Unexpected fast development of branched broomrape on slow-growing Brassicaceae

详细信息    查看全文

• 作者：Stéphanie Gibot-Leclerc ; Carole Reibel…
• 关键词：Phelipanche ramosa ; Parasitic plant ; Arabidopsis thaliana ; Capsella ; Cardamine ; Lepidium ; Sinapis
• 刊名：Agronomy for Sustainable Development
• 出版年：2015
• 出版时间：January 2015
• 年：2015
• 卷：35
• 期：1
• 页码：151-156
• 全文大小：413 KB
• 参考文献：1. Aksoy A, Dixon JM, Hale WHG (1998) / Capsella bursa- / pastoris (L.) Medikus. ( / Thlaspi bursa- / pastoris (L.), / Bursa bursa- / pastoris (L.) / Schull, / Bursa pastoris (L.) Weber). J Ecol 86:171-86 CrossRef
  2. Benharrat H, Boulet C, Theodet C, Thalouarn P (2005) Virulence diversity among branched broomrape ( / O. ramosa L.) populations in France. Agron Sustain Dev 25:123-28 CrossRef
  3. Boulet C, Labrousse P, Arnaud MC, Zehhar N, Fer A (2001) Weed species present various responses to / Orobanche ramosa. In: Proceedings of the Seventh International Parasitic Weed Symposium. Faculté des Sciences de Nantes. 228-31. Nantes, France
  4. Bouwmeester HJ, Matusova R, Zhongkui S, Beale MH (2003) Secondary metabolite signalling in host-parasitic plant interactions. Curr Opin Plant Biol 6:358-64 CrossRef
  5. Boyes D, Zayed AM, Ascenzi R et al (2001) Growth-stage based phenotypic analysis of / Arabidopsis: a model for high throughout functional genomics in plants. Plant Cell 13:1499-510 CrossRef
  6. Brault M, Betsou F, Jeune B, Tuquet C, Sallé G (2007) Variability of / Orobanche ramosa populations in France as revealed by cross infestations and molecular markers. Environ Exp Bot 67:271-80
  7. Buschmann H, Gonsior G, Sauerborn J (2005) Pathogenecity of branched broomrape ( / Orobanche ramosa) populations on tobacco cultivars. Plant Pathol 54:650-56 CrossRef
  8. Ceplitis A, Su Y, Lascoux M (2005) Bayesian inference of evolutionary history from chloroplast microsatellites in the cosmopolitan weed / Capsella bursa- / pastoris (Brassicaceae). Mol Ecol 14:4221-233 CrossRef
  9. Foy CL, Jain R, Jacobsohn R (1989) Recent approaches for chemical control of broomrape ( / Orobanche spp.). Rev Weed Sci 4:123-52
  10. Fried G, Reboud X (2007) Evolution de la composition des communautés adventices des cultures de colza sous l’influence des systèmes de culture. OCL 14:130-38 CrossRef
  11. Gibot-Leclerc S, Brault M, Pinochet X, Sallé G (2003) Potential role of winter rape weeds in the extension of broomrape in Poitou-Charentes. C R Biol 326:645-58 CrossRef
  12. Gibot-Leclerc, S., Charles, J., Dessaint, F., 2009. Potential host plant susceptibility to two / Orobanche ramosa L. races. In: XIIIe Colloque International sur la Biologie des Mauvaises Herbes, Dijon, France, pp. 446-56.
  13. Gibot-Leclerc S, Sallé G, Reboud X, Moreau D (2012) What are the traits to / Phelipanche ramosa (L.) Pomel that contribute to the success of its biological cycle on its host / Brassica napus L. ? Flora 207:512-21 CrossRef
  14. Gibot-Leclerc S, Reibel C, Dessaint F, Le Corre V (2013a) / Phelipanche ramosa (L.) Pomel populations differ in life-history and infection response to hosts. Flora 208:247-52 CrossRef
  15. Gibot-Leclerc S, Abdennebi-Abdemessed N, Reibel C, Colbach N (2013b) Non host-facilitators, a new category that unexpectedly favours parasitic weeds. Agron Sustain Dev 33:787-93 CrossRef
  16. Goldwasser Y, Yoder JI (2001) Differential induction of / Orobanche seed germination by / Arabidopsis thaliana. Plant Sci 160:951-59 CrossRef
  17. Goldwasser Y, Westwood JH, Yoder JI (2002) The use of / Arabidopsis to study interactions between parasitic angiosperms and their plant hosts. The Arabidopsis Book. American Society of Plant Biologists
  18. Goldwasser Y, Yoneyama K, Xie X, Yoneyama K (2008) Production of strigolactones by / Arabidopsis thaliana responsible for / Orobanche aegyptiaca seed germination. P
• 刊物主题：Agriculture; Soil Science & Conservation; Sustainable Development;
• 出版者：Springer Paris
• ISSN：1773-0155

文摘

In France, oilseed rape is getting highly infected since 1990 by the branched broomrape Phelipanche ramosa (L.) Pomel. Branched broomrape infection causes serious yield losses ranging from 5 to 100?%, notably in the Mediterranean area. P. ramosa is parasiting the plant roots. The growth of P. ramosa on Brassicaceae weeds has not been studied quantitatively so far, except for the model species Arabidopsis thaliana. Since P. ramosa has a fast development rate on the fast-growing A. thaliana, P. ramosa development should be slower on other slower-growing Brassicaceae species. Here, we cultivated in the laboratory seven Brassicaceae weed species including Capsella bursa-pastoris, Capsella rubella, Cardamine hirsuta, Lepidium campestre, Lepidium draba, Sinapis arvensis and A. thaliana as control, during 3?weeks. We counted the number of P. ramosa individuals that have reached the following growth stages: germination, attachment, tubercle, bud and underground stem. We then assessed the development rate of P. ramosa by calculating the odds ratio of attachment or higher development stages of P. ramosa on Brassicaceae, with A. thaliana as the reference. We found that five Brassicaceae species had an odds ratio ranging from 0.9 to 2.4. These ratios are thus similar or higher than that of the A. thaliana reference. This finding shows for the first time that P. ramosa develops faster on the five Brassicaceae species. This finding is also unexpected because A. thaliana is a fast-growing plant, whereas the five Brassicaceae species have a longer life cycle. Therefore, this observation demonstrates for the first time that P. ramosa development depends on others factors than the speed of plant host development.