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Bridal Creeper (Asparagus asparagoides)–Invaded Sites with Elevated Levels of Available Soil Nutrients: Barrier to Restoration?

Published online by Cambridge University Press:  20 January 2017

Peter J. Turner*
Affiliation:
School of Animal Biology, University of Western Australia
John K. Scott
Affiliation:
CSIRO Ecosystem Sciences, Private Bag 5, P.O. Wembley, WA 6913, Australia
Helen Spafford
Affiliation:
School of Animal Biology, University of Western Australia
*
Corresponding author's E-mail: [email protected]

Abstract

Bridal creeper has become a serious environmental weed in southern Australia. Historically the invaded areas had low soil nutrient levels. However, our field surveys indicate that soils in bridal creeper–invaded areas have higher phosphorus and iron levels than soils in nearby native reference areas regardless of the proximity to agriculture or other disturbances. A glasshouse experiment was undertaken to determine the influence of increased nutrients on plants that co-occur with bridal creeper in order to (1) assess the impact of changed soil conditions and (2) predict the response of dominant species following the biological control of bridal creeper. The relative growth rate (RGR) of bridal creeper, two native shrubs (narrow-leaved thomasia [Thomasia angustifolia] and bluebell creeper [Billardiera heterophylla]), and an invasive exotic grass (annual veldt grass [Ehrharta longiflora]) were determined in three soil types: soil collected within a bridal creeper stand, soil collected from a nearby reference area, and a potting mix with nutrient levels higher than that recorded in the field. The plant species were chosen due to their association with bridal creeper. For example, the native species narrow-leaved thomasia was identified in a previous survey as the most abundant shrub at the invaded site where the soil was collected. The two other species, bluebell creeper and annual veldt grass, were identified from a previous seedbank trial as being abundant (in the seedbank) and able to readily germinate in invaded areas. When grown in either the bridal creeper–invaded soil or reference soil, bluebell creeper had significantly lower RGRs than narrow-leaved thomasia and annual veldt grass. However, as all these species showed increases in RGRs between reference soil and bridal creeper soil, this study indicates that for at least these three species the impact of increased nutrients may not be a barrier to the recovery of invaded areas following the control of bridal creeper.

Type
Research
Copyright
Copyright © Weed Science Society of America 

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References

Literature Cited

Adam, P., Stricker, P., and Anderson, D. J. 1989. Species-richness and soil phosphorus in plant communities in coastal New South Wales. Aust. J. Ecol 14:189198.Google Scholar
Allcock, K. G. 2002. Effects of phosphorus on growth and competitive interactions of native and introduced species found in white box woodlands. Austral Ecol 27:638646.Google Scholar
Attiwill, P. and Weston, C. 2003. Soils. Pages 5471. In Attiwill, P. M. and Wilson, B. eds. Ecology. An Australian Perspective. South Melbourne, Australia Oxford University Press.Google Scholar
Beadle, N. C. W. 1966. Soil phosphate and its role in molding segments of the Australian flora and vegetation, with special reference to xeromorphy and scherophylly. Ecology 47:9921007.Google Scholar
[BOM] Commonwealth of Australia, Bureau of Meteorology 2010a. Monthly Rainfall Bremer Bay. http://www.bom.gov.au/jsp/ncc/cdio/weatherData/av?p_nccObsCode=139&p_display_type=dataFile&p_startYear=&p_stn_num=009654. Accessed: October 19, 2010.Google Scholar
Boswell, C. C. and Espie, P. R. 1998. Uptake of moisture and nutrients by Hieracium pilosella and effects on soil in a dry sub-humid grassland. N. Z. J. Agric. Res 41:251261.CrossRefGoogle Scholar
Cannon, J. P., Allen, E. B., Allen, M. F., Dudley, L. M., and Jurinak, J. J. 1995. The effects of oxalates produced by Salsola tragus on the phosphorus nutrition of Stipa pulchra . Oecologia 102:265272.Google Scholar
Clarke, K. R. 1993. Non-parametric multivariate analyses of changes in community structure. Aust. J. Ecol 18:117143.Google Scholar
Clarke, K. R. and Gorley, R. N. 2006. PRIMER v6. User Manual/Tutorial. Plymouth, UK PRIMER-E. 192 p.Google Scholar
Clarke, K. R. and Warwick, R. M. 2001. Change in Marine Communities: An Approach to Statistical Analysis and Interpretation. 2nd ed. Plymouth PRIMER-E.Google Scholar
Clements, A. 1983. Suburban development and resultant changes in the vegetation of the bushland of the northern Sydney region. Aust. J. Ecol 8:307319.Google Scholar
Colwell, J. D. 1963. The estimation of the phosphorus fertilizer requirements of wheat in southern New South Wales by soil analysis. Aust. J. Exp. Agric. Anim. Husb 3:190197.Google Scholar
Daehler, C. C. 2003. Performance comparisons of co-occurring native and alien invasive plants: implications for conservation and restoration. Annu. Rev. Ecol. Evol. Syst 34:183211.Google Scholar
Dakora, F. D. and Phillips, D. A. 2002. Root exudates as mediators of mineral acquisition in low-nutrient environments. Plant Soil 245:3547.CrossRefGoogle Scholar
Ehrenfeld, J. G. 2003. Effects of exotic plant invasions on soil cycling processes. Ecosystems 6:503523.Google Scholar
Ehrenfeld, J. G. and Scott, N. 2001. Invasive species and the soil: effects on organisms and ecosystem processes. Ecol. Appl 11:12591260.Google Scholar
Fogarty, G. and Facelli, J. M. 1999. Growth and competition of Cytisus scoparius, an invasive shrub, and Australian native shrubs. Plant Ecol 144:2735.Google Scholar
Gardner, W. K., Barber, D. A., and Parbery, D. G. 1983. The acquisition of phosphorus by Lupinus albus L. III. The probable mechanism by which phosphorus movement in the soil/root interface is enhanced. Plant Soil 70:107124.Google Scholar
GenStat 2003. Release 7.2, Lawes Agricultural Trust (Rothamsted Experimental Station). Hemel Hempstead VSN International Ltd.Google Scholar
Gordon, D. R. 1998. Effects of invasive non-indigenous plant species on ecosystem processes: lessons from Florida. Ecol. Appl 8:975989.Google Scholar
Grierson, P. F., Smithson, P., Nziguheba, G., Radersma, S., and Comerford, N. B. 2004. Phosphorus dynamics and mobilization by plants. Pages 127142. In van Noordwijk, M., Cadisch, G., and Ong, C. K. eds. Below-Ground Interactions in Tropical Agroecosystems: Concepts and Models with Multiple Plant Components. Cambridge, UK CABI Publishing.Google Scholar
Grime, J. P. 1979. Plant Strategies and Vegetation Processes. Chichester John Wiley and Sons. 419 p.Google Scholar
Haynes, R. J. and Mokolobate, M. S. 2001. Amelioration of Al toxicity and P deficiency in acid soils by additions of organic residues: a critical review of the phenomenon and the mechanisms involved. Nutr. Cycl. Agroecosyst 59:4763.Google Scholar
Heneghan, L., Fatemi, F., Umek, L., Grady, K., Fagen, K., and Workman, M. 2006. The invasive shrub European buckthorn (Rhamnus cathartica L.) alters soil properties in midwestern U.S. woodlands. Appl. Soil Ecol 32:142148.Google Scholar
Hobbs, R. J. 1991. Disturbance a precursor to weed invasion in native vegetation. Plant Prot. Q 6:99104.Google Scholar
Hunt, R. 1978. Plant Growth Analysis. London Edward Arnold. 67 p.Google Scholar
Hunt, R., Causton, D. R., Shipley, B., and Askew, A. P. 2002. A modern tool for classical plant growth analysis. Ann. Bot 90:485488.CrossRefGoogle ScholarPubMed
Iyamuremye, F. and Dick, R. P. 1996. Organic amendments and phosphorus sorption by soils. Adv. Agron 56:139185.Google Scholar
Kuo, S. 1996. Phosphorus. Pages 869919. In Sparkes, D. L., Page, A. L., Helmke, P. A., Loeppert, R. H., Soltanpour, P. N., Tabatabai, M. A., Johnston, C. T., Summer, M. E., Bartels, J. M., and Bigham, J. M. eds. Methods of Soil Analysis. Part 3 Chemical Methods. Madison, WI Soil Science Society of America, Inc.Google Scholar
Lake, J. C. and Leishman, M. R. 2004. Invasion success of exotic plants in natural ecosystems: the role of disturbance, plant attributes and freedom from herbivores. Biol. Conserv 117:215226.Google Scholar
Leishman, M. R., Hughes, M. T., and Gore, D. B. 2004. Soil phosphorus enhancement below stormwater outlets in urban bushland: spatial and temporal changes and the relationship with invasive plants. Aust. J. Soil Res 42:197202.Google Scholar
Leishman, M. R. and Thomson, V. P. 2005. Experimental evidence for the effects of additional water, nutrients and physical disturbance on invasive plants in low fertility Hawkesbury Sandstone soils, Sydney, Australia. J. Ecol 93:3849.Google Scholar
McArthur, W. M. 1991. Reference Soils of South-western Australia. Perth Department of Agriculture, Western Australia. 265 p.Google Scholar
McQuaker, N. R., Brown, D. F., and Kluckner, P. D. 1979. Digestion of environmental materials for analysis by inductively coupled plasma-atomic emission spectrometry. Anal. Chem 51:10821084.CrossRefGoogle Scholar
Mitchell, R. J., Marrs, R. H., Le Duc, M. G., and Auld, M. H. D. 1997. A study of succession on lowland heaths in Dorset, southern England: changes in vegetation and soil chemical properties. J. Appl. Ecol 34:14261444.Google Scholar
Morgan, J. W. 1998. Patterns of invasion of an urban remnant of a species-rich grassland in southeastern Australia by non-native plant species. J. Veg. Sci 9:181190.CrossRefGoogle Scholar
Morin, L., Batchelor, K. L., and Scott, J. K. 2006a. The biology of Australian weeds. 44 Asparagus asparagoides (L.) Druce. Plant Prot. Q 21:4662.Google Scholar
Morin, L., Neave, M., Batchelor, K., and Reid, A. 2006b. Biological control: a promising tool for managing bridal creeper, Asparagus asparagoides (L.) Druce, in Australia. Plant Prot. Q 21:6977.Google Scholar
Myers, N., Mittermeier, R. A., Mittermeier, C. G., da Fonseca, G. A. B., and Kent, J. 2000. Biodiversity hotspots for conservation priorities. Nature 403:853858.Google Scholar
Quinn, G. P. and Keough, M. J. 2002. Experimental Design and Data Analysis for Biologists. Cambridge, UK University Press. 537 p.Google Scholar
Rayment, G. E. and Higginson, F. R. 1992. Australian Laboratory Handbook of Soil and Water Chemical Methods. Melbourne Inkata. 330 p.Google Scholar
Raymond, K. 1995. The autecology of bridal creeper: how does it work?. Pages 1721. In Cooke, D. and Choate, J. eds. Weeds of Conservation Concern. Adelaide Department of Environment and Natural Resources, Animal and Plant Control Commission.Google Scholar
Sala, A., Verdaguer, D., and Villa, M. 2007. Sensitivity of the invasive geophyte Oxalis pes-caprae to nutrient availability and competition. Ann. Bot 99:637645.CrossRefGoogle ScholarPubMed
Specht, R. L. 1963. Dark Island heath (Ninety-mile Plain, South Australia) VII. The effect of fertilizers on composition and growth, 1950–1960. Aust. J. Bot 11:6794.Google Scholar
Specht, R. L., Connor, D. J., and Clifford, H. T. 1977. The heath-savannah problem: the effect of fertilizer on sand-heath vegetation of North Stradbroke Island, Queensland. Aust. J. Ecol 2:179186.Google Scholar
Stansbury, C. D., Batchelor, K. L., Morin, L., Woodburn, T. L., and Scott, J. K. 2007. Standardized support to measure biomass and fruit production by the invasive climber (Asparagus asparagoides). Weed Technol 21:820824.CrossRefGoogle Scholar
Thomson, V. P. and Leishman, M. R. 2004. Survival of native plants of Hawkesbury Sandstone communities with additional nutrients: effects of plant age and habitat. Aust. J. Bot 52:141147.Google Scholar
Thomson, V. P. and Leishman, M. R. 2005. Post-fire vegetation dynamics in nutrient-enriched and non-enriched sclerophyll woodland. Austral Ecol 30:250260.Google Scholar
Thorpe, A. S., Archer, V., and DeLuca, T. H. 2006. The invasive forb, Centaurea maculosa, increases phosphorus availability in Montana grasslands. Appl. Soil Ecol 32:118222.Google Scholar
Traeger, A., Spafford Jacob, H., and Bruzzese, E. 2004. Characteristics of Sollya heterophylla Lindl.: a native weedy plant. Pages 111. In Sindel, B. M. and Johnson, S. B. eds. Proceedings of the Fourteenth Australian Weeds Conference. Wagga Wagga, Australia Weed Society of New South Wales.Google Scholar
Turner, P. J. 2008. The impacts of the environmental weed Asparagus asparagoides and the ecological barriers to restoring invaded sites following biological control. Ph.D thesis. Perth, Australia University Western Australia. 212 p.Google Scholar
Turner, P. J., Morin, L., Williams, D. G., and Kriticos, D. J. 2010. Interactions between a leafhopper and rust fungus on the invasive plant Asparagus asparagoides in Australia: a case of two agents being better than one for biological control. Biol. Cont 54:322330.Google Scholar
Turner, P. J., Scott, J. K., and Spafford, H. 2008a. Implications of successful biological control of bridal creeper (Asparagus asparagoides (L.) Druce) in south west Australia. Pages 390–292. In van Klinken, R. D., Osten, V. A., Panetta, F. D., and Scanlan, J. C. eds. Proceedings of the Sixteenth Australian Weeds Conference. Brisbane Queensland Weeds Society.Google Scholar
Turner, P. J., Scott, J. K., and Spafford Jacob, H. 2006. Barrier to restoration: the decomposition of bridal creeper's root system. Pages 827830. In Preston, C., Watts, J. H., and Crossman, N. D. eds. Proceedings of the Fifteenth Australian Weeds Conference. Adelaide Weed Management Society of South Australia.Google Scholar
Turner, P. J., Spafford, H., and Scott, J. K. 2008b. The ecological barriers to the recovery of bridal creeper (Asparagus asparagoides (L.) Druce) infested sites: impacts on vegetation and the potential increase in other exotic species. Austral Ecol 33:713722.Google Scholar
Turner, P. J. and Virtue, J. G. 2006. An eight-year removal experiment measuring the impact of bridal creeper (Asparagus asparagoides (L.) Druce) and the potential benefit from its control. Plant Prot. Q 21:7984.Google Scholar
Turner, P. J. and Virtue, J. G. 2009. Ten year post-fire response of a native ecosystem in the presence of high or low densities of the invasive weed, Asparagus asparagoides . Plant Prot. Q 24:2026.Google Scholar
Vranjic, J. A., Woods, M. J., and Barnard, J. 2000. Soil-mediated effects on germination and seedling growth of coastal wattle (Acacia sophorae) by the environmental weed, bitou bush (Chrysanthemoides monilifera ssp. rotundata). Austral Ecol 25:445453.Google Scholar
Walkley, A. and Black, I. A. 1934. An examination of the Gedtjareff method for determining soil organic matter and a proposed modification of the chromic acid titration method. Soil Science 37:2938.Google Scholar
Wei, L., Chen, C., and Xu, Z. 2010. Citric acid enhances the mobilization of organic phosphorus in subtropical and tropical forest soils. Biol. Fertil. Soils 46:765769.Google Scholar
Wheeler, J., Marchant, N., Lewington, M., and Graham, L. 2002. Flora of the South West. Bunbury, Augusta, Denmark. Canberra Flora of Australia Supplementary Series 12. Australian Biological Resources Study and University of Western Australia Press. 470 p.Google Scholar