SEARCH

SEARCH BY CITATION

References

  • Arraiano LS, Brown JKM, 2006. Identification of isolate-specific and partial resistance to septoria tritici blotch in 238 European wheat cultivars and breeding lines. Plant Pathology 55, 72638.
  • Barrett CF, Atkins DHF, Cape JN et al., 1983. Acid Deposition in the United Kingdom. Stevenage, UK: Warren Spring Laboratory.
  • Bayles RA, 1991. Varietal resistance as a factor contributing to the increased importance of Septoria tritici Rob. and Desm. in the UK wheat crop. Plant Varieties and Seeds 4, 17783.
  • Bayles RA, Parry DW, Priestley RH, 1985. Resistance of winter wheat varieties to Septoria tritici. Journal of the National Institute of Agricultural Botany 17, 216.
  • Bearchell SJ, Fraaije BA, Shaw MW, Fitt BDL, 2005. Wheat archive links long-term fungal pathogen population dynamics to air pollution. Proceedings of the National Academy of Sciences, USA 102, 543842.
  • Bonjean A, Angus J, 2001. The World Wheat Book - A History of Wheat Breeding. Andover, UK: Intercept.
  • van den Bosch F, Fraaije BA, van den Berg F, Shaw MW, 2010. Evolutionary bi-stability in pathogen transmission mode. Proceedings of the Royal Society B 277, 173542.
  • Chandramohan P, 2010. Causal Relationships between Sulphur Emissions and Pathogen Abundance. Reading, UK: University of Reading, PhD thesis.
  • Cooper RM, Resende MLV, Flood J, Rowan MG, Beale MH, Potter U, 1996. Detection and localization of elemental sulphur in disease-resistant genotypes of Theobroma cacao. Nature 379, 15962.
  • Cowger C, Brunner PC, 2008. Frequency of sexual recombination by Mycosphaerella graminicola in mild and severe epidemics. Phytopathology 98, 7529.
  • Cowger C, Mundt CC, 2002. Aggressiveness of Mycosphaerella graminicola isolates from susceptible and partially resistant wheat cultivars. Phytopathology 92, 62430.
  • Faris JD, Friesen TL, 2009. Re-evaluation of a tetraploid wheat population indicates that the Tsn1–ToxA interaction is the only factor governing Stagonospora nodorum blotch susceptibility. Phytopathology 99, 90612.
  • Fowler D, Cape N, Smith R et al., 2007. Acid Deposition Processes. Final Report to DEFRA. NERC Centre for Ecology and Hydrology. [http://nora.nerc.ac.uk/4558/]. Accessed 6 Feb 2013.
  • Goodwin JWL, Salway AG, Murrells TP, Dore CJ, Passant NR, Eggleston HS, 2000. UK Emissions of Air Pollutants 1970–1998. AEA Technology. AEAT/R/EN/0270. [http://www.aeat.co.uk/netcen/airqual/naei]. Accessed 3 Dec 2011.
  • Goodwin SB, M'Barek SB, Dhillon B et al., 2011. Finished genome of the fungal wheat pathogen Mycosphaerella graminicola reveals dispensome structure, chromosome plasticity, and stealth pathogenesis. PLoS Genetics 7, e1002070.
  • Haneklaus S, Bloem E, Schnug E, 2006. Disease control by sulphur induced resistance. Aspects of Applied Biology 79, 2204.
  • Harrower KM, 1978. Effects of mixed inocula of Leptosphaeria nodorum and Septoria tritici on wheat seedlings. Transactions of the British Mycological Society 70, 415.
  • HGCA, 2008. Recommended List: Winter Wheat 2008/9. London, UK: Home-Grown Cereals Authority.
  • Jenkins PD, Jones DG, 1981. The effects of dual inoculation of wheat cultivars with Septoria tritici and Septoria nodorum. Journal of Phytopathology 101, 21021.
  • Kema GHJ, Yu D, Rijkenberg FHJ, Shaw MW, Baayen RP, 1996. Histology of the pathogenesis of Septoria tritici in wheat. Phytopathology 86, 77786.
  • Keon J, Rudd JJ, Antoniw J, Skinner W, Hargreaves J, Hammond-Kosack K, 2005. Metabolic and stress adaptation by Mycosphaerella graminicola during sporulation in its host revealed through microarray transcription profiling. Molecular Plant Pathology 6, 52740.
  • Keon J, Antoniw J, Carzaniga R et al., 2007. Transcriptional adaptation of Mycosphaerella graminicola to programmed cell death (PCD) of its susceptible wheat host. Molecular Plant–Microbe Interactions 20, 17893.
  • Khan MW, Kulshrestha M, 1991. Impact of sulphur dioxide exposure on conidial germination of powdery mildew fungi. Environmental Pollution 70, 818.
  • Khan MR, Khan MW, Pasha MJ, 1998. Effects of sulfur dioxide on the development of powdery mildew of cucumber. Environmental and Experimental Botany 40, 26573.
  • Knights JS, Zhao FJ, Spiro B, McGrath SP, 2000. Long-term effects of land use and fertilizer treatments on sulfur cycling. Journal of Environmental Quality 29, 186774.
  • Magan N, McLeod AR, 1991. Effect of open-air fumigation with sulphur dioxide on the occurrence of phylloplane fungi on winter barley. Agriculture, Ecosystems and Environment 33, 24561.
  • Mansfield PJ, Bell JNB, McLeod AR, Wheeler BEJ, 1991. Effects of sulphur dioxide on the development of fungal diseases of winter barley in an open-air fumigation system. Agriculture, Ecosystems and Environment 33, 21532.
  • Murrells TP, Passant NR, Thistlethwaite G et al., 2010. UK Emissions of Air Pollutants 1970 to 2008. Report AEAT/ENV/R/3036. Didcot, UK: AEA Technologies.
  • Neftel A, Beer J, Oeschger H, Zürcher F, Finkel RC, 1985. Sulphate and nitrate concentrations in snow from South Greenland 1895–1978. Nature 314, 61113.
  • NIAB, 1960. Descriptions of Cereal Varieties. Cambridge, UK: National Institute of Agricultural Botany.
  • NIAB, 1976. Recommended Varieties of Cereals. Cambridge, UK: National Institute of Agricultural Botany.
  • Nolan S, Cooke BM, Monahan FJ, 1999. Studies on the interaction between Septoria tritici and Stagonospora nodorum in wheat. European Journal of Plant Pathology 105, 91725.
  • Oliver RP, Friesen TL, Faris JD, Solomon PS, 2012. Stagonospora nodorum: from pathology to genomics and host resistance. Annual Review of Phytopathology 50, 2343.
  • Rodgers-Gray BS, Shaw MW, 2004. Effects of straw and silicon soil amendments on some foliar and stem-base diseases in pot-grown winter wheat. Plant Pathology 53, 73340.
  • Salac I, Haneklaus SH, Bloem E et al., 2005. Sulfur nutrition and its significance for crop resistance–a case study from Scotland. Landbauforschung Völkenrode 283, 11118.
  • Schnug E, 1997. Significance of sulphur for the nutritional and technological quality of domesticated plants. In: Cram WJ, de Kok LJ, Stulen I, Brunold C, Rennenberg H, eds. Sulfur Metabolism in Higher Plants: Molecular Ecophysiological and Nutritional Aspects. Leiden, the Netherlands: Backhuys, 10930.
  • Shaw MW, 2008. The population dynamical consequences of density-dependence in fungal plant pathogens. In: Avery SV, Stratford M, van West P, eds. Stress in Yeasts and Filamentous Fungi. Dordrecht, the Netherlands: Kluwer, 5365.
  • Shaw MW, Bearchell SJ, Fitt BDL, Fraaije BA, 2008. Long-term relationships between environment and abundance in wheat of Phaeosphaeria nodorum and Mycosphaerella graminicola. New Phytologist 177, 22938.
  • Walters DR, Bingham IJ, 2007. Influence of nutrition on disease development caused by fungal pathogens: implications for plant disease control. Annals of Applied Biology 151, 30724.
  • Zelikovitch N, Eyal Z, 1991. Reduction in pycnidial coverage after inoculation of wheat with mixtures of isolates of Septoria tritici. Plant Disease 75, 90710.
  • Zhao FJ, Knights JS, Hu ZY, McGrath SP, 2003. Stable sulfur isotope ratio indicates long-term changes in sulfur deposition in the Broadbalk experiment since 1845. Journal of Environmental Quality 32, 339.