化感物质调控种子萌发的机理与生态价值(7)

　　[53] Voegele A, Graeber K, Oracz K, et al. Embryo growth, testapermeability, and endosperm weakening are major targets forthe environmentally regulated inhibition of Lepidium sativumseed germination by myrigalone A[J]. Journal of ExperimentalBotany, 2012, 63（14）： 5337–5350.　　
　　[54] Kato-Noguchi H, Macías F A. Inhibition of germination andα-amylase induction by 6-methoxy-2-benzoxazolinone intwelve plant species[J]. Biologia Plantarum, 2008, 52（2）：351–354.　　
　　[55] Kato-Noguchi H, Macías F A. Effects of 6-methoxy-2-benzoxazolinone on the germination and α-amylase activityin lettuce seeds[J]. Journal of Plant Physiology, 2005, 162（12）：1304–1307.　
　　[56] Kupid?owska E, Gniazdowska A, St?pień J, et al. Impact ofsunflower （Helianthus annuus L.） extracts upon reserve mo-bilization and energy metabolism in germinating mustard（Sinapis alba L.） seeds[J]. Journal of Chemical Ecology, 2006,32（12）： 2569–2583.　
　　[57] Miransari M, Smith D L. Plant hormones and seed germina-tion[J]. Environmental and Experimental Botany, 2014, 99:110–121.　
　　[58] Shu K, Meng Y J, Shuai H W, et al. Dormancy and germina-tion: How does the crop seed decide?[J]. Plant Biology, 2015,17（6）： 1104–1112.　
　　[59] Shu K, Chen Q, Wu Y R, et al. ABI4 mediates antagonisticeffects of abscisic acid and gibberellins at transcript and pro-tein levels[J]. The Plant Journal, 2015, 85（3）： 348–361[60] Linkies A, Leubner-Metzger G. Beyond gibberellins and ab-scisic acid: How ethylene and jasmonates control seed ger-mination[J]. Plant Cell Reports, 2012, 31（2）： 253–270.　
　　[61] Shu K, Zhang H W, Wang S F, et al. ABI4 regulates primaryseed dormancy by regulating the biogenesis of abscisic acidand gibberellins in Arabidopsis[J]. PLoS Genetics, 2013, 9（6）：e1003577.　
　　[62] Holdsworth M J, Bentsink L, Soppe W J J. Molecular net-works regulating Arabidopsis seed maturation, after- ripening,dormancy and germination[J]. New Phytologist, 2008, 179（1）：33–54.　　
　　[63] Finkelstein R, Reeves W, Ariizumi T, et al. Molecular aspectsof seed dormancy[J]. Annual Review of Plant Biology, 2008,59（1）： 387–415.　　
　　[64] Skene K R, Sprent J I, Raven J A, et al. Myrica gale L.[J].Journal of Ecology, 2000, 88（6）： 1079–1094.　　
　　[65] Popovici J, Bertrand C, Jacquemoud D, et al. An allelochem-ical from Myrica gale with strong phytotoxic activity againsthighly invasive Fallopia x bohemica taxa[J]. Molecules, 2011,16（3）： 2323–2333.　
　　[66] Gniazdowska A, Oraczr K, Bogatek R. Phytotoxic effects ofsunflower （Helianthus annuus L.） leaf extracts on germinatingmustard （Sinapis alba L.） seeds[J]. Allelopathy Journal, 2007,19（1）： 215–226.　
　　[67] Zhu Y, Li Q X. Movement of bromacil and hexazinone in soilsof Hawaiian pineapple fields[J]. Chemosphere, 2002, 49（6）：669–674.　
　　[68] Roeleveld N, Bretveld R. The impact of pesticides on malefertility[J]. Current Opinion in Obstetrics and Gynecology,2008, 20（3）： 229–233.　
　　[69] Dayan F E, Cantrell C L, Duke S O. Natural products in cropprotection[J]. Bioorganic & Medicinal Chemistry, 2009,17（12）： 4022–4034.　
　　[70] Schulz M, Marocco A, Tabaglio V, et al. Benzoxazinoids inrye allelopathy-from discovery to application in sustainableweed control and organic farming[J]. Journal of ChemicalEcology, 2013, 39（2）： 154–174.　
　　[71] Kato-Noguchi H, Peters R J. The role of momilactones in riceallelopathy[J]. Journal of Chemical Ecology, 2013, 39（2）：175–185.　
　　[72] Weston L A, Alsaadawi I S, Baerson S R. Sorghum allelopa-thy - From ecosystem to molecule[J]. Journal of ChemicalEcology, 2013, 39（2）： 142–153.　
　　[73] Bogatek R, Gniazdowska A, Zakrzewska W, et al. Allelopa-thic effects of sunflower extracts on mustard seed germinationand seedling growth[J]. Biologia Plantarum, 2006, 50（1）：156–158.　　
　　[74] Fragasso M, Iannucci A, Papa R. Durum wheat and allelopa-thy: Toward wheat breeding for natural weed management[J].Frontiers Plant in Science, 2013, 4: 375.　　
　　[75] 王建花， 陈婷， 林文雄。 植物化感作用类型及其在农业中的应用[J]. 中国生态农业学报， 2013, 21（10）： 1173–1183.Wang J H, Chen T, Lin W X. Plant allelopathy types and theirapplication in agriculture[J]. Chinese Journal of Eco- Agri-culture, 2013, 21（10）： 1173–1183.　　
　　[76] Vyvyan J R. Allelochemicals as leads for new herbicides andagrochemicals[J]. Tetrahedron, 2002, 58（9）： 1631–1646.　　
　　[77] Jabran K, Mahajan G, Sardana V, et al. Allelopathy for weedcontrol in agricultural systems[J]. Crop Protection, 2015, 72:57–65.　　
　　[78] Macías F A, Molinillo J M, Galindo J C G, et al. The use ofallelopathic studies in the search for natural herbicides[J].Journal of Crop Production, 2001, 4（2）： 237–255.　
　　[79] Khanh T D, Chung M I, Xuan T D, et al. The exploitation ofcrop allelopathy in sustainable agricultural production[J].Zeitschrift fur Acker-und Pflanzenbau, 2005, 191（3）： 172–184.　
　　[80] Dilipkumar M, Chuah T S. Is combination ratio an importantfactor to determine synergistic activity of allelopathic cropextract and herbicide?[J]. International Journal of Agriculture& Biology, 2013, 15（2）： 259–265.　　
　　[81] Blackshaw R E, Moyer J R, Doram R C, et al. Yellow sweet-clover, green manure, and its residues effectively suppress weedsduring fallow[J]. Weed Science, 2001, 49（3）： 406–413.　
　　[82] Moyer J R, Blackshaw R E, Huang H C. Effect of sweetclovercultivars and management practices on following weed infes-tations and wheat yield[J]. Canadian Journal of Plant Science,2007, 87（4）： 973–983.　
　　[83] Tesio F, Vidotto F, Ferrero A. Allelopathic persistence of He-lianthus tuberosus L. residues in the soil[J]. Scientia Horti-culturae, 2012, 135: 98–105.　　
　　[84] 鞠瑞亭， 李慧， 石正人， 等。 近十年中国生物入侵研究进展[J].生物多样性， 2012, 20（5）： 581–611.Ju R T, Li H, Shi Z R, et al. Progress of biological invasionsresearch in China over the last decade[J]. Biodiversity Sci-ence, 2012, 20（5）： 581–611.　
　　[85] Schittko C, Wurst S. Above- and belowground effects ofplant-soil feedback from exotic Solidago canadensison nativeTanacetum vulgare[J]. Biological Invasions, 2014, 16（7）：1465–1479.　　
　　[86] Shen S C, Xu G F, Clements D R, et al. Suppression of theinvasive plant mile-a-minute （Mikania micrantha） by localcrop sweet potato （Ipomoea batatas） by means of highergrowth rate and competition for soil nutrients[J]. BMC Ecol-ogy, 2015, 15: 1.　　
　　[87] Hodgins K A, Lai Z, Nurkowski K, et al. The molecular basisof invasiveness: Differences in gene expression of native andintroduced common ragweed （Ambrosia artemisiifolia） instressful and benign environments[J]. Molecular Ecology,2013, 22（9）： 2496–2510.　　
　　[88] 张敏， 付冬梅， 陈华保， 等。 紫茎泽兰叶片对小麦、油菜幼苗的化感作用及化感机制的初步研究[J]. 浙江大学学报：农业与生命科学版， 2010, 36（5）： 547–553.Zhang M, Fu D M, Chen H B, et al. Preliminary studyon allelopathic effects and mechanism of Eupatorium ade-nophorum to wheat and rape seedlings[J]. Journal of ZhejiangUniversity: Agriculture & Life Sciences, 2010, 36（5）：547–553.　　
　　[89] Jarchow M E, Cook B J. Allelopathy as a mechanism for theinvasion of Typha angustifolia[J]. Plant Ecology, 2009,204（1）： 113–124.　　
　　[90] Greer M J, Wilson G W, Hickman K R, et al. Experimentalevidence that invasive grasses use allelopathic biochemicalsas a potential mechanism for invasion: Chemical warfare innature[J]. Plant and Soil, 2014, 385（1/2）： 165–179.