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Factors Affecting Seed Germination of Feather Fingergrass (Chloris virgata)

Published online by Cambridge University Press:  20 January 2017

Nimesha Fernando*
Affiliation:
Centre for Environmental Management, Faculty of Science and Technology, Federation University Australia, Mt. Helen, Victoria 3350, Australia
Talia Humphries
Affiliation:
Centre for Environmental Management, Faculty of Science and Technology, Federation University Australia, Mt. Helen, Victoria 3350, Australia
Singarayer K. Florentine
Affiliation:
Centre for Environmental Management, Faculty of Science and Technology, Federation University Australia, Mt. Helen, Victoria 3350, Australia
Bhagirath S. Chauhan
Affiliation:
The Centre for Plant Science, Queensland Alliance for Agriculture and Food Innovation (QAAFI), The University of Queensland, Toowoomba, Queensland 4350, Australia
*
Corresponding author's E-mail: [email protected]

Abstract

Laboratory experiments were carried out to determine the effect of several environmental factors on seed germination of feather fingergrass, one of the most significant emerging weeds in warm regions of the world. Seed germination occurred over a broad range of temperatures (17/7, 25/10, and 30/20 C), but germination being highest at alternating temperatures of 30/20 C under both 12 h light/12 h dark and 24 h dark conditions. Although seed germination was favored by light, some seeds were capable of germinating in the dark. Increasing salt stress decreased seed germination until complete inhibition was reached at 250-mM sodium chloride. Germination decreased from 64 to 0.7% as osmotic potential decreased from 0 to −0.4 MPa, and was completely inhibited at −0.6 MPa. Higher seed germination (> 73%) was observed in the range of pH 6.4 to 8 than the other tested pH levels. Heat shock had a significant effect on seed germination. Germination of seeds placed at 130 C for 5 min was completely inhibited for both dry and presoaked seeds. The results of this study will help to develop protocols for managing feather fingergrass, and to thus avoid its establishment as a troublesome weed in economically important cropping regions.

Type
Weed Biology and Ecology
Copyright
Copyright © 2016 by the Weed Science Society of America 

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Footnotes

Associate editor for this paper: Hilary Sandler, University of Massachusetts.

References

Literature Cited

Batlla, D, Luis, RB (2014) Weed seed germination and the light environment: Implications for weed management Weed Biol Manage 14:7787 Google Scholar
Bewley, JD, Black, M (1994) Physiology of Development and Germination. Pages 259262 in Seeds: The Language of Science. 2nd edn. New York: Plenum Press Academic.Google Scholar
Chachalis, D, Reddy, KN (2000) Factors affecting Campsis radicans seed germination and seedling emergence Weed Sci 48:212216 Google Scholar
Chauhan, BS, Johnson, DE (2008a) Influence of environmental factors on seed germination and seedling emergence of eclipta (Eclipta prostrata) in a tropical environment Weed Sci 56:383388 Google Scholar
Chauhan, BS, Johnson, DE (2008b) Germination ecology of Chinese sprangletop (Leptochloa chinensis) in the Philippines Weed Sci 56:820825 Google Scholar
Chauhan, BS, Johnson, DE (2009) Seed germination ecology of junglerice (Echinochloa colona) : a major weed of rice Weed Sci 57:235240 Google Scholar
Ferrari, FN, Parera, CA (2015) Germination of six native perennial grasses that can be used as potential soil cover crops in drip-irrigated vineyards in semiarid environs of Argentina J Arid Environ 113:15 Google Scholar
Ghebrehiwot, HM, Kulkarni, MG, Kirkman, KP, Staden, J (2012) Smoke and heat: influence on seedling emergence from the germinable soil seed bank of mesic grassland in South Africa Plant Growth Reg 66:119127 Google Scholar
Górski, T, Górska, K (1979) Inhibitory effects of full daylight on the germination of Lactuca sativa Planta 144:121124 Google Scholar
Halvorson, WL, Guertin, P (2003) Factsheet for Chloris virgata SW. Southern Arizona Data Service Program. http://www.sdrsnet.srnr.arizona.edu/data/sdrs/docs/chlovirg.pdf Google Scholar
Hawkes, JR, Jones, RAC (2005) Incidence and distribution of barley yellow dwarf virus and cereal yellow dwarf virus in oversummering grasses in a Mediterranean-type environment Aust J Agric Res 56:257270 Google Scholar
Holman, J (2009) The aphids and their host plants. Pages 244531 in Host plants catalog of aphids. Berlin: Springer Netherlands Google Scholar
Kim, S, Park, C (2008) Gibberellic acid–mediated salt signaling in seed germination Plant Signaling Behav 3:877879 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
Li, C, Fang, B, Yang, C, Shi, D, Wang, D (2009) Effects of various salt–alkaline mixed stresses on the state of mineral elements in nutrient solutions and the growth of alkali resistant halophyte Chloris virgata J Plant Nutr 32:11371147 Google Scholar
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
Osten, V (2012) Feathertop Rhodes Grass: A Best Weed Management Guide. Department of Agriculture, Fisheries and Forestry, Queensland. http://www.daff.qld.gov.au/26_10792.htm. Accessed October 24, 2015Google Scholar
Pezzani, F, Montana, C (2006) Inter- and intraspecific variation in the germination response to light quality and scarification in grasses growing in two-phase mosaics of the Chihuahuan Desert Ann Bot 97:10631071 Google Scholar
Pons, TL (2000) Seed responses to light. Pages 237260 in Fenner, M, ed. Seeds: The Ecology of Regeneration in Plant Communities. New York: CAB International Google Scholar
Rasheed, A, Hameed, A, Khan, MA, Gul, B (2015) Effects of salinity, temperature, light and dormancy regulating chemicals on seed germination of Salosla drummondii ULBR Pak J Bot 47:1119 Google Scholar
Rengasamy, P (2002) Transient salinity and subsoil constraints to dryland farming in Australian sodic soils: an overview Aust J Exp Agric 42:351361 Google Scholar
Rengasamy, P (2010) Soil processes affecting crop production in salt–affected soils Funct Plant Biol 37:613620 Google Scholar
Saatkamp, A, Affre, L, Dutoit, T, Poschlod, P (2011) Germination traits explain soil seed persistence across species: the case of Mediterranean annual plants in cereal fields Ann Bot 107:415426 Google Scholar
Waes, JM, Debergh, PC (1986) Adaptation of the tetrazolium method for testing the seed viability, and scanning electron microscopy study of some Western European orchids Physiol Planta 66:435442 Google Scholar
Walsh, M, Newman, P (2007) Burning narrow windrows for weed seeds destrcution Field Crop Res 104:2430 Google Scholar
Walsh, M, Newman, P, Stephen, P (2013) Targeting weed seeds in-crop: A new weed control paradigm for global agriculture Weed Technol 27:431436 Google Scholar
Yang, CW, Zhang, ML, Liu, J, Shi, DC, Wang, DL (2009) Effects of buffer capacity on growth, photosynthesis, and solute accumulation of a glycophyte (wheat) and a halophyte (Chloris virgata). Photosynthetica 47:5560 Google Scholar
Zhang, H, Irving, LJ, Tian, Y, Zhou, D (2012) Influence of salinity and temperature on seed germination rate and the hydrotime model parameters for the halophyte, Chloris virgata, and the glycophyte, Digitaria sanguinalis South Afr J Bot 78:203210 Google Scholar