全部 标题 作者
关键词 摘要

OALib Journal期刊
ISSN: 2333-9721
费用:99美元
投递稿件

查看量下载量

相关文章

更多...
PLOS ONE  2013 

Can Global Weed Assemblages Be Used to Predict Future Weeds?

DOI: 10.1371/journal.pone.0055547

Full-Text   Cite this paper   Add to My Lib

Abstract:

Predicting which plant taxa are more likely to become weeds in a region presents significant challenges to both researchers and government agencies. Often it is done in a qualitative or semi-quantitative way. In this study, we explored the potential of using the quantitative self-organising map (SOM) approach to analyse global weed assemblages and estimate likelihoods of plant taxa becoming weeds before and after they have been moved to a new region. The SOM approach examines plant taxa associations by analysing where a taxon is recorded as a weed and what other taxa are recorded as weeds in those regions. The dataset analysed was extracted from a pre-existing, extensive worldwide database of plant taxa recorded as weeds or other related status and, following reformatting, included 187 regions and 6690 plant taxa. To assess the value of the SOM approach we selected Australia as a case study. We found that the key and most important limitation in using such analytical approach lies with the dataset used. The classification of a taxon as a weed in the literature is not often based on actual data that document the economic, environmental and/or social impact of the taxon, but mostly based on human perceptions that the taxon is troublesome or simply not wanted in a particular situation. The adoption of consistent and objective criteria that incorporate a standardized approach for impact assessment of plant taxa will be necessary to develop a new global database suitable to make predictions regarding weediness using methods like SOM. It may however, be more realistic to opt for a classification system that focuses on the invasive characteristics of plant taxa without any inference to impacts, which to be defined would require some level of research to avoid bias from human perceptions and value systems.

 References

[1]  Mack RN, Lonsdale WM (2001) Humans as global plant dispersers: Getting more than we bargained for. Bioscience 51: 95–102.
[2]  Hulme PE (2009) Trade, transport and trouble: managing invasive species pathways in an era of globalisation. Journal of Applied Ecology 46: 10–18.
[3]  Lambdon PW, Py?ek P, Basnou C, Hejda M, Arianoutsou M, et al. (2008) Alien flora of Europe: species diversity, temporal trends, geographical patterns and research needs. Preslia 80: 101–149.
[4]  Richardson DM, Py?ek P, Rejmánek M, Barbour MG, Panetta FD, et al. (2000) Naturalization and invasion of alien plants: concepts and definitions. Diversity and Distributions 6: 93–107.
[5]  Py?ek P, Richardson DM, Rejmánek M, Webster GL, Williamson M, et al. (2004) Alien plants in checklists and floras: Towards better communication between taxonomists and ecologists. Taxon 53: 131–143.
[6]  Oerke EC (2006) Crop losses to pests. Journal of Agricultural Science 144: 31–43.
[7]  Vilà M, Espinar JL, Hejda M, Hulme PE, Jaro?ík V, et al. (2011) Ecological impacts of invasive alien plants: a meta-analysis of their effects on species, communities and ecosystems. Ecology Letters 14: 702–708.
[8]  Binns JA, Illgner PM, Nel EL (2001) Water shortage, deforestation and development: South Africa's Working for Water programme. Land Degradation and Development 12: 341–355.
[9]  Pimentel D, Zuniga R, Morrison D (2005) Update on the environmental and economic costs associated with alien-invasive species in the United States. Ecological Economics 52: 273–288.
[10]  Sinden J, Jones R, Hester S, Odom D, Kalisch D, et al. (2005) The economic impact of weeds in Australia. Plant Protection Quarterly 20: 25–32.
[11]  Cunningham DC, Barry SC, Woldendorp G, Burgess MB (2004) A framework for prioritizing sleeper weeds for eradication. Weed Technology 18: 1189–1193.
[12]  Groves RH (2006) Are some weeds sleeping? Some concepts and reasons. Euphytica 148: 111–120.
[13]  Mack RN, Simberloff D, Lonsdale WM, Evans H, Clout M, et al. (2000) Biotic invasions: Causes, epidemiology, global consequences and control. Ecological Applications 10: 689–710.
[14]  Richardson DM, Py?ek P (2006) Plant invasions: merging the concepts of species invasiveness and community invasibility. Progress in Physical Geography 30: 409–431.
[15]  Rejmánek M, Richardson DM (1996) What attributes make some plant species more invasive? Ecology 77: 1655–1661.
[16]  Hayes KR, Barry SC (2008) Are there any consistent predictions of invasion success? Biological Invasions 10: 483–506.
[17]  Thompson K, Davis MA (2011) Why research on traits of invasive plants tells us very little. Trends in Ecology and Evolution 26: 155–156.
[18]  Heikkil? J (2011) A review of risk prioritisation schemes of pathogens, pests and weeds: principles and practices. Agricultural and Food Science 20: 15–28.
[19]  Roberts W, Harrod O, Mitterdorfer B, Pheloung P (2011) Regulating invasive plants and use of weed risk assessments. Current Opinion in Environmental Sustainability 3: 60–65.
[20]  Hulme PE (2012) Weed risk assessment: a way forward or a waste of time? Journal of Applied Ecology 49: 10–19.
[21]  Pheloung PC, Williams PA, Halloy SR (1999) A weed risk assessment model for use as a biosecurity tool evaluating plant introductions. Journal of Environmental Management 57: 239–251.
[22]  Daehler CC, Carino DA (2000) Predicting invasive plants: prospects for a general screening system based on current regional models. Biological Invasions 2: 93–102.
[23]  Gordon DR, Onderdonk DA, Fox AM, Stocker RK (2008) Consistent accuracy of the Australian weed risk assessment system across varied geographies. Diversity and Distribution 14: 234–242.
[24]  McClay A, Sissons A, Wilson C, Davis S (2010) Evaluation of the Australian weed risk assessment system for the prediction of plant invasiveness in Canada. Biological Invasions 12: 4085–4098.
[25]  Smith CS, Lonsdale WM, Fortune J (1999) When to ignore advice: invasion predictions and decision theory. Biological Invasions 1: 89–96.
[26]  Caley P, Lonsdale WM, Pheloung PC (2006) Quantifying uncertainty in predictions of invasiveness, with emphasis on weed risk assessment. Biological Invasions 8: 1595–1604.
[27]  National Weed Risk Assessment System Review Group (2006) Review of the National Weed Risk Assessment System. Canberra, Australia: Natural Resource Management Standing Committee/Primary Industries Standing Committee Sub-Committee. Available: http://www.weeds.org.au/docs/Review_of_t?he_National_Weed_Risk_Assessmt_System_20?05.pdf. Accessed 11 April 2012.
[28]  Cousens R (2008) Risk assessment of potential biofuel species: An application for trait-based models for predicting weediness? Weed Science 56: 873–882.
[29]  Weber J, Panetta FD, Virtue J, Pheloung P (2009) An evaluation of eight years' data from the Australian border weed risk assessment system. Journal of Environmental Management 90: 798–807.
[30]  Lonsdale WM, Fitzgibbon F (2011) The known unknowns – managing the invasion risk from biofuels. Current Opinion in Environmental Sustainability 3: 31–35.
[31]  Groves RH, Hosking JR, Batianoff GN, Cooke DA, Cowie ID, et al. (2003) Weed categories for natural and agricultural ecosystem management. Canberra: Bureau of Rural Sciences.
[32]  Virtue JG, Spencer RD, Weiss JE, Reichard SE (2008) Australia's botanic gardens weed risk assessment procedure. Plant Protection Quarterly 23: 166–178.
[33]  Burgman M (2005) Risks and decisions for conservation and environmental management. Cambridge: Cambridge University Press.
[34]  Cereghino R, Santoul F, Compin A, Mastrorillo S (2005) Using self-organizing maps to investigate spatial patterns of non-native species. Biological Conservation 125: 459–465.
[35]  Worner SP, Gevrey M (2006) Modelling global insect pest species assemblages to determine risk of invasion. Journal of Applied Ecology 43: 858–867.
[36]  Paini DR, Worner S, Cook DC, De Barro PJ, Thomas MB (2010) Threat of invasive pests from within national borders. Nature Communications 1: 115 doi:10.1038/ncomms1118.
[37]  Paini DR, Worner SP, Cook DC, De Barro PJ, Thomas MB (2010) Using a self-organising map to predict invasive species: sensitivity to data errors and a comparison with expert opinion. Journal of Applied Ecology 47: 290–298.
[38]  Paini DR, Bianchi FJJA, Northfield TD, De Barro PJ (2011) Predicting invasive fungal pathogens using invasive pest assemblages: Testing model predictions in a virtual world. PLoS ONE 6(10): e25695 doi:10.1371/journal.pone.0025695.
[39]  Randall RP (2009) Plants Database. Department of Agriculture and Food, Western Australia (Unpublished data).
[40]  Randall R.P. (2012) A Global Compendium of Weeds. 2nd Edition. Perth: Department of Agriculture and Food, Western Australia. Available: http://www.agric.wa.gov.au/objtwr/import?ed_assets/content/pw/weed/global-compend?ium-weeds.pdf. Accessed 1 November 2012.
[41]  Py?ek P, Jaro?ík V, Pergl J, Randall R, Chytry M, et al. (2009) The global invasion success of Central European plants is related to distribution characteristics in their native range and species traits. Diversity and Distribution 15: 891–903.
[42]  Diez JM, Williams PA, Randall RP, Sullivan JJ, Hulme PE, et al. (2009) Learning from failures: testing broad taxonomic hypotheses about plant naturalization. Ecology Letters 12: 1174–1183.
[43]  United Nations Statistics Division (2011) Composition of macro geographical (continental) regions, geographical sub-regions, and selected economic and other groupings. United Nations. Available: http://millenniumindicators.un.org/unsd/?methods/m49/m49regin.htm. Accessed 11 April 2012.
[44]  Kohonen T (2001) Self-organizing maps. Berlin: Springer.
[45]  Vesanto J, Himberg J, Alhoniemi E, Parhankangas J (2000) SOM toolbox for Matlab 5. Helsinki University of Technology, Finland.
[46]  Mathworks (2007) MATLAB, version 7.4. Natick, MA:The Mathworks.
[47]  Categorisation Working Group (2011) National categorisation for invasive species. Australian Weeds Committee and the Vertebrate Pests Committee. Available: http://www.weeds.org.au/docs/National_Ca?tegorisation_Invasive_Species.pdf. Accessed 11 April 2012.
[48]  Standards Australia, Standards New Zealand, CRC Australian Weed Management (2006) HB 294–2006 National post-border weed risk management protocol. Sydney: Standards Australia International Ltd. and Auckland: Standards New Zealand).
[49]  Caley P, Kuhnert PM (2006) Application and evaluation of classification trees for screening unwanted plants. Austral Ecology 31: 647–655.
[50]  Randall RP (2007) The Introduced Flora of Australia and its Weed Status. Adelaide: CRC for Australian Weed Management. Available: http://www.agric.wa.gov.au/objtwr/import?ed_assets/content/hort/intro_flora_austr?alia.pdf. Accessed 1 November 2012.
[51]  L?ve D, Dansereau P (1959) Biosystematic studies on Xanthium: taxonomic appraisal and ecological status. Canadian Journal of Botany 37: 173–208.
[52]  Hocking PJ, Liddle MJ (1986) The biology of Australian weeds: 15. Xanthium occidentale Bertol. complex and Xanthium spinosum L. The Journal of the Australian Institute of Agricultural Science 52: 191–221.
[53]  Vilà M, Basnou C, Py?ek P, Josefsson M, Genovesi P, et al. (2010) How well do we understand the impacts of alien species on ecosystem services? A pan-European, cross-taxa assessment. Frontiers in Ecology and the Environment 8: 135–144.
[54]  Hulme PE, Weser C (2011) Mixed messages from multiple information sources on invasive species: a case of too much of a good thing? Diversity and Distribution 17: 1152–1160.
[55]  Essl F, Dullinger S, Rabitsch W, Hulme PE, Huelber K, et al. (2011) Socio-economic legacy yields an invasion debt. Proceedings of the National Academy of Sciences of the United States of America 108: 203–207.
[56]  Py?ek P, Jaro?ík V, Hulme PE, Pergl J, Hejda M, et al. (2012) A global assessment of invasive plant impacts on resident species, communities and ecosystems: the interaction of impact measures, invading species' traits and environment. Global Change Biology 18: 1725–1737.

Full-Text

Contact Us

service@oalib.com

QQ:3279437679

WhatsApp +8615387084133