References
- Duke SO, Blair AC, Dayan FE, Johnson RD, Meepagala KM, Cook D, et al. Is (−) catechin a “novel weapon” of spotted knapweed (Centaurea stoebe)?. J Chem Ecol 2009; 35:141 - 153
- Blair AC, Hanson BD, Brunk GR, Marrs RA, Westra P, Nissen SJ, et al. New techniques and findings in the study of a candidate allelochemical implicated in invasion success. Ecol Lett 2005; 8:1039 - 1047
- Blair AC, Nissen SJ, Brunk GR, Hufbauer RA. A lack of evidence for an ecological role of the putative allelochemical (±) catechin in spotted knapweed invasion success. J Chem Ecol 2006; 32:2327 - 2331
- Weidenhamer JD, Callaway RM. Direct and indirect effects of invasive plants on soil chemistry and ecosystem function. J Chem Ecol 2010; 36:56 - 69
- Bais HP, Vepachedu R, Gilroy S, Callaway RM, Vivanco JM. Allelopathy and exotic plant invasion: From molecules and genes to species interactions. Science 2003; 301:1377 - 1380
- Stermitz FR, Hufbauer RA, Vivanco JM. Enantiomeric-dependent phytotoxic and antimicrobial activity of (±) catechin. A rhizosecreted racemic mixture from spotted knapweed. Plant Physiol 2009; 151:967
- Weir TL, Bais HP, Stull VJ, Callaway RM, Thelen GC, Ridenour WM, et al. Oxalate contributes to the resistance of Gaillardia grandiflora and Lupinus sericeus to a phytotoxin produced by Centaurea maculosa. Planta 2006; 223:785 - 795
- He WM, Feng Y, Ridenour WM, Thelen GC, Pollock JL, Diaconu A, et al. Novel weapons and invasion: Biogeographic differences in the competitive effects of Centaurea maculosa and its root exudate (±) catechin. Oecologia 2009; 159:803 - 815
- Inderjit, Pollock JL, Callaway RM, Holben W. Phytotoxic effects of (±) catechin in vitro, in soil, and in the field. PLoS ONE 2008; 3:2536
- Ridenour WM, Vivanco JM, Feng YL, Horiuchi J, Callaway RM. No evidence for trade-offs: Centaurea plants from America are better competitors and defenders. Ecol Mono 2008; 78:369 - 386
- Thorpe AS, Thelen GC, Diaconu A, Callaway RM. Root exudate is allelopathic in invaded community but not in native community: Field evidence for the novel weapons hypothesis. J Ecol 2009; 97:641 - 645
- Prithiviraj B, Perry LG, Badri DV, Vivanco JM. Chemical facilitation and induced pathogen resistance mediated by a root-secreted phytotoxin. New Phytol 2007; 173:852 - 860
- Veluri R, Weir TL, Bais HP, Stermitz FR, Vivanco JM. Phytotoxic and antimicrobial activities of catechin derivatives. Journal of Agricultural and Food Chemistry 2004; 52:1077 - 1082
- Perry LG, Thelen GC, Ridenour WM, Weir TL, Callaway RM, Paschke MW, et al. Dual role for an allelochemical: (±) catechin from Centaurea maculosa root exudates regulates conspecific seedling establishment. Journal of Ecology 2005; 93:1126 - 1135
- Thelen GC, Vivanco JM, Newingham B, Good W, Bais HP, Landres P, et al. Insect herbivory stimulates allelopathic exudation by an invasive plant and the suppression of natives. Ecology Letters 2005; 8:209 - 217
- Weir TL, Perry LG, Vivanco JM. Rimando AM, Duke SO. Phytoxins produced by invasive weeds and their applications in agriculture and the restoration of natural areas. Natural Products for Pest Management 2006; Washington D.C. American Chemical Society 99 - 112 Symposium Series No. 927
- Perry LG, Weir TL, Prithiviraj B, Paschke MW, Vivanco JM. Manuska FBS, Volkmann D. Root exudation and rhizosphere biology: multiple functions of a plant secondary metabolite. Communication in Plants 2006; Berlin, Heidelberg Springer-Verlag 403 - 420
- Perry LC, Thelen GC, Ridenour WM, Callaway RM, Pashcke MW, Vivanco JM. Concentrations of the allelochemical (±) catechin in Centaurea maculosa soils. J Chem Ecol 2007; 33:2337 - 2344
- Simoes K, Du J, Kretzschmar FS, Broeckling CD, Stermitz FS, Vivanco JM, et al. Phytotoxic catechin leached by seeds of the tropical weed Sesbania virgata. J Chem Ecol 2008; 34:681 - 687
- Broeckling CD, Vivanco JM. A selective, sensitive and rapid in-field assay for soil catechin, an allelochemical of Centaurea maculosa. Soil Biology and Biochemistry 2008; 40:1189 - 1196
- Tharayil N, Triebwasser DJ. Elucidation of a diurnal pattern of catechin exudation by Centaurea stoebe. J Chem E coli 2010; http://dx.doi.org/10.1007/s10886-100-9749-7
- He WM, Feng Y, Ridenour WM, Thelen GC, Pollock JL, Diaconu A, et al. Novel weapons and invasion: biogeographic differences in the competitive effects of Centaurea maculosa and its root exudate (±) catechin. Oecologia 2009; 159:803 - 815
- Pollock JL, Callaway RM, Thelen GC, Holben WE. Catechin-metal interactions as a mechanism for conditional allelopathy by the invasive plant, Centaurea maculosa. Journal of Ecology 2009; 6:1234 - 1242
- Kaku M, Nakagawa N. (+) catechin with Cu2+ induces protein modifications via reactive oxygen species-independent pathway. J Health Sci 2009; 3:441 - 446
- Oikawa S, Furukawaa A, Asada H, Hirakawa K, Kawanishi S. Catechins induce oxidative damage to cellular and isolated DNA through the generation of reactive oxygen species. Free Radical Research 2003; 37:881 - 890
- Sofic E, Denisova N, Youdim K, Vatrenjak-Velagic V, De Filippo C, Mehmedagic A, et al. Antioxidant and pro-oxidant capacity of catecholamines and related compounds: Effects of hydrogen peroxide on glutathione and sphingomyelinase activity in pheochromocytoma PC12 cells: potential relevance to age-related diseases. J Neural Transm 2001; 108:541 - 557
- Kaushik S, Venkatachalam L, Biedrzycki M, Bais HP. Catechin is a phytotoxin and pro-oxidant secreted from the roots of Centaurea stoebe. Plant Sig and behavior 2010; 9:1 - 11
- Nanjo F, Goto K, Seto R, et al. Scavenging effects of tea catechins and their derivatives on 1,1-diphenyl-2-picrylhydrazyl radical. Free Radic Biol Med 1996; 21:895 - 902
- Foreman J, Demidchik V, Bothwell JHF, et al. Reactive oxygen species produced by NADPH oxidase regulate plant cell growth. Nature 2003; 422:442 - 446
- Cao J, Xu Y, Chen J, et al. Chemopreventive effects of green and black tea on pulmonary and hepatic carcinogenesis. Toxicol Sci 1996; 29:244 - 250