The spatial distribution of canopy-resident and ground-resident cereal aphids (Sitobion avenae and Metopolophium dirhodum) in winter wheat

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• 作者：Linton Winder (1)
  Colin J. Alexander (2)
  Chris Woolley (3)
  Joe N. Perry (4)
  John M. Holland (5)
  
• 关键词：Sitobion avenae ; Metopolophium dirhodum ; Fall ; off ; Integrated pest management ; Cereal ; Aphid
• 刊名：Arthropod-Plant Interactions
• 出版年：2013
• 出版时间：February 2013
• 年：2013
• 卷：7
• 期：1
• 页码：21-32
• 全文大小：2370KB
• 参考文献：1. Alexander CJ, Holland JM, Winder L, Woolley C, Perry JN (2005) Performance of sampling strategies in the presence of known insect spatial pattern. Ann Appl Biol 146:361鈥?70 CrossRef
  2. Alyokhin A, Sewell G (2003) On-soil movement and plant colonization by walking wingless morphs of three aphid species (Homoptera: Aphididae) in greenhouse arenas. Environ Entomol 32(6):1393鈥?398 CrossRef
  3. Annan IB, Schaefers GA, Saxena KN (1999) Pattern and rate of within-field dispersal and economic of the cowpea aphid, / Aphis craccivora (Aphididae), on selected cowpea cultivars. Insect Sci Appl 19:1鈥?6
  4. Aqueel MA, Leather SR (2011) Effect of nitrogen fertilizer on the growth and survival of / Rhopalosiphum padi (L.) and / Sitobion avenae (F.) (Homoptera: Aphididae) on different wheat cultivars. Crop Prot 30:216鈥?21 CrossRef
  5. Basky Z, F贸nagy A (2007) The effect of aphid infection and cultivar on the protein content governing baking quality of wheat flour. J Sci Food Agric 87:2488鈥?494 CrossRef
  6. Bommarco R, Firle SO, Ekbom B (2007) Outbreak suppression by predators depends on spatial distribution of prey. Ecol Model 201:163鈥?70 CrossRef
  7. Bryan KM, Wratten SD (1984) The responses of polyphagous predators to prey spatial heterogeneity: aggregation by carabid and staphylinid beetles to their cereal aphid prey. Ecol Entomol 9:251鈥?59 CrossRef
  8. Chapin JW, Thomas JS, Gray SM, Smith DM, Halbert SE (2001) Seasonal abundance of aphids (Homoptera: Aphididae) in wheat and their role as barley yellow dwarf virus vectors in the South Carolina coastal plain. J Econ Entomol 94:410鈥?21 CrossRef
  9. Chaul A, Heinzl KM, Davies FT Jr (2005) Influences of fertilization on / Aphis gossypii and insecticide usage. J Appl Entomol 129:89鈥?7 CrossRef
  10. Delin S (2004) Within-field variations in grain protein content: relationships to yield and soil nitrogen and consistency in maps between years. Precision Agric 5:565鈥?77 CrossRef
  11. Dixon AFG (1987) Cereal aphids as an applied problem. Agric Zool Rev 2:1鈥?7
  12. Duffield SJ, Jepson PC, Wratten SD, Sotherton NW (1996) Spatial changes in invertebrate predation rate in winter wheat following treatment with dimethoate. Entomol Exp Appl 78:9鈥?7 CrossRef
  13. Duffield SJ, Bryson RJ, Young JEB, Sylvester-Bradley R, Scott RK (1997) The influence of nitrogen fertiliser on the population development of the cereal aphids / Sitobion avenae (F.) and / Metopolophium dirhodum (Wlk.) on field grown winter wheat. Ann Appl Biol 130:13鈥?6 CrossRef
  14. Dutilleul P (1993) Modifying the t-test for assessing the correlation between two spatial processes. Biometrics 49:305鈥?14 CrossRef
  15. Ehsan-Ul-Haq, van Emden, HF (2002) Effect of varying levels of nitrogen and potassium on the development of / Metopolophium dirhodum reared on a susceptible and a partially resistant cultivar of wheat. Pak J Zool 34:297鈥?02
  16. Ehsan-Ul-Haq, van Emden, HF (2003) Some effects of different soil moisture on development of / Metopolophium dirhodum using a susceptible and partially resistant cultivar of wheat. Pak J Zool 35:21鈥?4
  17. Evans EW (2008) Multitrophic interactions among plants, aphids, alternate prey and shared natural enemies: a review. Eur J Entomol 105:369鈥?80
  18. Finke DL, Snyder WE (2008) Niche partitioning increases resource exploitation by diverse communities. Science 321:1488鈥?490 CrossRef
  19. George KS, Gair R (1979) Crop loss assessment on winter wheat attacked by the grain aphid Sitobion avenae (F.), 1974鈥?977. Plant Pathol 28:143鈥?49 CrossRef
  20. Griffiths GJK, Wilby A, Crawley MJ, Thomas MB (2008) Density-dependent effects of predator species-richness in diversity-function studies. Ecology 89:2986鈥?993 CrossRef
  21. Harwood JD, Sunderland KD, Symondson WOC (2001) Living where the food is: web location by linyphiid spiders in relation to prey availability in winter wheat. J Appl Ecol 38:88鈥?9 CrossRef
  22. Harwood JD, Sunderland KD, Symondson WOC (2003) Web-location by linyphiid spiders: Prey-specific aggregation and foraging strategies. J Anim Ecol 72:745鈥?56 CrossRef
  23. Harwood JD, Sunderland KD, Symondson WOC (2004) Prey selection by linyphiid spiders: molecular tracking of the effects of alternative prey on rates of aphid consumption in the field. Mol Ecol 10:3549鈥?560 CrossRef
  24. Holland JM, Thomas CFG, Birkett T, Southway S (2007) Spatio-temporal distribution and emergence of beetles in arable fields in relation to soil moisture. Bull Entomol Res 97:89鈥?00 CrossRef
  25. Holland JM, Oaten H, Southway S, Moreby S (2008) The effectiveness of field margin enhancement for cereal aphid control by different natural enemy guilds. Biol Control 47:71鈥?6 CrossRef
  26. Holland JM, Birkett T, Southway S (2009) Contrasting the farm-scale spatio-temporal dynamics of boundary and field overwintering predatory beetles in arable crops. Biocontrol 54:19鈥?3 CrossRef
  27. Holland JM, Oaten H, Birkett TC, Simper J, Southway S, Smith BM (2012) Agri-environment scheme enhancing ecosystem services: a demonstration of improved biological control in cereal crops. Agric Ecosyst Environ 155:147鈥?52 CrossRef
  28. Honek A (1991) Nitrogen fertilization and abundance of the cereal aphids / Metopolophium dirhodum and / Sitobion avenae (Homoptera, Aphididae). Zeitschrift fur Pflanzenkrankheiten und Pflanzenschutz 98:655鈥?60
  29. Hon锚k A, Martinkov谩 Z (2002) Factors of between- and within-plant distribution of / Metopolophium dirhodum (Hom., Aphididae) on small grain cereals. J Appl Entomol 126:378鈥?83 CrossRef
  30. Irwin EI, Kampmeier GE, Weisser WW (2007) Aphid movement: process and consequences. In: van Emden H, Harrington R (eds) Aphids as crop pests. CAB International, Wallingford, pp 153鈥?86
  31. Kerzicnik LM, Peairs FB, Harwood JD (2010) Implications of Russian wheat aphid, / Diuraphis noxia, falling rates for biological control in resistant and susceptible winter wheat. Arthropod-Plant Interact 4:129鈥?38 CrossRef
  32. Khan M, Port G (2008) Performance of clones and morphs of two cereal aphids on wheat plants with high and low nitrogen content. Entomol Sci 11:159鈥?65 CrossRef
  33. Losey JE, Denno RF (1998) Positive predator鈥損redator interactions: enhanced predation rates and synergistic suppression of aphid populations. Ecology 79:2143鈥?152
  34. Minoretti N, Weisser WW (2000) The impact of individual ladybirds ( / Coccinella septempunctata, Coleoptera: Coccinellidae) on aphid colonies. Eur J Entomol 97:475鈥?79
  35. Monsrud C, Toft S (1999) The aggregative numerical response of polyphagous predators to aphids in cereal fields: attraction to what? Ann Appl Biol 134:265鈥?70 CrossRef
  36. M枚wes M, Freier B, Heimann J (1997) Variation in yield loss per aphid-day due to / Sitobion avenae-infestation in high yielding winter wheat. Zeitschrift fur Pflanzenkrankheiten und Pflanzenschutz 104:569鈥?75
  37. Perry JN, Dixon PM (2002) A new method to measure spatial association for ecological count data. Ecoscience 9:133鈥?41
  38. Perry JN, Winder L, Holland JM, Alston RD (1999) Red鈥揵lue plots for detecting clusters in count data. Ecol Lett 2:106鈥?13 CrossRef
  39. Romero S, Harwood JD (2010) Prey utilization by a community of linyphiid spiders: variation across diel and seasonal gradients. Biol Control 52:84鈥?0 CrossRef
  40. Rowntree JK, McVennon A, Prezios RF (2010) Plant genotype mediates the effects of nutrients on aphids. Oecologia 163:675鈥?79 CrossRef
  41. Ruppel RF (1983) Cumulative insect-days as an index of crop protection. J Econ Entomol 76:375鈥?77
  42. Schmidt MH, Lauer A, Purtauf T, Thies C, Schaefer M, Tscharntke T (2003) Relative importance of predators and parasitoids for cereal aphid control. Proc Royal Soc London B Biol Sci 270:1905鈥?909 CrossRef
  43. Schmidt MH, Thewes U, Thies C, Tscharntke T (2004) Aphid suppression by natural enemies in mulched cereals. Entomol Exp Appl 113:87鈥?3 CrossRef
  44. Sopp PI, Sunderland KD, Coombes DS (1987) Observations on the number of cereal aphids on the soil in relation to aphid density in winter wheat. Ann Appl Biol 111:53鈥?7 CrossRef
  45. Sunderland KD, Fraser AM, Dixon AFG (1986) Field and laboratory studies on money spiders (Linyphiidae) as predators of cereal aphids. J Appl Ecol 23:433鈥?47 CrossRef
  46. Symondson WOC, Sunderland KD, Greenstone MH (2002) Can generalist predators be effective biocontrol agents? Annu Rev Entomol 47:561鈥?94 CrossRef
  47. Trumble JT, Nakakihara H, Zehnder GW (1982) Comparisons of traps and visual searches of foliage for monitoring aphid (Heteroptera: Aphididae) population density in broccoli. J Econ Entomol 75:853鈥?56
  48. Tscharntke T, Bommarco R, Clough Y, Crist TO, Kleijn D, Rand TA, Tylianakis JM, van Nouhuys S, Vidal S (2007) Conservation biological control and enemy diversity on a landscape scale. Biol Control 43:294鈥?09 CrossRef
  49. van Emden HF, Harrington R (eds) (2007) Aphids as Crop Pests. CABI, Wallingford
  50. Winder L (1990) Predation of the cereal aphid / Sitobion avenae by polyphagous predators on the ground. Ecol Entomol 101:569鈥?74
  51. Winder L, Hirst DJ, Carter N, Wratten SD, Sopp PI (1994) Estimating predation of the grain aphid / Sitobion avenae by polyphagous predators. J Appl Ecol 31:1鈥?2 CrossRef
  52. Winder L, Perry JN, Holland JM (1999) The spatial and temporal distribution of the grain aphid / Sitobion avenae in winter wheat. Entomol Exp Appl 93:277鈥?90 CrossRef
  53. Winder L, Alexander CJ, Holland JM, Woolley C, Perry JN (2001) Modelling the dynamic spatio-temporal response of predators to transient prey patches in the field. Ecol Lett 4:568鈥?76 CrossRef
  54. Winder L, Griffiths GJK, Perry JN, Alexander CJ, Holland JM, Kennedy PJ, Birt A (2005) The role of large-scale spatially explicit and small-scale localized processes on the population dynamics of cereal aphids. Bull Entomol Res 95:579鈥?87
  55. Zadoks JC, Chang TT, Konzak CF (1974) A decimal code for the growth stages of cereals. Weed Res 14:415鈥?21 CrossRef
  
• 作者单位：Linton Winder (1)
  Colin J. Alexander (2)
  Chris Woolley (3)
  Joe N. Perry (4)
  John M. Holland (5)
  
  1. Department of Natural Sciences, Faculty of Social and Health Sciences, Unitec Institute of Technology, Auckland, New Zealand
  2. Biomathematics and Statistics Scotland, BioSS Office, The James Hutton Institute, Invergowrie, Dundee, Scotland, UK
  3. 41 Green End, Fen Ditton, Cambridge, Cambridgeshire, CB5 8SX, UK
  4. Plant and Insect Ecology Division, Rothamsted Research, Rothamsted, Harpenden, Herts, UK
  5. Farmland Ecology Unit, Game and Wildlife Conservation Trust, Fordingbridge, Hants, SP6 1EF, UK
  

文摘

We investigated, within two cereal fields in Southern England, the within-canopy spatial distribution of the aphids Sitobion avenae and Metopolophium dirhodum in relation to crop yield and plant nitrogen. We extended the study to investigate the spatial distribution of aphids that fell to, or returned from, the ground in order to estimate availability of the within-canopy aphid population to ground-active predators. We revealed that crop canopy aphid spatial pattern was associated with nitrogen or yield. Differences were evident between species: S. avenae was generally negatively associated with yield or plant nitrogen, whilst M. dirhodum exhibited positive association. For both aphid species, we observed strong spatial pattern for aphids falling to the ground and conclude that this could, in part, mediate the effectiveness of ground-active predators as pest control agents.