Hostname: page-component-78c5997874-4rdpn Total loading time: 0 Render date: 2024-11-05T21:25:53.288Z Has data issue: false hasContentIssue false

Wind-mediated seed dispersal of invasive forage grasses from agricultural grasslands in Hokkaido, Japan

Published online by Cambridge University Press:  28 May 2019

Chika Egawa*
Affiliation:
Researcher, Institute for Agro-Environmental Sciences, National Agriculture and Food Research Organization, Ibaraki, Japan
Atsushi Shoji
Affiliation:
Principal Researcher, Hokkaido Agricultural Research Center, National Agriculture and Food Research Organization, Sapporo, Japan
Hiroyuki Shibaike
Affiliation:
Unit Leader, Institute for Agro-Environmental Sciences, National Agriculture and Food Research Organization, Ibaraki, Japan
*
Author for correspondence: Chika Egawa, Institute for Agro-Environmental Sciences, National Agriculture and Food Research Organization, 3-1-3 Kannondai, Tsukuba 305-8604, Ibaraki, Japan. (Email: [email protected])

Abstract

Although introduced pasture grasses are essential for forage production in current livestock farming, some species cause serious impacts on native biodiversity when naturalized. Information on the seed dispersal of invasive forage grasses from cultivated settings to surrounding environments can inform management efforts to prevent their naturalization. In this case study, we quantified the wind-mediated seed dispersal distance and amount of dispersed seed of invasive forage grasses from agricultural grasslands in Hokkaido, northern Japan. In total, 200 funnel seed traps were installed around three regularly mown grasslands and one unmown grassland where various forage grass species were grown in mixture. Seeds of each species dispersed outside the grasslands were captured from May to October 2017. Based on the trapped distances of seeds, the 99th percentile dispersal distance from the grasslands was estimated for six species, including timothy (Phleum pratense L.), orchardgrass (Dactylis glomerata L.), and Kentucky bluegrass (Poa pratensis L.). For two dominant species, P. pratense and D. glomerata, the numbers of seeds dispersed outside the field under mown and unmown conditions were determined under various plant cover situations. The estimated dispersal distances ranged from 2.3 m (P. pratense) to 31.5 m (P. pratensis), suggesting that areas within approximately 32 m of the grasslands are exposed to the invasion risk of some forage grass species. For both P. pratense and D. glomerata, the number of seeds dispersed outside the unmown grassland exceeded 100 seeds m−2 under high plant cover situations, while the number of seeds dispersed from the mown grasslands at the same plant cover level was less than one-third of that number. The results suggest that local land managers focus their efforts on frequent mowing of grasslands and monitoring of the areas within approximately 32 m of the grasslands to substantially reduce the naturalization of invasive forage grasses.

Type
Case Study
Copyright
© Weed Science Society of America, 2019 

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: Steven S. Seefeldt, Washington State University

References

Asai, M (2014) Weeds of Japan in Colors. 1st ed. Tokyo: Zenkoku Nouson Kyouiku Kyokai. 357 p. JapaneseGoogle Scholar
Burnham, KP, Anderson, DR (2002) Model Selection and Multimodel Inference. 2nd ed. Heidelberg: Springer. 488 pGoogle Scholar
Cain, ML, Damman, H, Muir, A (1998) Seed dispersal and the Holocene migration of woodland herbs. Ecol Monogr 68:325347Google Scholar
Cousens, R, Dytham, C, Law, R (2008) Dispersal in Plants: A Population Perspective. 1st ed. Oxford: Oxford University Press. 221 pCrossRefGoogle Scholar
Deguchi, K (2016) Invasion of rhizomatous grasses on timothy grassland in Hokkaido. Jpn J Grassl Sci 62:153157. JapaneseGoogle Scholar
Diacon-Bolli, JC, Edwards, PJ, Bugmann, H, Scheidegger, C, Wagner, HH (2013) Quantification of plant dispersal ability within and beyond a calcareous grassland. J Veg Sci 24:10101019CrossRefGoogle Scholar
DiTommaso, A, Stokes, CA, Cordeau, S, Milbrath, LR, Whitlow, TH (2018) Seed-dispersal ability of the invasive perennial vines Vincetoxicum nigrum and Vincetoxicum rossicum. Invasive Plant Sci Manag 11:1019CrossRefGoogle Scholar
Driscoll, DA, Banks, SC, Barton, PS, Ikin, K, Lentini, P, Lindenmayer, DB, Smith, AL, Berry, LE, Burns, EL, Edworthy, A, Evans, MJ, Gibson, R, Heinsohn, R, Howland, B, Kay, G, Munro, N, Scheele, BC, Stirnemann, I, Stojanovic, D, Sweaney, N, Villaseňor, NR, Westgate, MJ (2014a) The trajectory of dispersal research in conservation biology. Systematic review. PLoS ONE 9:e95053CrossRefGoogle ScholarPubMed
Driscoll, DA, Catford, JA, Barney, JN, Hulme, PE, Inderjit, , Martin, TG, Pauchard, A, Pyšek, P, Richardson, DM, Riley, S, Visser, V (2014b) New pasture plants intensify invasive species risk. Proc Natl Acad Sci USA 111:1662216627CrossRefGoogle ScholarPubMed
Egawa, C (2017) Wind dispersal of alien plant species into remnant natural vegetation from adjacent agricultural fields. Glob Ecol Conserv 11:3341CrossRefGoogle Scholar
Ford, RH, Sharik, TL, Feret, PP (1983) Seed dispersal of the endangered Virginia round-leaf birch (Beura uber). For Ecol Manag 6:12051218CrossRefGoogle Scholar
Friedel, MH, Grice, AC, Marshall, NA, van Klinken, RD (2011) Reducing contention amongst organisations dealing with commercially valuable but invasive plants: the case of buffel grass. Environ Sci Policy 14:12051218CrossRefGoogle Scholar
Goyal, N, Sharma, GP (2016) Emerging invaders from the cultivated croplands: an invasion perspective. Pages 271290 in Rajpal, VR, Rao, SR, Raina, SN, eds. Gene Pool Diversity and Crop Improvement. Volume 1, Sustainable Development and Biodiversity. Cham: Springer International PublishingCrossRefGoogle Scholar
Grechi, I, Chadès, I, Buckley, YM, Friedel, MH, Grice, AC, Possingham, HP, Van Klinken, RD, Martin, TG (2014) A decision framework for management of conflicting production and biodiversity goals for a commercially valuable invasive species. Agric Syst 125:111CrossRefGoogle Scholar
Grice, AC (2006) Commercially valuable weeds: can we eat our cake without choking on it? Ecol Manag Restor 7:4044CrossRefGoogle Scholar
Grice, T, Friedel, M, Setterfield, S, Ferdinands, K, Clarkson, J, Rolfe, J, MacLeod, N (2011) Best Practice for Making Strategic Decisions about Invasive Plants of Commercial Value. Canberra: Rural Industries Research and Development Corporation Publication No. 11/055. 38 pGoogle Scholar
Hanada, M (2014) Measures to improve the self-sufficiency rate of forages at TMR centers. Pages 6781 in Agriculture and Livestock Industries Cooperation, ed. Joint Research Report on Contractors and TMR Centers in Hokkaido. Tokyo: Agriculture and Livestock Industries Cooperation. JapaneseGoogle Scholar
Herrmann, JD, Carlo, TA, Brudvig, LA, Damschen, EI, Haddad, NM, Levey, DJ, Orrock, JL, Tewksbury, JJ (2016) Connectivity from a different perspective: comparing seed dispersal kernels in connected vs. unfragmented landscapes. Ecology 97:12741282CrossRefGoogle ScholarPubMed
Hokkaido (2010) The Hokkaido Blue List Alien Species Database. http://bluelist.ies.hro.or.jp. Accessed: February 1, 2018. JapaneseGoogle Scholar
Hokkaido Agricultural Research Center (2017) Meteorological Observation Data in Hitsujigaoka. http://www.naro.affrc.go.jp/laboratory/harc/kisyo/month/073666.html. Accessed: January 25, 2019. JapaneseGoogle Scholar
Kleyer, M, Bekker, RM, Knevel, IC, Bakker, JP, Thompson, K, Sonnenschein, M, Poschlod, P, Van Groenendael, JM, Klimeš, L, Klimešová, J, Klotz, S, Rusch, GM, Hermy, M, Adriaens, D, Boedeltje, G, Bossuyt, B, Dannemann, A, Endels, P, Götzenberger, L, Hodgson, JG, Jackel, AK, Kühn, I, Kunzmann, D, Ozinga, WA, Römermann, C, Stadler, M, Schlegelmilch, J, Steendam, HJ, Tackenberg, O, Wilmann, B, Cornelissen, JHC, Eriksson, O, Garnier, E, Peco, B (2008) The LEDA Traitbase: a database of life-history traits of the Northwest European flora. J Ecol 96:12661274. https://uol.de/en/landeco/research/leda/. Accessed: January 25, 2019CrossRefGoogle Scholar
Kunelius, HT, MacLeod, LB, Calder, FW (1974) Effects of cutting management on yields, digestibility, crude protein, and persistence of timothy, bromegrass, and orchard grass. Can J Plant Sci 54:5564CrossRefGoogle Scholar
Lonsdale, WM (1994) Inviting trouble: introduced pasture species in northern Australia. Aust J Ecol 19:345354CrossRefGoogle Scholar
Marshall, NA, Friedel, M, van Klinken, RD, Grice, AC (2011) Considering the social dimension of invasive species: the case of buffel grass. Environ Sci Policy 14:327338CrossRefGoogle Scholar
Ministry of Agriculture, Forestry and Fisheries Japan (2018) Area Survey. http://www.maff.go.jp/j/tokei/kouhyou/sakumotu/menseki/index.html. Accessed: February 19, 2018. JapaneseGoogle Scholar
Ministry of the Environment and Ministry of Agriculture, Forestry and Fisheries Japan (2015) The List of Regulated Living Organisms Under the Invasive Alien Species Act. https://www.env.go.jp/nature/intro/2outline/iaslist.html. Accessed: February 2, 2018. JapaneseGoogle Scholar
Mori, A, Hojito, M (2012) Effect of combined application of manure and fertilizer on N2O fluxes from a grassland soil in Nasu, Japan. Agric Ecosyst Environ 160:4050CrossRefGoogle Scholar
Morimoto, J, Shibata, M, Shida, Y, Nakamura, F (2017) Wetland restoration by natural succession in abandoned pastures with a degraded soil seed bank. Restor Ecol 25:10051014CrossRefGoogle Scholar
Nakayama, S, Inokuchi, M, Minamitani, T (2000) Seeds of Wild Plants in Japan. 1st ed. Sendai: Tohoku University Press. 642 p. JapaneseGoogle Scholar
Okubo, A, Levin, SA (1989) A theoretical framework for data analysis of wind dispersal of seeds and pollen. Ecology 70:329338CrossRefGoogle Scholar
Pándi, I, Penksza, K, Botta-Dukát, Z, Kröel-Dulay, G (2014) People move but cultivated plants stay: abandoned farmsteads support the persistence and spread of alien plants. Biodivers Conserv 23:12891302CrossRefGoogle Scholar
Peeters, A (2004) Wild and Sown Grasses―Profiles of a Temperate Species Selection: Ecology, Biodiversity and Use. 1st ed. Rome: Blackwell. 311 pGoogle Scholar
Quick, ZI, Houseman, GR, Büyüktahtakin, İE (2017) Assessing wind and mammals as seed dispersal vectors in an invasive legume. Weed Res 57:3543Google Scholar
Rabinowitz, D, Rapp, JK (1981) Dispersal abilities of seven sparse and common grasses from a Missouri prairie. Am J Bot 68:616624CrossRefGoogle Scholar
R Core Team (2016) R: A Language and Environment for Statistical Computing. Vienna: R Foundation for Statistical Computing. http://www.R-project.org. Accessed: October 5, 2016Google Scholar
Rew, LJ, Froud-Williams, RJ, Boatman, ND (1996) Dispersal of Bromus sterilis and Anthriscus sylvestris seed within arable field margins. Agric Ecosyst Environ 59:107114CrossRefGoogle Scholar
Scasta, JD, Engle, DM, Fuhlendorf, SD, Redfearn, DD, Bidwell, TG (2015) Meta-analysis of exotic forages as invasive plants in complex multi-functioning landscapes. Invasive Plant Sci Manag 8:292306CrossRefGoogle Scholar
Socher, SA, Prati, D, Boch, S, Müller, J, Baumbach, H, Gockel, S, Hemp, A, Schöning, I, Wells, K, Buscot, F, Kalko, EKV, Linsenmair, KE, Schulze, ED, Weisser, WW, Fischer, M (2013) Interacting effects of fertilization, mowing and grazing on plant species diversity of 1500 grasslands in Germany differ between regions. Basic Appl Ecol 14:126136CrossRefGoogle Scholar
Soons, MB, Bullock, JM (2008) Non-random seed abscission, long-distance wind dispersal and plant migration rates. J Ecol 96:581590CrossRefGoogle Scholar
Soons, MB, Ozinga, WA (2005) How important is long-distance seed dispersal for the regional survival of plant species? Divers Distrib 11:165172Google Scholar
Stone, KR (2010) Schedonorus pratensis. Fire Effects Information System, U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory. https://www.fs.fed.us/database/feis/plants/graminoid/schpra/all.html. Accessed: February 4, 2019Google Scholar
Takeda, Y (2004) Grassland productivity and renovation in Hokkaido. Jpn J Grassl Sci 50:7582. JapaneseGoogle Scholar
Tamme, R, Götzenberger, L, Zobel, M, Bullock, JM, Hooftman, DAP, Kaasik, A, Pärtel, M (2014) Predicting species’ maximum dispersal distances from simple plant traits. Ecology 95:505513CrossRefGoogle ScholarPubMed
Treep, J, de Jager, M, Kuiper, LS, Duman, T, Katul, GG, Soons, MB (2018) Costs and benefits of non-random seed release for long-distance dispersal in wind-dispersed plant species. Oikos 127:13301343CrossRefGoogle Scholar
Tsuyuzaki, S, Kanda, F, Narita, K (1994) Revegetation patterns on abandoned pasture in northern Japan. Acta Oecol 15:461467Google Scholar
Wilkins, PW, Humphreys, MO (2003) Progress in breeding perennial forage grasses for temperate agriculture. J Agric Sci 140:129150CrossRefGoogle Scholar
Yamada, T (2009) Forage crops. Pages 6890 in Iwata, K, Uchino, H, Gopal, J, eds. Agriculture in Hokkaido. Sapporo: Hokkaido UniversityGoogle Scholar
Supplementary material: File

Egawa et al. supplementary material

Figure S1 and Table S1

Download Egawa et al. supplementary material(File)
File 61.2 KB