Utilization of a major brown rust resistance gene in sugarcane breeding

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• 作者：Neil C. Glynn (1)
  Chris Laborde (3)
  R. Wayne Davidson (4)
  Mike S. Irey (2)
  Barry Glaz (1)
  Angélique D’Hont (5)
  Jack C. Comstock (1)
  
• 关键词：Sugarcane (Saccharum spp.) ; Brown rust ; Puccinia melanocephala ; Marker ; assisted selection
• 刊名：Molecular Breeding
• 出版年：2013
• 出版时间：February 2013
• 年：2013
• 卷：31
• 期：2
• 页码：323-331
• 全文大小：347KB
• 参考文献：1. Asnaghi C, D’hont A, Glaszmann J, Rott P (2001) Resistance of sugarcane cultivar R 570 to / Puccinia / melanocephala isolates from different geographic locations. Plant Dis 85:282-86 CrossRef
  2. Asnaghi C, Roques D, Ruffel S, Kaye C, Hoarau JY, Telismart H, Girard J, Raboin L, Risterucci A, Grivet L (2004) Targeted mapping of a sugarcane rust resistance gene ( / Bru1) using bulked segregant analysis and AFLP markers. Theor Appl Genet 108:759-64 CrossRef
  3. Comstock JC (1987) Rust. Varietal differences in urediospore production. Hawaii. Sugar Plant Assoc Exp Stn Annu Rep 1986, p 31
  4. Comstock JC, Shine J Jr, Raid RN (1992) Effect of rust on sugarcane growth and biomass. Plant Dis 76:175-77 CrossRef
  5. Costet L, Le Cunff L, Royaert S, Raboin L-M, Hervouet C, Toubi L, Telismart H, Garsmeur O, Rousselle Y, Pauquet J, Nibouche S, Glaszmann J-C, Hoarau J-Y, D’Hont A (2012) Haplotype structure around / Bru1 reveals a narrow genetic basis for brown rust resistance in modern sugarcane cultivars. Theor Appl Genet 125:825-36
  6. Daugrois J, Grivet L, Roques D, Hoarau J, Lombard H, Glaszmann J, D’Hont A (1996) A putative major gene for rust resistance linked with a RFLP marker in sugarcane cultivar ‘R570- Theor Appl Genet 92:1059-064 CrossRef
  7. Dean J, Purdy L (1984) Races of the sugar cane rust fungus, / Puccinia / melanocephala, found in Florida. Sugar Cane 1:15-6
  8. Glynn NC, Dixon LJ, Castlebury LA, Szabo LJ, Comstock JC (2010) PCR assays for the sugarcane rust pathogens / Puccinia kuehnii and / P. melanocephala and detection of a SNP associated with geographic distribution in / P. kuehnii. Plant Path 59:703-11 CrossRef
  9. Hogarth D, Ryan C, Taylor P (1993) Quantitative inheritance of rust resistance in sugarcane. Field Crops Res 34:187-93 CrossRef
  10. Hoy J, Hollier C (2009) Effect of brown rust on yield of sugarcane in Louisiana. Plant Dis 93:1171-174 CrossRef
  11. Johnson RM, Grisham MP, Richard EP Jr (2007) Relationship between sugarcane rust severity and soil properties in Louisiana. Phytopathology 97:748-55 CrossRef
  12. Kolmer J (1996) Genetics of resistance to wheat leaf rust 1. Annual Rev Phytopath 34:435-55 CrossRef
  13. Le Cunff L, Garsmeur O, Raboin LM, Pauquet J, Telismart H, Selvi A, Grivet L, Philippe R, Begum D, Deu M (2008) Diploid/polyploid syntenic shuttle mapping and haplotype-specific chromosome walking toward a rust resistance gene ( / Bru1) in highly polyploid sugarcane (2n-2x?~?115). Genetics 180:649-60 CrossRef
  14. Legendre BL, Gravois KA (2005) The 2004 Louisiana sugarcane variety survey. Sugar Bull 89:15-1
  15. McFarlane SA, Meyer JH, Cadet P, Rutherford RS (2008) Investigation into the effect of nutrition on brown rust development in sugarcane Investigation into the effect of nutrition on brown rust development in sugarcane. Proc S Afr Sug Technol Ass 81:388-92
  16. Priestly R (1978) Detection of increased virulence in populations of wheat yellow rust. In: Scott PR, Bainbridge A (eds) Plant disease epidemiology. Oxford, Blackwell Scientific, pp 63-0
  17. Purdy L, Liu LJ, Dean J (1983) Sugarcane rust, a newly important disease. Plant Dis 67:1292-296 CrossRef
  18. Purdy L, Krupa S, Dean J (1985) Introduction of sugarcane rust into the Americas and its spread to Florida. Plant Dis 69:689-93 CrossRef
  19. Raid RN, Comstock JC (2006) Sugarcane rust disease (SS-AGR-207). In: Gilbert RA (ed) Florida sugarcane handbook, 1st Edition 1991, revised 2006 [Online]. Agronomy Department, Florida Cooperative Extension Service, Institute of Food and Agricultural Sciences, University of Florida. Available: http://edis.ifas.ufl.edu. 27 Aug 2007
  20. Ramdoyal K, Sullivan S, Chong LLS, Badaloo G, Saumtally S, Domaingue R (2000) The genetics of rust resistance in sugar cane seedling populations. Theor Appl Genet 100:557-63
  21. Rice RW, Baucum L, Glaz B (2011) Sugarcane variety census: Florida 2010. Sugar J 74:13-9
  22. Shine JM Jr, Comstock JC, Dean JL (2005) Comparison of five isolates of sugarcane rust and differential reaction on six sugarcane clones. Proc Int Soc Sugar Cane Technol 25:638-47
  23. Srinivasan KV, Muthaiyan MC (1965) A note on physiological races in / Puccinia / erianthi Padu & Khan affecting sugarcane varieties. Proc Int Soc Sugar Cane Technol 12:1126-128
  24. Van der Plank JE (1963) Plant diseases. Epidemics and control. Academic Press, New York
  25. Wolfe M, McDermott J (1994) Population genetics of plant pathogen interactions: the example of the / Erysiphe graminis-em class="a-plus-plus">Hordeum vulgare pathosystem. Ann Rev Phytopath 32:89-13 CrossRef
  
• 作者单位：Neil C. Glynn (1)
  Chris Laborde (3)
  R. Wayne Davidson (4)
  Mike S. Irey (2)
  Barry Glaz (1)
  Angélique D’Hont (5)
  Jack C. Comstock (1)
  
  1. USDA-ARS Sugarcane Field Station, 12990 US Highway 441?N, Canal Point, FL, 33438, USA
  3. Florida Crystals, Okeelanta Sugar Mill, 21250 US Highway 27, South Bay, FL, 33493, USA
  4. Florida Sugar Cane League, Inc., P.O. Box 1208, Clewiston, FL, 33440, USA
  2. United States Sugar Corporation, 111 Ponce de Leon Ave., Clewiston, FL, 33440, USA
  5. CIRAD, UMR AGAP, Montpellier, France
  
• ISSN：1572-9788

文摘

Brown rust, caused by Puccinia melanocephala, has had devastating effects on sugarcane (Saccharum spp.) breeding programs and commercial production. The discovery of Bru1, a major gene conferring resistance to brown rust, represented a substantial breakthrough. Markers for Bru1 are the first available for sugarcane molecular breeding. The contribution of Bru1 towards brown rust resistance in the Canal Point (CP) sugarcane breeding program was determined as a means of directing future breeding strategies. Bru1 was detected in 285 of 1,072 (27?%) clones used for crossing; this germplasm represents the genetic base for cultivar development in Florida. The frequency of Bru1 was greatest in CP clones (42?%) and lowest among Louisiana clones (6?%). Bru1 was not detected in clones with year assignments before 1953. However, Bru1 frequency increased from 15?% (assignments 1975-985) to 47?% in the current decade. The increase coincided with the introduction of brown rust to Florida. Bru1 was detected in 155 (32?%) of 485 parental clones tested for brown rust susceptibility at two field locations. Of clones classed resistant to brown rust, 154 (59?%) contained Bru1, yet none of 100 susceptible clones contained the gene. Bru1 was detected in 667 (44?%) clones in the second clonal stage of selection, 87?% of which were free of brown rust symptoms. Bru1 is the predominant source of resistance in the Florida sugarcane genetic base. Efforts to identify and integrate new brown rust resistance genes must be pursued to minimize risks associated with a future breakdown in major gene resistance provided by Bru1.