Evaluation of Verticillium wilt resistance in commercial cultivars and advanced breeding lines of cotton

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• 作者：Huiping Zhou (1)
  Hui Fang (1)
  Soum Sanogo (2)
  Sidney E. Hughs (3)
  Don C. Jones (4)
  Jinfa Zhang (1)
  
• 关键词：Cotton ; Germplasm ; Verticillium wilt ; Resistance
• 刊名：Euphytica
• 出版年：2014
• 出版时间：April 2014
• 年：2014
• 卷：196
• 期：3
• 页码：437-448
• 全文大小：246 KB
• 参考文献：1. Blasingame D, Patel MV (2005) Cotton disease loss estimate committee report. Proceedings of the Beltwide Cotton Conference, pp 259-62
  2. Bolek Y, Bell A, El-Zik K, Thaxton P, Magill C (2005) Reaction of cotton cultivars and an F₂ population to stem inoculation with isolates / Verticillium dahliae. J Phytopathol 153:269-73 CrossRef
  3. Cirulli M, Colella C, D’Amico M, Amenduni M, Bubici G (2008) Comparison of screening methods for the evaluation of olive resistance to / Verticillium dahliae Kleb. J Plant Pathol 90:7-4
  4. Colella C, Miacola C, Amenduni M, D’Amico M, Bubici G, Cirulli M (2008) Sources of Verticillium wilt resistance in wild olive germplasm from the Mediterranean region. Plant Pathol 57:533-39 CrossRef
  5. Devey M, Rosielle A (1986) Relationship between field and greenhouse ratings for tolerance to Verticillium wilt on cotton. Crop Sci 26:1- CrossRef
  6. Diwan N, Fluhr R, Eshed Y, Zamir D, Tanksley S (1999) Mapping of / Ve in tomato: a gene conferring resistance to the broad-spectrum pathogen, / Verticillium dahliae race 1. Theor Appl Genet 98:315-19 CrossRef
  7. Fang H, Zhou H, Sanogo S, Flynn R, Percy RG, Hughs SE, Ulloa M, Jones DC, Zhang JF (2013a) Quantitative trait locus mapping for Verticillium wilt resistance in a backcross inbred line population of cotton ( / Gossypium hirsutum?×? / Gossypium barbadense) based on RGA-AFLP analysis. Euphytica 194:79-1 CrossRef
  8. Fang H, Zhou H, Sanogo S, Lipka AE, Fang DD, Percy RG, Hughs SE, Jones DC, Gore MA, Zhang JF (2013b) Quantitative trait locus analysis of Verticillium wilt resistance in an introgressed inbred line population of Upalnd cotton. Mol Breed. doi:10.1007/s/11032-013-9987-9
  9. G?re ME, Caner ?K, Alt?n N, Ayd?n MH, Erdo?an O, Filizer F, Büyükd??erlio?lu A (2009) Evaluation of cotton cultivars for resistance to pathotypes of / Verticillium dahliae. Crop Prot 28:215-19 CrossRef
  10. Gossen B, Jefferson P (2004) A novel source of resistance to Verticillium wilt in alfalfa. Can J Plant Sci 84:401-04 CrossRef
  11. Karademir E, Karademir C, Ekinci R, Baran B, Sagir A (2012) Effect of / Verticillium dahliae Kleb. on cotton yield and fiber technological properties. Int J Plant Prod 6:387-07
  12. Lüders RR, Galbieri R, Fuzatto MG, Cia E (2008) Inheritance of resistance to Verticillium wilt in cotton. Crop Breed Appl Biotechnol 8:265-70 CrossRef
  13. Marani A, Yaacobi YZ (1976) Evaluation of Verticillium wilt tolerance in Upland cotton relative to lint yield reduction. Crop Sci 16:392-95 CrossRef
  14. Miranda BEC, Boiteux LS, Cruz EM, Reis A (2010) Sources of resistance to / Verticillium dahliae races 1 and 2 in accessions of / Solanum (section / Lycopersicon). Hort Brasil 28:458-65 CrossRef
  15. Oakley S (1998) Breeding for resistance to Verticillium wilt and root-knot nematode in California Acalas. Proceedings of the Beltwide Cotton Conf, p. 128
  16. Paplomatas E, Bassett D, Broome J, DeVay J (1992) Incidence of Verticillium wilt and yield losses of cotton cultivars ( / Gossypium hirsutum) based on soil inoculum density of / Verticillium dahliae. Phytopathology 82:1417-420 CrossRef
  17. Tiwari RS, Picchioni GA, Steiner RL, Jones DC, Hughs SE, Zhang JF (2013) Genetic variation in salt tolerance at the seedling stage in an interspecific backcross inbred line population of cotton. Euphytica 194:1-1 CrossRef
  18. USDA-ERS (2013) Cotton and wool outlook. http://www.ers.usda.gov/publications/cws-cotton-and-wool-outlook/cws-13i.aspx#.UjnnW83nbIU. Accessed 23 Sept 2013
  19. USDA-NASS (2011) Arizona field office 2011 annual statistic bulletin. http://www.nass.usda.gov/Statistics_by_State/Arizona/Publications/Bulletin/11bul/main.htm. Accessed 23 Sept 2013
  20. Wheeler T, Woodward J (2010) Response of cotton cultivars to diseases on the Southern High Plains of Texas. http://lubbock.tamu.edu/files/2011/11/ DiseaseRecommendations.pdf. Accessed 23 Sept 2013
  21. Wheeler T, Woodward J (2012) Response of cotton cultivars to diseases on the Texas high plains. http://lubbock.tamu.edu/files/2013/02/2012-cotton-disease-ratings.pdf. Accessed 23 Sept 2013
  22. Wilhelm S, Sagen JE, Tietz H (1974) Resistance to Verticillium wilt in cotton: sources, techniques of identification. inheritance trends, and the resistance potential of multiline cultivars. Phytopathology 64:924-31 CrossRef
  23. Yang C, Guo W, Li G, Gao F, Lin S, Zhang T (2008) QTLs mapping for Verticillium wilt resistance at seedling and maturity stages in / Gossypium barbadense L. Plant Sci 174:290-98 CrossRef
  24. Zhang JF, Lu Y, Adragna H, Hughs E (2005) Genetic improvement of New Mexico Acala cotton germplasm and their genetic diversity. Crop Sci 45:2363-373 CrossRef
  25. Zhang JF, Sanogo S, Flynn R, Baral JB, Bajaj S, Hughs S, Percy RG (2012) Germplasm evaluation and transfer of Verticillium wilt resistance from Pima ( / Gossypium barbadense) to Upland cotton ( / G. hirsutum). Euphytica 187:147-60 CrossRef
  26. Zhang JF, Fang H, Zhou HP, Hughs SE, Jones DC (2013a) Inheritance and transfer of thrips resistance from Pima cotton to Upland cotton. J Cotton Sci 17:163-69
  27. Zhang JF, Fang F, Zhou HP, Sanogo S, Ma ZY (2013b) Genetics, breeding, and marker-assisted selection for Verticillium wilt resistance in cotton. Crop Sci (accepted)
  28. Zhou HP (2013) Evaluation of Upland cotton germplasm for Verticillium wilt resistance and its association with SSR markers. M.S. Thesis, New Mexico State University, Las Cruces
  
• 作者单位：Huiping Zhou (1)
  Hui Fang (1)
  Soum Sanogo (2)
  Sidney E. Hughs (3)
  Don C. Jones (4)
  Jinfa Zhang (1)
  
  1. Department of Plant and Environmental Sciences, New Mexico State University, Las Cruces, NM, USA
  2. Department of Entomology, Plant Pathology and Weed Science, New Mexico State University, Las Cruces, NM, USA
  3. Southwestern Cotton Ginning Research Laboratory, USDA-ARS, Mesilla Park, NM, 88047, USA
  4. Cotton Incorporated, Cary, NC, USA
  
• ISSN：1573-5060

文摘

Verticillium wilt (VW), caused by Verticillium dahliae Kleb, is one of the most destructive diseases in cotton (Gossypium spp.). The most efficient and cost-effective method of controlling the disease is the use of resistant cotton cultivars. Most commercial cultivars and elite breeding lines are developed under non-VW conditions and their responses to the disease are currently unknown. This study was conducted to evaluate current commercial cotton cultivars and advanced breeding lines for VW resistance. In 2011-013, a total of 84 cultivars from major US seed companies, 52 advanced breeding lines from the US public breeding programs, and 87 introgression lines from a cross between Acala 1517-99?×?Pima PHY 76 from the New Mexico Cotton Breeding Program, were evaluated for VW resistance in the greenhouse. Cotton cultivars and breeding lines were evaluated in ten separate replicated tests by inoculation with a defoliating-type isolate of V. dahliae. While leaf severity rating and percentages of infected plants, infected leaves and defoliated leaves were found to be significantly and positively correlated with one another, leaf severity rating and percentage of infected leaves were best choices because of their relatively low coefficients of variation and higher resolutions to differentiate resistant genotypes from susceptible ones. The heritabilities for the VW resistance traits ranged from 0.58 to 0.80 with an average of 0.67, indicating that variation in VW resistance is predominantly due to genetic factors. Of the 223 commercial cultivars and advanced lines, six Upland cultivars (FM 9160B2F, FM 9170 B2F, NG 4010 B2RF, Nitro 44 B2RF, DP 1219 B2RF, and ST 4288 B2F), five advanced lines (Ark 0403-3, MD 10-5, MD 25ne, NC11AZ01, and PD 0504), two introgression lines from Upland?×?Pima (NM11Q1157 and 08N1618), and four Pima cultivars (COBALT, DP 357, PHY 800, and PHY 830) had higher levels of resistance to VW. The resistance shown by most of these cultivars in the greenhouse was consistent with their performance in previous field tests. Based on the initial VW resistance, 19 highly or moderately resistant genotypes were chosen for re-evaluation and 30 genotypes were also assessed more than once for VW resistance in different tests, most of which had concordant performance. These cultivars and advanced lines should be useful resources to improve VW resistance in cotton breeding.