UK: Cambridge University Press. 332 pGoogle Scholar
Cussans, G, Raudonius, S, Brain, P, Cumberworth, S (1996) Effects of depth of seed burial and soil aggregate size on seedling emergence of Alopecurus myosuroides, Galium aparine, Stellaria media and wheat. Weed Res 36:133141 Google Scholar
Farley, GJ, Bellairs, SM, Adkins, SW (2013) Germination of selected Australian native grass species, with potential for minesite rehabilitation. Aust J Bot 61:283290 CrossRefGoogle Scholar
Grime, J, Mason, G, Curtis, A, Rodman, J, Band, S (1981) A comparative study of germination characteristics in a local flora. J Ecol 69:10171059 Google Scholar
Kleemann, SGL, Preston, C, Gill, GS (2016) Influence of management on long-term seedbank dynamics of rigid ryegrass (Lolium rigidum) in cropping systems of southern Australia. Weed Sci 64:303311 Google Scholar
Kloot, PM (1985) The spread of native Australian plants as weeds in South Australia and in other Mediterranean regions. J Adel Bot Gard 7:145157 Google Scholar
Koger, CH, Reddy, KN, Poston, DH (2004) Factors affecting seed germination, seedling emergence, and survival of texasweed (Caperonia palustris). Weed Sci 52:989995 Google Scholar
Llewellyn, R, Ronning, D, Ouzman, J, Walker, S, Mayfield, A, Clarke, M (2016) Impact of Weeds on Australian Grain Production: The Cost of Weeds to Australian Grain Growers and the Adoption of Weed Management and Tillage Practices. Kingston, ACT, Australia: Grains Research and Development Corporation (GRDC). 112 pGoogle Scholar
Lodge, G, Whalley, R (1981) Establishment of warm- and cool-season native perennial grasses on the north-west slopes of New South Wales. I. dormancy and germination. Aust J Bot 29:111119 Google Scholar
Machado, ECR, Lima, RSO, Silva, APP, Marques, BS, Goncalves, MF, Carvalho, SJP (2014) Initial growth and development of southern sandbur based on thermal units. Planta Daninha 32:335343 Google Scholar
Malone, J, Cook, A, Wu, H, Hashem, A, Preston, C (2012) Management of glyphosate resistant weeds in non-agricultural areas. Developing solutions to evolving weed problems. 18th Australasian Weeds Conference. October 8–11, 2012. Melbourne, VIC, AustraliaGoogle Scholar
Masin, R, Zuin, MC, Archer, DW, Forcella, F, Zanin, G (2005) Weedturf: a predictive model to aid control of annual summer weeds in turf. Weed Sci 53:193201 Google Scholar
Matthews, J (1994) Management of herbicide resistant weed populations. Pages 317335 in Powles S & Holtum J eds, Herbicide Resistance in Plants: Biology and Biochemistry. Boca Raton, FL: CRC Google Scholar
Maze, KM, Koen, TB, Watt, LA (1993) Factors influencing the germination of six perennial grasses of central New South Wales. Aust J Bot 41:7990 CrossRefGoogle Scholar
Mennan, H, Ngouajio, M (2006) Seasonal cycles in germination and seedling emergence of summer and winter populations of catchweed bedstraw (Galium aparine) and wild mustard (Brassica kaber). Weed Sci 54:114120 Google Scholar
Michael, PJ, Borger, CP, MacLeod, WJ, Payne, PL (2010a)Occurrence of summer fallow weeds within the grain belt region of southwestern Australia. Weed Technol 24:562568 Google Scholar
Michael, PJ, Yeoh, PB, Scott, JK (2010b) Potential climate change impacts on agricultural weeds in the northern agricultural region of Western Australia. Pages 74--75 in Zydenbos SM, ed. 17th Australasian Weeds Conference: New Frontiers in New Zealand: Together We Can Beat the Weeds. September 26–30, 2010. Christchurch, New Zealand: New Zealand Plant Protection SocietyGoogle Scholar
Michael, PJ, Yeoh, PB, Scott, JK (2012a) The current and future projected distribution of Solanum hoplopetalum (Solanaceae): an indigenous weed of the south-western Australian grain belt. Aust J Bot 60:128135 Google Scholar
Michael, PJ, Yeoh, PB, Scott, JK (2012b) Potential distribution of the Australian native Chloris truncata based on modelling both the successful and failed global introductions. PLoS One 7:e42140 CrossRefGoogle ScholarPubMed
Michel, BE (1983) Evaluation of the water potentials of solutions of polyethylene glycol 8000 both in the absence and presence of other solutes. Plant Physiol 72:6670 Google Scholar
Milberg, P, Andersson, L, Thompson, K (2000) Large-seeded spices are less dependent on light for germination than small-seeded ones. Seed Sci Res 10:99104 Google Scholar
Mitchell, M (1994) Native Grasses: An Identification Handbook for Temperate Australia. Collingwood, VIC, Australia: Landlinks. 41 pGoogle Scholar
Nightingale, ME, Lazarides, M, Weiller, CM (2005) Flora of Australia Vol. 44B, Poaceae 3, Melbourne: ABRS/CSIRO Google Scholar
Osten, V, Hashem, A, Koetz, E, Lemerle, D, Pathan, S, Wright, G (2006) Impacts of summer fallow weeds on soil nitrogen and wheat in the southern, western and northern Australian grain regions. Pages 395–398 in Preston C, Watts JH, Crossman ND, eds. 15th Australian Weeds Conference: Managing Weeds in a Changing Climate. Adelaide, SA, Australia: Weed Management Society of South AustraliaGoogle Scholar
Preston, C (2016) Glyphosate Resistant Weeds in Australia. http://glyphosateresistance.org.au/register_summary.html. Accessed: October 20, 2016Google Scholar
Saatkamp, A, Affre, L, Dutoit, T, Poschlod, P (2009) The seed bank longevity index revisited: limited reliability evident from a burial experiment and database analyses. Ann Bot 104:715724 CrossRefGoogle ScholarPubMed
Schutte, B, Tomasek, B, Davis, A, Andersson, L, Benoit, D, Cirujeda, A, Dekker, J, Forcella, F, Gonzalez‐Andujar, J, Graziani, F (2014) An investigation to enhance understanding of the stimulation of weed seedling emergence by soil disturbance. Weed Res 54:112 CrossRefGoogle Scholar
Simpson, GM (1990) The occurrence of dormancy in the Gramineae (Pages 359 in Seed Dormancy in Grasses, New York: Cambridge University Press Google Scholar
Steinmaus, SJ, Prather, TS, Holt, JS (2000) Estimation of base temperatures for nine weed species. J Exp Bot 51:275286 Google Scholar
Werth, J, Boucher, L, Thornby, D, Walker, S, Charles, G (2013) Changes in weed species since the introduction of glyphosate-resistant cotton. Crop Pasture Sci 64:791798 Google Scholar
Widderick, M, Cook, T, McLean, A, Churchett, J, Keenan, M, Miller, B, Davidson, B (2014) Improved management of key northern region weeds: diverse problems, diverse solutions. Pages 312–315 in Baker M, ed. 19th Australasian Weeds Conference: Science, Community and Food Security: The Weed Challenge. Hobart, TAS, Australia: Tasmanian Weed SocietyGoogle Scholar