Abstract
Efforts to arrest the spread of invasive weeds with herbivory may be hindered by weak effects of the herbivores or strong compensatory responses of the invaders. We conducted a greenhouse experiment to study the effects of defoliation and soil fungi on competition between the invasive weed Centaurea solstitialis and C. solstitialis and Avena barbata, a naturalized Eurasian annual grass, and Nassella pulchra, a native California bunchgrass. Surprisingly, considering the explosive invasion of grasslands by C. solstitialis, Avena and Nassella were strong competitors and reduced the invader’s biomass by 80.2% and 80.1% over all defoliation and soil fungicide treatments, respectively. However, our experiments were conducted in artificial environments where competition was probably accentuated. When fungicide was applied to the soil, the biomass of C. solstitialis was reduced in all treatment combinations, but reduction in the biomass of the invader had no corollary impact on the grasses. There was no overall effect of defoliation on the final biomass of C. solstitialis as the invader compensated fully for severe clipping. In fact, the directional trend of the clipping effect was +6.4% over all treatments after eight weeks. A significant neighbor × soil fungicide × clipping effect suggested that the compensatory response was the strongest without soil fungicide and when C. solstitialis was alone (+ 19%). Our key finding was that the compensatory response of C. solstitialis in all treatments was associated with an increase in the weed’s negative effects on Nassella and Avena – there was a significant decrease in the total biomass of both grasses and the reproductive biomass of Avena in pots with clipped C. solstitialis. Our results were obtained in controlled conditions that may have been conducive to compensatory growth, but they suggest the existence of mechanisms that may allow C. solstitialis, like other Centaurea species, to resist herbivory.
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References
Bais HP, Walker TS, Stermitz FR, Hufbauer RA and Vivanco JM (2002). Enantiomeric-dependent phytotoxic and antimicrobial activity of (±)-catechin. A rhizosecreted racemic mixture from spotted knapweed. Plant Physiology 128: 1173–1179
Bais HP, Vepachedu R, Gilroy S, Callaway RM and Vivanco JM (2003). Allelopathy and exotic plants: from genes to invasion. Science 301: 1377–1380
Callaway RM and Aschehoug ET (2000). Invasive plants versus their new and old neighbors: a mechanism for exotic invasion. Science 290: 521–523
Callaway RM, DeLuca T and Ridenour WM (1999). Herbivores used for biological control may increase the competitive ability of the noxious weed Centaurea maculosa. Ecology 80: 1196–1201
Callaway RM, Newingham B, Zabinski CA and Mahall BE (2001). Compensatory growth and competitive ability of and invasive weed are enhanced by soil fungi and native neighbors. Ecology Letters 4: 1–5
Callaway RM, Mahall BE, Wicks C, Pankey J and Zabinski CA (2003). Soil fungi and the effects of an invasive forb on native versus naturalized grasses: neighbor identity matters. Ecology 84: 129–135
Callaway RM, Thelen GC, Barth S, Ramsey PW and Gannon JE (2004a). Soil fungi alter interactions between North American plant species and the exotic invader Centaurea maculosa in the field. Ecology 85: 1062–1071
Callaway RM, Thelen GC, Rodriguez A and Holben WE (2004b). Release from inhibitory soil biota in Europe may promote exotic plant invasion in North America. Nature 427: 731–733
Crawley MJ (1992). Natural Enemies: the Population Biology of Predators, Parasites and Diseases. Blackwell Science, Oxford, UK
DiTomaso JM and Gerlach JD (2000). Centaurea solstitialis L. In: Bossard, CC, Randall, JM and Hoshovsky, Marc C (eds) Invasive Plants of California’s Wildlands, pp 101–105. University of California Press, Davis, California, USA
Driesche RG (1996). Biological Control. Chapman and Hall, New York, USA
Dukes J (2001). Biodiversity and invisibility in grassland microcosms. Oecologia 126: 563–568
Dukes J (2002). Species composition and diversity affect grassland susceptibility and response to invasion. Ecology 12: 602–617
Fitter AH and Nichols R (1988). The use of benomyl to control infection by vesicular- arbuscular mycorrhizal fungi. New Phytologist 110: 210–206
Fletcher RA and Renney AJ (1963). A growth inhibitor found in␣Centaurea spp. Canadian Journal of Plant Science 43: 475–481
Rice KJ (2003). Testing life history correlates of invasiveness using congeneric plant species. Ecological Applications 13: 167–179
Hamilton JG (1997). Changing perceptions of pre-European grasslands in California. Madroño 44: 311–333
Frank DA (2001). Can plants stimulate soil microbes and their own nutrient supply?. Ecology 82: 2397–2402
Harper JL (1969). The role of predation in vegetational diversity. Brookhaven Symposium in Biology 22: 48–62
Herms DA and Mattson WJ (1992). The dilemma of plants: to grow or defend. Quarterly Review of Biology 67: 283–335
Herzog P and Randall J (1992). Element Stewardship Abstract for Centaurea solstichialis. The Nature Conservancy. Arlington, Virginia
Hetrick BAD, Wilson GT and Hartnett DC (1989). Relationship between mycorrhizal dependence and competitive ability of two tallgrass prairie grasses. Canadian Journal of Botany 67: 2608–2615
Hierro JL and Callaway RM (2003). Allelopathy and exotic plant invasion. Plant and Soil 255: 1–11
Howald A, Randall J, Sigg J, Wagner E and Warner P (1999) Exotic pest plants of greatest concern in California. California Exotic Pest Plant Council, October
Kelsey RG and Locken RJ (1987). Phytotoxic properties of cnicin, a sesquiterpene lactone from Centaurea maculosa (spotted knapweed). Journal of Chemical Ecology 13: 19–33
Kennett GA, Lacey JR, Butt CA, Olson-Rutz KM and Haferkamp MR (1992). Effects of defoliation, shading and competition on spotted knapweed and bluebunch wheatgrass. Journal of Range Management 45: 363–369
Lacey JR, Olson-Rutz KM, Haferkamp MR and Kennet GA (1994). Effects of defoliation and ompetition on total nonstructural carbohydrates of spotted knapweed. Journal of Range Management 47: 481–484
LeJeune KD and Seastedt TR (2001). Centaurea species: the forb that won the west. Conservation Biology 15: 1568–1574
Louda SM, Keeler KH and Holt RD (1990). Herbivore influences on plant performance and competitive interactions. In: Grace, JB and Tilman, D (eds) Perspectives on Plant Competition, pp 413–444. Academic Press, New York
Marler MJ, Zabinski CA and Callaway RM (1999). Mycorrhizae indirectly enhance competitive effects of an invasive forb on a native bunchgrass. Ecology 80: 1180–1186
Maschinski J and Whitham TG (1989). The continuum of plant responses to herbivory: the influence of plant association, nutrient availability and timing. American Naturalist 134: 1–19
McGonigle TP, Miller MH, Evans DG, Fairchild DL and Swan JA (1990). A new method which gives an objective measure, of colonization of roots by vesicular- arbuscular mycorrhizal fungi. New Phytologist 115: 495–501
McNaughton SJ (1983). Compensatory plant growth as a response to herbivory. Oikos 40: 329–336
Muir AD and Majak W (1983). Allelopathic potential of diffuse knapweed (Centaurea diffusa) extracts. Canadian Journal of Plant Sciences 63: 989–996
Müller H (1989). Growth pattern of diploid and tetraploid spotted knapweed, Centaurea maculosa Lam. (Compositae) and effects of the root mining moth Agapeta zoegana (L.) (Lepidoptera:Cochylidae). Weed Research 29: 103–111
Müller-Schärer H (1991). The impact of root herbivory as a function of plant density and competition: survival, growth and fecundity of Centaurea maculosa in field plots. Journal of Applied Ecology 28: 759–776
Müller H and Steinger T (1990). Separate and joint effects of root herbivores, plant competition and nitrogen shortage on resource allocation and components of reproduction in Centaurea maculosa (Compositae). In: Szentesi, A (eds) Proceedings of the 7th International Symposium on Insect-Plant relationships, pp 215–224. Hungarian academy of Sciences, Budapest
Newsham KK, Fitter AH and Watkinson AR (1994). Root pathogenic and arbuscular mycorrhizal fungi determine fecundity of asymptomatic plants in the field. Journal of Ecology 82: 805–814
Paige KN (1992). Overcompensation in response to mammalian herbivory: from mutualistic to antagonistic interactions. Ecology 73: 2076–2085
Paige KN and Whitham TG (1987). Overcompensation in response to mammalian herbivory: the advantage of being eaten. American Naturalist 129: 407–416
Paul ND, Ayres PG and Wyness LE (1989). On the use of fungicides for experimentation in natural vegetation. Functional Ecology 3: 759–769
Phillips JM and Hayman DS (1970). Improved procedures for clearing roots and staining parasitic and vesicular–arbuscular mycorrhizal fungi for rapid assessment of infection. Transactions of the British Mycorrhizal Society 55: 158–161
Pitcairn MJ, O’Connell RA and Gendron JM (1998). Yellow starthistle: survey of statewide distribution. In: Woods, DM (eds) Biological Control Program Annual Summary, 1997, pp 64–66. California Department of Food and Agriculture, Plant Health and Pest Preservation Services, Sacramento, California, USA
Rice P (2000) INVADERS Database. [WWW document] URL http://invader.dbs.umt.edu
Ridenour WM and Callaway RM (2001). The relative importance of allelopathy in interference: the effects of an invasive weed on a native bunchgrass. Oecologia 126: 444–450
Ridenour WL and Callaway RM (2003). Root herbivores, pathogenic fungi and competition between Centaurea maculosa and Festuca idahoensis. Plant Ecology 169: 161–170
Smith MD, Hartnett DC and Rice CW (2000). Effects of long-term fungicide applications on microbial properties in tallgrass soil. Soil Biology and Biochemistry 32: 935–946
Steinger T and Müller-Schärer H (1992). Physiological and growth responses of Centaurea maculosa (Asteraceae) to root herbivory under varying levels of interspecific competition and soil nitrogen availability. Oecologia 91: 141–149
Stevens KL (1986). Allelopathic polyacetylenes from Centaurea repens (Russian knapweed). Journal Chemical Ecology 12: 1205–1211
Story JM, Good WR, White LJ and Smith L (2000). Effects of the interaction of the biocontrol agent Agapeta zoegana (L.) (Lepidoptera:Cochylidae) and grass competition on spotted knapweed. Biological Control 17: 182–190
Trumble JT, Kolodny-Hirsch DM and Ting IP (1993). Plant compensation for herbivory. Annual Review of Entomology 38: 93–119
Maas PWTh, Van Gulik WJM and Brinkman H (1990). Characterization of soil organisms involved in the degeneration of Ammophila arenaria. Soil Biology and Biogeochemistry 22: 845–852
Vet LEM, Harvey JA and Wäckers FL (2001). Linking above- and belowground interactions of plants, herbivores, pathogens, and their antagonists. Trends in Ecology and Evolution 16: 547–554
Vivanco JM, Bais HP, Stermitz FR, Thelen GC and Callaway RM (2004). Biogeographical variation in community response to root allelochemistry: novel weapons and exotic invasion. Ecology Letters 7: 285–292
West HM, Fitter AH and Watkinson AR (1993). The influence of three biocides on the fungal associates of the roots of Vulpia ciliata spp. ambigua under natural conditions. Journal of Ecology 81: 345–350
Zabinski CA, Quinn L and Callaway RM (2002). Phosphorus uptake, not carbon transfer, explains arbuscular mycorrhizal enhancement of Centaurea maculosa in the presence of native grassland species. Functional Ecology 16: 758–765
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Callaway, R.M., Kim, J. & Mahall, B.E. Defoliation of Centaurea solstitialis Stimulates Compensatory Growth and Intensifies Negative Effects on Neighbors. Biol Invasions 8, 1389–1397 (2006). https://doi.org/10.1007/s10530-006-0003-8
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DOI: https://doi.org/10.1007/s10530-006-0003-8