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Seed longevity and germination in response to changing drought and heat conditions on four populations of the invasive weed African lovegrass (Eragrostis curvula)

Published online by Cambridge University Press:  20 April 2021

Jason Roberts
Affiliation:
BSc (Honours) Graduate, Future Regions Research Centre, School of Science, Psychology and Sport, Federation University, Mount Helen, Victoria, Australia
Singarayer Florentine*
Affiliation:
Professor, Future Regions Research Centre, School of Science, Psychology and Sport, Federation University, Mount Helen, Victoria, Australia
Eddie van Etten
Affiliation:
Senior Researcher, Centre for Ecosystem Management, School of Science, Edith Cowan University, Joondalup, Western Australia, Australia
Christopher Turville
Affiliation:
Senior Researcher, School of Engineering, Information Technology and Physical Sciences, Federation University, Mount Helen, Victoria, Australia
*
Author for correspondence: Singarayer Florentine, Future Regions Research Centre, School of Science, Psychology and Sport, Federation University, Mount Helen, VIC3350, Australia. (Email: [email protected])

Abstract

African lovegrass [Eragrostis curvula (Schrad.) Nees] is an invasive weed that is threatening biodiversity around the world and will continue to do so unless its efficient management is achieved. Consequently, laboratory and field-based experiments were performed to analyze several measures of germination to determine the effect of drought stress, radiant heat stress, and burial depth and duration (longevity) on E. curvula seeds. This study investigated seeds from four spatially varied populations across Australia: Maffra and Shepparton, VIC; Tenterfield, NSW; and Midvale, WA. Results showed that increasing drought stress reduced and slowed germination for all populations. Maffra (24% vs. 83%) and Shepparton (41% vs. 74%) were reduced at the osmotic potential of ≤−0.4 MPa, while Tenterfield (35% vs. 98.6%) and Midvale (32% vs. 91%) were reduced at ≤−0.6 MPa, compared with the mean of all other osmotic potentials. Radiant heat at 100 C significantly reduced and slowed germination compared with 40 C for Tenterfield (62% vs. 100%), Shepparton (15% vs. 89%), and Midvale (41% vs. 100%), while Maffra (75% vs. 86%) had consistent germination. For the effect of burial depth and duration (longevity), there was no significant difference across the 14-mo period; however, the 0-cm burial depth had a significantly lower final germination percentage compared with depths of 3, 5, and 10 cm (24% vs. 55%). Although each trial was conducted independently, the results can be used to help identify efficient control measures to reduce infesting populations. Recommended measures include using soil moisture monitoring to detect which conditions will promote germination, as germination is encouraged when the osmotic potential is >−0.6 MPa; exposing seeds to radiant heat (>100 C) using methods such as prescribed burning; and limiting soil disturbance over time to reduce seed establishment.

Type
Research Article
Copyright
© The Author(s), 2021. Published by Cambridge University Press on behalf of the Weed Science Society of America

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Footnotes

Associate Editor: Vipan Kumar, Kansas State University

References

Ahmed, S, Opeña, JL, Chauhan, BS (2015) Seed germination ecology of doveweed (Murdannia nudiflora) and its implication for management in dry-seeded rice. Weed Sci 63:491501 CrossRefGoogle Scholar
Archibald, S, Bond, WJ, Stock, WD, Fairbanks, DHK (2005) Shaping the landscape: fire-grazer interactions in an African savanna. Ecol Appl 15:96109 CrossRefGoogle Scholar
Baskin, CC, Baskin, JM (2014) Seeds: Ecology, Biogeography and Evolution of Dormancy and Germination. San Diego: Elsevier Science. 1600 p Google Scholar
Bureau of Meteorology (2020) Climate Data Online, Bureau of Meteorology. http://www.bom.gov.au/climate/data. Accessed: May 20, 2020Google Scholar
Chauhan, BS (2013) Seed germination ecology of feather lovegrass [Eragrostis tenella (L.) Beauv. ex Roemer & J.A Schultes]. PLoS ONE 8:e79398 CrossRefGoogle Scholar
Clarke, S, French, K (2005) Germination response to heat and smoke of 22 Poaceae species from grassy woodlands. Aust J Bot 53:445454 CrossRefGoogle Scholar
Csurhes, S, Leigh, C, Walton, C (2016) African Lovegrass (Eragrostis curvula) (Invasive Plant Risk Assessment). Queensland, Australia: Department of Agriculture and Fisheries, Biosecurity Queensland. 20 p Google Scholar
Donohue, K, Casas, RRD, Burghardt, L, Kovach, K, Willis, CG (2010) Germination, post germination, adaption and species ecology ranges. Annu Rev Ecol Evol Syst 41:293319 CrossRefGoogle Scholar
Ekwealor, KU, Echereme, CB, Ofobeze, TN, Okereke, CN (2019) Economic importance of weeds: a review. Asian J Plant Sci 3:111 Google Scholar
Escudero, A, Nunez, Y, Perez-Garcials, F (2000) Fire a selective force of seed size in pine species? Acta Oecol 21:245256 CrossRefGoogle Scholar
Fenner, M, Thompson, K (2005) The Ecology of Seeds. Cambridge, UK: Cambridge University Press. 260 p CrossRefGoogle Scholar
Ferrari, FN, Parera, CA (2015) Germination of six native perennial grasses that can be used as potential soil cover in drip-irrigated vineyards in semiarid environs of Argentina. J Arid Environ 113:15 CrossRefGoogle Scholar
Fichino, BS, Dombroski, JRG, Pivello, VR, Fidelis, A (2016) Does fire trigger seed germination in the Neotropical savannas? Experimental tests with six Cerrado species. Biotropica 48:181187 CrossRefGoogle Scholar
Firn, J (2009) African lovegrass in Australia: a valuable pasture species or embarrassing invader? Trop Grassl 43:8697 Google Scholar
Firn, J, House, APN, Buckley, YM (2010) Alternative states models provide an effective framework for invasive species control and restoration of native communities. J Appl Ecol 47:96105 CrossRefGoogle Scholar
Firn, J, Ladouceur, E, Dorrough, J (2018) Integrating local knowledge and research to refine the management of an invasive non-native grass in critically endangered grassy woodlands. J Appl Ecol 55:321330 CrossRefGoogle Scholar
Ghebrehiwot, HM, Aremu, AO, Van Staden, J (2014) Evaluation of the allelopathic potential of five South African mesic grassland species. Plant Growth Regul 72:155162 CrossRefGoogle Scholar
Haswell, ES, Verslues, PE (2015) The ongoing search for the molecular basis of plant osmosensing. J Gen Physiol 145: 389394 CrossRefGoogle ScholarPubMed
Johnson, DP, Catford, JA, Driscoll, DA, Gibbons, P (2018) Seed addition and biomass removal key to restoring native forbs in degraded temperate grassland. Appl Veg Sci 21:219228 CrossRefGoogle Scholar
Kader, MA (2005) A comparison of seed germination calculation formulae and associated interpretation of resulting data. J Proc R Soc NSW 138:6575 Google Scholar
Leigh, JH, Davidson, RL (1968) Eragrostis curvula (Schrad) Nees and some other African lovegrasses. Plant Intro Rev 5:2146 Google Scholar
Li, D, Liu, H, Qiao, Y, Wang, Y, Cai, Z, Dong, B, Shi, C, Liu, Y, Li, X, Liu, M (2013) Effects of elevated CO2 on the growth, seed yield and water efficiency of soybean (Glycine max (L.) Merr.) under drought stress. Agric Water Manag 129:105112 CrossRefGoogle Scholar
McFarland, JB, Mitchell, R (2000) Fire effects on weeping lovegrass tiller density and demographics. Agron J 92:4247 CrossRefGoogle Scholar
Medeiros, RB, Focht, T, Menegon, LL, Freitas, MR (2014) Seed longevity of Eragrostis plana Nees buried in natural grassland soil. R Bras Zootec 43: 561567 CrossRefGoogle Scholar
Moreira, B, Pausas, JG (2012) Tanned or burned: the role of fire in shaping physical seed dormancy. PLoS ONE 7:e51523.CrossRefGoogle ScholarPubMed
Musso, C, Miranda, HS, Aires, SS, Bastos, AC, Soares, AMVM, Loureiro, S (2015) Simulated post-fire temperature affects germination of native and invasive grasses in Cerrado (Brazilian savanna). Plant Ecol Divers 8:219227 CrossRefGoogle Scholar
Nechet, KL, Vitorino, MD, Vieira, BS, Halfeld-Vieira, BA (2019) Weeds. Pages 437450 in Souza, B, Vazquez, LL, Marucci, RC, eds. National Enemies of Insect Pests in Neotropical Agroecosystems. Cham, Switzerland: Springer CrossRefGoogle Scholar
Nguyen, T, Keizer, P, Van Eeuwijk, F, Smeekens, S, Bentsink, L (2012) Natural variation for seed longevity and seed dormancy are negatively correlated in Arabidopsis . Plant Physiol 160:20832092 CrossRefGoogle ScholarPubMed
Roberts, J (2020) Germination Biology of Four Climatically Varied Populations of the Globally Invasive Species Eragrostis curvula [Schrad. Nees] (African Lovegrass). Unpublished honors thesis. Mount Helen, VIC: Federation University Australia. Pp 36–38Google Scholar
Rodrigo, JM, Zappacosta, DC, Selva, JP, Garbus, I, Albertini, E, Echenique, V (2017) Apomixis frequency under stress conditions in weeping lovegrass (Eragrostis curvula). PLoS ONE 12:e0175852 CrossRefGoogle Scholar
Ruttledge, A, Whalley, RDB, Falzon, G, Backhouse, D, Sindel, BM (2020) The role of soil temperature and seed dormancy in the creation and maintenance of persistent seed banks of Nassella trichotoma (serrated tussock) on the Northern Tablelands of New South Wales. Rangeland J 42:8595 CrossRefGoogle Scholar
Santana, VM, Bradstock, RA, Ooi, MKJ, Denham, AJ, Auld, TD, Baeza, MJ (2010) Effects of soil temperature regimes after fire on seed dormancy and germination in six Australian Fabaceae species. Aus J Bot 58:539545 CrossRefGoogle Scholar
Schoffl, F, Prandl, R, Reindl, A (1999) Molecular responses to heat stress. Pages 8198 in Shinozaki, K, Yamaguchi-Shinozaki, K, ed. Molecular Responses to Cold, Drought, Heat and Salt Stress in Higher Plants. Austin, TX: R. G. Landes Google Scholar
Seglias, AE, Williams, E, Bilge, A, Kramer, AT (2018) Phylogeny and source climate impact seed dormancy and germination of restoration-relevant forb species. PLoS ONE 13:e0191931 CrossRefGoogle ScholarPubMed
Selva, JP, Zappacosta, D, Carballo, J, Rodrigo, JM, Bellido, A, Gallo, CA, Echenique, V (2020) Genes modulating the increase in sexuality in the facultative diplosporous grass Eragrostis curvula under water stress conditions. Genes 11: 969 CrossRefGoogle ScholarPubMed
Trabaud, L (1980) Fire as an agent of plant invasion? A case study in the French Mediterranean vegetation. Pages 417437 In Biological Invasions in Europe and the Mediterranean Basin. Vienna: Springer Google Scholar
Van den Berg, L, Zeng, YJ (2006) Response of South African indigenous grass species to drought stress induced by polyethylene glycol (PEG) 6000. S Afr J Bot 72:284286 CrossRefGoogle Scholar
Verslues, PE, Bray, EA (2004) LWR1 and LWR2 are required for osmoregulation and osmotic adjustment in Arabidopsis . Plant Physiol 36:28312842 CrossRefGoogle 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 CrossRefGoogle Scholar
Walters, C, Dear, B, Hackney, B, Jessop, P, Melville, G (2008) Trangie wallaby grass [Austrodanthonia caespitosa (Gaudich.) H.P. Linder]. Aust J Exp Agric 48:575577 CrossRefGoogle Scholar
Wang, A, Gopurenko, D, Wu, H, Lepschi, B (2017) Evaluation of six candidate DNA barcode loci for identification of five important invasive grasses in eastern Australia. PLoS ONE 12:e0175338 CrossRefGoogle ScholarPubMed
Williams, D (2012) African Love Grass (Eragrostis curvula): Interim Best Practice Manual. Gippsland, Australia: East Gippsland Landcare Network. Pp 1–20Google Scholar