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Characterization of seedling and adult plant resistance to stripe rust in recombinant inbred lines derived from wheat landrace PI388222 × Avocet cross

Published online by Cambridge University Press:  10 January 2020

Yesrab Aman*
Affiliation:
Department of Plant Sciences, Faculty of Biological Sciences, Quaid-i-Azam University, Islamabad- 45320, Pakistan
Fatima Khalid
Affiliation:
Department of Plant Sciences, Faculty of Biological Sciences, Quaid-i-Azam University, Islamabad- 45320, Pakistan
Muzaffar Shaukat
Affiliation:
Department of Plant Sciences, Faculty of Biological Sciences, Quaid-i-Azam University, Islamabad- 45320, Pakistan
Tariq Mahmood
Affiliation:
Department of Plant Sciences, Faculty of Biological Sciences, Quaid-i-Azam University, Islamabad- 45320, Pakistan
Syed Wasim Hasan
Affiliation:
Department of Plant Breeding and Genetics, College of Agriculture, University of Sargodha, Sargodha, Pakistan
Javed Iqbal Mirza
Affiliation:
Crop Disease Research Institute (CDRI), Pakistan Agriculture Research Council, Murree, Pakistan
*
*Corresponding author. E-mail: [email protected]

Abstract

Stripe rust caused by Puccinia striiformis f. sp. tritici (Pst), is a devastating fungal disease of wheat (Triticum aestivum L.). The best economical technique for disease control is breeding for genetic resistance to stripe rust. To find resistance genes in landrace PI388222 from Pakistan, a segregating population was developed by a cross between PI388222 and susceptible Australian spring wheat line Avocet ‘S’. The F2:4 seeds were harvested and seeds were planted in the greenhouse of Washington State University Pullman, to grow F4:5 recombinant inbred lines (RIL). A variable set of seedling reactions were noted when a set of 136 F5 and parental lines were screened with four Puccinia striiformis f. sp. tritici races (PSTv-37, PSTv-40, PSTv-4 and PSTv-51). The great proportion of RILs showed resistant reaction displayed by the RILs was against PSTv-40, for which 85% of the RILs showed resistant reaction, while less resistance to the race PSTv-37 was detected against which the resistance was for only 49% of the RILs. The RIL population was further evaluated at two locations; Palouse Conservation Field Station (PCFS) and Mount Vernon (MV). In MV field, 76% of RILs displayed resistant reaction while 15% of RILs exhibited moderate reaction. About 53% of RILs exhibited resistant reaction to four P. tritici races that were used in glasshouse screening and they were also resistant in field environments at PCFS and MV. This study demonstrates that landrace comprises partial resistance in the range of resistant to moderately resistant lines.

Type
Research Article
Copyright
Copyright © NIAB 2020

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References

Ali, S, Shah, SJA and Ibrahim, M (2007) Assessment of wheat breeding lines for slow yellow rusting (Puccinia striiformis West. tritici). Pakistan Journal of Biological Sciences 10: 34403444.Google Scholar
Ali, S, Shah, SJA, Raman, IKH, Maqbool, K and Ullah, W (2009) Partial resistance to yellow rust in introduced winter wheat germplasm at the north of Pakistan. Australian Journal of Crop Science 3: 37.Google Scholar
Bariana, HS, Brown, GN, Ahmed, NU, Khatkar, S, Conner, RL, Wellings, CR, Haley, S, Sharpe, PJ and Laroche, A (2002) Characterisation of Triticum vavilovii-derived stripe rust resistance using genetic, cytogenetic and molecular analyses and its marker-assisted selection. Theoretical and Applied Genetics 104: 315320.CrossRefGoogle Scholar
Bariana, HS, Forrest, K, Qureshi, N, Miah, H, Hayden, M and Bansal, U (2016) Adult plant stripe rust resistance gene Yr71 maps close to Lr24 in chromosome 3D of common wheat. Molecular Breeding 36: 98.CrossRefGoogle Scholar
Beddow, JM, Pardey, PG, Chai, Y, Hurley, TM, Kriticos, DJ, Braun, HJ, Park, RF, Cuddy, WS and Yonow, T (2015) Research investment implications of shifts in the global geography of wheat stripe rust. Nature Plants 1: 15132.CrossRefGoogle Scholar
Bux, H, Ashraf, M and Chen, X (2012) Expression of high-temperature adult-plant (HTAP) resistance against stripe rust (Puccinia striiformis f. sp. tritici) in Pakistan wheat landraces. Canadian Journal of Plant Pathology 34: 6874.CrossRefGoogle Scholar
Chen, XM (2005) Epidemiology and control of stripe rust [Puccinia striiformis f. sp. tritici] on wheat. Canadian Journal of Plant Pathology 27: 314337.CrossRefGoogle Scholar
Chen, XM, Line, RF and Jones, SS (1995) Chromosomal location of genes for resistance to Puccinia striiformis in winter wheat cultivars Heines VII, Clement, Moro, Tyee, Tres, and Daws. Phytopathology 85: 13621367.CrossRefGoogle Scholar
Chen, X, Penman, L, Wan, A and Cheng, P (2010) Virulence races of Puccinia striiformis f. sp. tritici in 2006 and 2007 and development of wheat stripe rust and distributions, dynamics, and evolutionary relationships of races from 2000 to 2007 in the United States. Canadian Journal of Plant Pathology 32: 315333.CrossRefGoogle Scholar
Chen, W, Wellings, C, Chen, X, Kang, Z and Liu, T (2014) Wheat stripe (yellow) rust caused by Puccinia striiformis f. sp. tritici. Molecular Plant Pathology 15: 433446.CrossRefGoogle Scholar
Cheng, P and Chen, XM (2010) Molecular mapping of a gene for stripe rust resistance in spring wheat cultivar IDO377s. Theoretical and Applied Genetics 121: 195204.CrossRefGoogle Scholar
Chhuneja, P, Kaur, S, Garg, T, Ghai, M, Kaur, S, Prashar, M, Bains, NS, Goel, RK, Keller, B, Dhaliwal, HS and Singh, K (2008) Mapping of adult plant stripe rust resistance genes in diploid A genome wheat species and their transfer to bread wheat. Theoretical and Applied Genetics 116: 313324.CrossRefGoogle Scholar
Edmeades, G, Fischer, RA and Byerlee, D (2010) Can we feed the world in 2050. In: Proceedings of the New Zealand Grassland Association, November 2010, Vol. 72, pp. 3542.Google Scholar
FAO (2015) FAO Statistical Pocketbook: World Food and Agriculture. Rome, Italy: FAOGoogle Scholar
Feng, J, Wang, M, See, DR, Chao, S, Zheng, Y and Chen, X (2018) Characterization of novel gene Yr79 and four additional quantitative trait loci for all-stage and high-temperature adult-plant resistance to stripe rust in spring wheat PI 182103. Phytopathology 108: 737747.CrossRefGoogle Scholar
Gerechter-Amital, ZK and Grama, A (1974) Inheritance of resistance to stripe rust (Puccinia striformis) in crosses between wild emmer (Triticum dicoccoides) and cultivated tetraploid and hexaploid wheats. I. Triticum durum. Euphytica 23: 387392.CrossRefGoogle Scholar
Hovmøller, MS (2001) Disease severity and pathotype dynamics of Puccinia striiformis f. sp. tritici in Denmark. Plant Pathology 50: 181189. https://maswheat.ucdavis.edu/protocols/Yr51/index.htm.CrossRefGoogle Scholar
Kankwatsa, P, Singh, D, Thomson, PC, Babiker, EM, Bonman, JM, Newcomb, M and Park, RF (2017) Characterization and genome-wide association mapping of resistance to leaf rust, stem rust and stripe rust in a geographically diverse collection of spring wheat landraces. Molecular Breeding 37: 113.CrossRefGoogle Scholar
Lin, F and Chen, XM (2007) Genetics and molecular mapping of genes for race-specific all-stage resistance and non-race-specific high-temperature adult-plant resistance to stripe rust in spring wheat cultivar Alpowa. Theoretical and Applied Genetics 114: 12771287.CrossRefGoogle Scholar
Line, RF and Qayoum, A (1992) Virulence, aggressiveness, evolution and distribution of races of Puccinia striiformis (the cause of stripe rust of wheat) in North America, 1968–87. Technical Bulletin (USA).Google Scholar
McIntosh, RA and Lagudah, ES (2000) Cytogenetical studies in wheat. XVIII. Gene Yr24 for resistance to stripe rust. Plant Breeding 119: 8193.CrossRefGoogle Scholar
Moore, JW, Herrera-Foessel, S, Lan, C, Schnippenkoetter, W, Ayliffe, M, Huerta-Espino, J, Lilemmo, M, Viccars, L, Milne, R, Peiryannan, S, Spielmeyer, W, Talbot, M, Bariana, H, Patrick, JW, Dodds, P, Singh, R and Lagudah, E (2015) A recently evolved hexose transporter variant confers resistance to multiple pathogens in wheat. Nature Genetics 47: 1494.CrossRefGoogle Scholar
Mujeeb-Kazi, A, Kazi, AG, Dundas, I, Rasheed, A, Ogbonnaya, F, Kishii, M, Bonnet, D, Wang, RRC, Xu, S, Chen, P, Mahmood, T, Bux, H and Farrakh, S (2013) Genetic diversity for wheat improvement as a conduit to food security. Advances in Agronomy 122: 179257.CrossRefGoogle Scholar
Niks, RE, Qi, X and Marcel, TC (2015) Quantitative resistance to biotrophic filamentous plant pathogens: concepts, misconceptions, and mechanisms. Annual Review of Phytopathology 53: 445470.CrossRefGoogle Scholar
Nsabiyera, V, Bariana, HS, Qureshi, N, Wong, D, Hayden, MJ and Bansal, UK (2018) Characterisation and mapping of adult plant stripe rust resistance in wheat accession Aus27284. Theoretical and Applied Genetics 131: 14591467.CrossRefGoogle Scholar
Parlevliet, JE (1988) Strategies for the utilization of partial resistance for the control of cereal rusts. In: Breeding Strategies for Resistance to the Rusts of Wheat, El Batan, Mexico (Mexico), 29 June–1 July 1987. CIMMYT.Google Scholar
Randhawa, M, Bansal, U, Valárik, M, Klocová, B, Doležel, J and Bariana, H (2014) Molecular mapping of stripe rust resistance gene Yr51 in chromosome 4AL of wheat. Theoretical and Applied Genetics 127: 317324.CrossRefGoogle Scholar
Rizwan, S, Iftikhar, A, Kazi, AM, Sahi, GM, Mirza, JI, Attiq-ur-Rehman, and Ashraf, M (2010) Virulence variation of Puccinia Striiformis Westend. F. sp. tritici In Pakistan. Archives of Phytopathology and Plant Protection 43: 875882CrossRefGoogle Scholar
Safavi, SA (2012) Evaluation of slow rusting parameters in thirty-seven promising wheat lines to yellow rust. Technical Journal of Engineering and Applied Sciences 2: 324329.Google Scholar
Shah, SJA, Hussain, S, Ahmad, M and Ibrahim, M (2014) Characterization of slow rusting resistance against Puccinia Striiformis f. sp. tritici in candidate and released bread wheat cultivars of Pakistan. Journal of Plant Pathology & Microbiology 5: 1.Google Scholar
Sthapit, J, Newcomb, M, Bonman, JM, Chen, X and See, DR (2014) Genetic diversity for stripe rust resistance in wheat landraces and identification of accessions with resistance to stem rust and stripe rust. Crop Science 54: 21312139.CrossRefGoogle Scholar
Venkata, BP, Bansal, UK, Singh, RP, Park, RF and Bariana, HS (2008) Genetic analyses of durable adult plant resistance to stripe rust and leaf rust in CIMMYT wheat genotype 11IBWSN50. International Journal of Plant Breeding 2: 6468.Google Scholar
Wan, A, Chen, X and Yuen, J (2016) Races of Puccinia Striiformis f. sp. tritici in the United States in 2011 and 2012 and comparison with races in 2010. Plant Disease 100: 966975.CrossRefGoogle Scholar
Wise, TA (2013) Can we feed the world in 2050. A scoping paper to assess the evidence. Global Development and Environment Institute Working Paper (13-04).Google Scholar
Zeven, AC (1998) Landraces: a review of definitions and classifications. Euphytica 104: 127139.CrossRefGoogle Scholar
Zhang, YM, Jun-Yi, G and Yong-Hua, Y (2003) The EIM algorithm in the joint segregation analysis of quantitative traits. Genetics Research 81: 157163.Google Scholar
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