Abstract
This review on the resistance to wheat blast disease focus on the latest knowledge useful for the breeders, but also takes into account the lacks in these knowledge. To tackle this disease, it is relevant to apply a breeding strategy which has previously proven its efficacy for obtaining rice varieties with a high level of partial and durable resistance to blast. But, incomplete information is available on wheat blast resistance. Therefore, firstly, it is necessary to adjust this breeding strategy considering the worst hypothesis corresponding to every lack of knowledge. Next, the possible invalidation of every hypothesis can allow simplifying the breeding schema and its implementation. For every lack of knowledge, the practical consequences of the corresponding worst hypothesis, the study of its validity and the consequences of its possible invalidation are explained. Scientific arguments, materials and methods details are provided with the latest available references.
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References
Aman A (2016) ‘Wheat blast’ threatens yield—farmers in 6 districts complain of infection. Dailystar March 01 http://www.thedailystar.net/backpage/wheat-blast-threatens-yield-784372 Accessed 6 Jun 2017
Anapo (2017) Trigo nacional prevé cubrir el 60% de la demanda interna http://anapobolivia.org/noticias.php?op=1&tipo=2&id=1237 Accessed 6 Jun 2017
Balfourier F, Roussel V, Strelchenko P, Exbrayat-Vinson F, Sourdille P, Boutet G, Koenig J, Ravel C, Mitrofanova O, Beckert M, Charmet G (2007) A worldwide bread wheat core collection arrayed in a 384-well plate. Theor Appl Genet 114(7):1265–1275
Ballini E, Morel JB, Droc G, Price A, Courtois B, Notteghem JL, Tharreau D (2008) Genome-wide meta-analysis of rice blast resistance genes and quantitative trait loci provides new insights into partial and complete resistance. Mol Plant-Microbe Interact 21(7):859–868
Barea G, Toledo J (1996) Identificación y zonificación de Pyricularia o brusone (Pyricularia oryzae) en el cutivo de trigo en el departamento de Santa Cruz. Santa Cruz de la Sierra, Bolivia, pp 76–86
BARI (2016) Detection and confirmation of “wheat blast disease” by BARI scientists in Bangladesh. Report, April, 2016, p 6 http://kamounlab.dreamhosters.com/pdfs/BARI_wheatblast_2016.pdf Accessed 6 Jun 2017
Barlow KK, Driscoll CJ (1981) Linkage studies involving two chromosomal male sterility mutants in hexaploid wheat. Genetics 98:791–799
Bhattacharya R, Pal S (2017) Deadly wheat blast symptoms enters India through the Bangladesh border, Bengal govt burning crops on war footing. Hindustan Times, Kolkata, Updated: Mar 05, 2017 13:52 IST http://www.hindustantimes.com/kolkata/deadly-wheat-blast-symptoms-enters-india-through-the-bangladesh-border-bengal-govt-burning-crops-on-war-footing/story-3zoWQ0H7sdMU4HxQyzWUsN.html Accessed 6 Jun 2017
Bonjean A (2001) Histoire de la culture des céréales et en particulier de celle du blé tendre (Triticum aestivum L.). In : Agriculture et biodiversité des plantes. Dossiers de l’Environnement de l’INRA (ed) no. 21, vol. 170. Paris, pp 29–37 http://www7.inra.fr/dpenv/pdf/bonjed21.pdf Accessed 6 Jun 2017
Bouet A, Vales M (2001) Importance of the rice (Oryza sp.) flowering date on the neck blast disease development (in French). Agron Afr 13(2):15–20
Bouet A, Vales M, Keli ZJ (2006) Evaluation of the rice (Oryza sp.) field resistance to neck blast disease (in French). Agron Afr 18(2):85–185
Brown J (2002) Yield penalties of disease resistance in crops. Curr Opin Plant Biol 5(4):339–344
Browne RA (2007) Components of resistance to fusarium head blight (FHB) in wheat detected in a seed-germination assay with Microdochium majus and the relationship to FHB disease development and mycotoxin accumulation from Fusarium graminearum infection. Plant Pathol 56:65–72
CABI (2016) Magnaporthe oryzae Triticum pathotype (wheat blast). Invasive species compendium. http://www.cabi.org/isc/datasheet/121970 Accessed 6 Jun 2017
Cabrera MG, Gutiérrez S (2007) Primer registro de Pyricularia grisea en cultivos de trigo del NE de Argentina. In: Jornada de Actualización en Enfermedades de Trigo. IFSC Press, Lavallol (ed), Buenos Aires, p 60
Chao-Chien J, Qualset CO (1977) Genetic male sterility in wheat (Triticum aestivum L.): reproductive characteristics and possible use in hybrid wheat breeding. Hilgardia 45(6):153–1714
Chauhan H, Boni R, Bucher R, Kuhn B, Buchmann G, Sucher J, Selter LL, Hensel G, Kumlehn J, Bigler L, Glauser G, Wicker T, Krattinger SG, Keller B (2015) The wheat resistance gene Lr34 results in the constitutive induction of multiple defense pathways in transgenic barley. Plant J 84:202–215
Chávez A, Kohli M (2015) Alternative hosts of Magnaporthe grisea of wheat in Paraguay (in Spanish). Investig Agrar 17(1):54–59
Chen HQ, Chen ZX, Ni S, Zuo SM, Pan XB, Zhu XD (2008) Pyramiding three genes with resistance to blast by marker assisted selection to improve rice blast resistance of Jin 23B. Chin J Rice Sci 22(1):23–27
Comstock CA, Martinson CA, Gengenbach BG (1973) Host specificity of a toxin from Phyllosticta maydis for Texas cytoplasmically male-sterile maize. Phytopathology 63:1357–1361
Cruz CD, Kiyuna J, Bockus WW, Todd TC, Stack JP, Valent B (2015) Magnaporthe oryzae conidia on basal wheat leaves as a potential source of wheat blast inoculum. Plant Pathol 64:1491–1514
Cruz CD, Bockus WW, Stack JP, Valent B (2016a) A standardized inoculation protocol to test wheat cultivars for reaction to head blast caused by Magnaporthe oryzae (Triticum pathotype). Plant Health Prog 17:186–187
Cruz CD, Peterson GL, Bockus WW, Kankanala P, Dubcovsky J, Jordan KW, Akhunov E, Chumley F, Baldelomar FD, Valent B (2016b) The 2NS translocation from Aegilops ventricosa confers resistance to the Triticum Pathotype of Magnaporthe oryzae. Crop Sci 56(3):990–1000
d’Alpoim Guedes J, Lu H, Li Y, Spengler RN, Wu X, Aldenderfer MS (2014) Moving agriculture onto the Tibetan plateau: the archaeobotanical evidence. Archaeol Anthropol Sci 6:255. https://doi.org/10.1007/s12520-013-0153-4
de Coelho MA, Torres M, Cecon PR, Santana FM (2016) Sowing date reduces the incidence of wheat blast disease. Pesq Agropec Bras 1(5):631–637
de Groot S (2012) Initiation of a pre-breeding programme for enhancing genetic resistance against wheat rust. Thesis presented in fulfilment of the requirements for the degree of Master of Science in the Faculty of AgriSciences at Stellenbosch University, p 160 http://scholar.sun.ac.za/handle/10019.1/71721 Accessed 6 Jun 2017
de Groot S, Botes WC (2010) Employing marker assisted recurrent mass selection in a pre-breeding strategy for accumulating disease resistance genes. In: 8th SAPBA Symposium 2010, Spier, Stellenbosch, 15–17 March 2010, P7: p 68 http://www.sapba.co.za/uploads/files/conferences/2010/8thSAPBASymposiumBooklet.pdf Accessed 6 Jun 2017
Delgado D y Vales M (1998) Escape a cepas virulentas de Pyricularia oryzae en selección genealógica en arroz (Oryza sativa) y consecuencias prácticas. In: VI Congreso de la Sociedad Colombiana de Fitomejoramiento y Producción de cultivos. Biodiversidad. 14–15 de Julio, Villavicencio, Meta, Colombia
Denancé N, Sánchez-Vallet A, Goffner D, Molina A (2013) Disease resistance or growth: the role of plant hormones in balancing immune responses and fitness costs. Front Plant Sci 4:12
Deng Y, Zhai K, Xie Z, Yang D, Zhu X, Liu J, Wang X, Qin P, Yang Y, Zhang G, Li Q, Zhang J, Wu S, Milazzo J, Mao B, Wang E, Xie H, Tharreau D, He Z (2017) Epigenetic regulation of antagonistic receptors confers rice blast resistance with yield balance. Science 355:962–965
Diekmann M, Putter CAJ (1995) Wheat blast. In: Small grain temperate cereals. International Center for Agricultural Research in the Dry Areas. Collection: FAO/IPGRI technical guidelines for the safe movement of germplasm, no. 14. FAO/IPGRI Edition, Rome, pp 51–52 http://cropgenebank.sgrp.cgiar.org/images/file/learning_space/STOG_small_grain_cereals.pdf Accessed 6 Jun 2017
Dodson JR, Lib X, Zhou X, Zhao K, Sun N, Atahan P (2013) Origin and spread of wheat in China. Quat Sci Rev 72:108–111
Dotlačil L, Stehno Z, Faberová I, Hermuth J (2011) Utilization of Czech collection of wheat genetic resources in breeding. Crop Research Institute Praha, Czech Republic. EUCARPIA, European Plant Genetic Resources Conference. Wageningen, The Netherlands April 5–7, p 24 http://www.epgrc2011.nl/docs/7-1010-Stehno.pdf Accessed 6 Jun 2017
Driscoll CJ (1975) Cytogenetic Analysis of two chromosomal male-sterility mutants in Hexaploid Wheat. Aust J Biol Sci 28:413–416
Dubina EV, Mukhina ZHM, Kharitonov EM, Shilovskiy VN, Kharchenko ES, Esaulova LV, Korkina NN, Maximenko EP, Nikitina IB (2015) Creation of blast disease-resistant rice sorts with modern DNA-markers (in Russian). Genetika 51(8):881–886
Enjalbert J, Goldringer I, David J, Brabant P (1998) The relevance of outcrossing for the dynamic management of genetic resources in predominantly selfing Triticum aestivum L. (bread wheat). Genet Sel Evol 30(Suppl. 1):S197–S211
Enjalbert J, Dawson JC, Paillard S, Rhone B, Rousselle Y, Thomas M, Goldringer I (2011) Dynamic management of crop diversity: from an experimental approach to on-farm conservation. C R Biol 334(5–6):458–468
Feistritzer WP, Bradley R, Ogada F (1975) Chapter 3. Seed production and harvesting, 25–59. In: Feistritzer WP (ed) Cereal seed technology—a manual of cereal seed production, quality control, and distribution. FAO, Rome, first published 1975 and reprinted 1977, p 266 http://www.fao.org/3/a-e8935e.pdf Accessed 6 Jun 2017
Fossati A, Ingold M (1970) A male sterile mutant in Triticum aestivum. Wheat Inf Serv 30:1–8
Galbieri R, Urashima AS (2008) Caracterização, compatibilidade e ocorrência de reprodução sexual entre isolados de Pyricularia grisea de diferentes hospedeiros. Summa Phytopathol Botucatu 34(1):22–28
Gallais A (1990) Théorie de la selection en amélioration des plantes. Masson (ed), Paris, p 588
Gastel (van) AJG, Zewdie Bishaw, Gregg BR (2002) Wheat seed production. In: Curtis BC, Rajaram S, Gómez Macpherson H Bread wheat. FAO plant production and protection series no. 30 improvement and production. http://www.fao.org/docrep/006/y4011e/y4011e0v.htm Accessed 6 Jun 2017
GNIS (2008) Règlements techniques de la production, du contrôle et de la certification des semences—Tome 1: semences de grandes cultures certifiées commerciales mélanges. Editeur Paris, GNIS, 2003, p 232 http://www.gnis-pedagogie.org/filiere-reglementation-semence-plant.html Accessed 6 Jun 2017
Gomes PD, Rocha VS, Pereira LO, Souza MA (2017) Damage of wheat blast on the productivity and quality of seeds as a function of the initial inoculum in the field. J Seed Sci 39(1):66–74
Guzmán R, Vedia A, Baek EH, Vales M (2017) Advances in participatory rice genetic improvement to face the climate change challenges in Bolivia (in Spanish). J Bol Inv Agric 1(1) [a new Journal] (in press)
Hallauer AR (1985) Compendium of recurrent selection methods and their application. CRC Crit Rev Plant Sci 3(1):1–33
Hao C, Wang L, Ge H, Dong Y, Zhang X (2011) Genetic diversity and linkage disequilibrium in chinese bread wheat (Triticum aestivum L.) Revealed by SSR Markers. PLoS ONE 6(2):13
Igarashi S, Utiamada CM, Igarashi LC, Kazuma AH, Lopes RS (1986) Pyricularia em trigo. 1. Ocorrência de Pyricularia sp. No estado do Paraná. Fitopatol Bras 11:351–352
Islam MT, Croll D, Gladieux P, Soanes DM, Persoons A, Bhattacharjee P, Hossain MS, Gupta DR, Rahman MM, Mahboob MG, Cook N, Salam MU, Surovy MZ, Sancho VB, Maciel JL, Nhani Júnior A, Castroagudín VL, Reges JT, Ceresini PC, Ravel S, Kellner R, Fournier E, Tharreau D, Lebrun MH, Mc Donald BA, Stitt T, Swan D, Talbot NJ, Saunders DG, Win J, Kamoun S (2016) Emergence of wheat blast in Bangladesh was caused by a South American lineage of Magnaporthe oryzae. BMC Biol 14(1):84
Jarosch B, Kogel K-H, Schaffrath U (1999) The Ambivalence of the barley Mlo locus: mutations conferring resistance against powdery mildew (Blumeria graminis f. sp. hordei) Enhance susceptibility to the rice blast fungus Magnaporthe grisea. MPMI 12(6):508–514
Jiang J, Friebe B, Dhaliwal HS, Martin TJ, Gill BS (1993) Molecular cytogenetic analysis of Agropyron elongatum chromatin in wheat germplasm specifying resistance to wheat streak mosaic virus. Theor Appl Genet 86(1):41
Kervella J, Goldringer I, Brabant P (1991) Recurrent selection for the breeding of autogamous species with pure line varieties: a critical review (in French). Agronomie 11(5):335–352
Klindworth DL, Norman DW, Shivcharan SM (2002) Chromosomal location of genetic male sterility genes in four mutants of hexaploid wheat. Crop Sci 42(5):1447–1450
Kohli MM, Mehta YR, Guzman E, De Viedma L, Cubilla LE (2011) Pyricularia blast—a threat to wheat cultivation. Czech J Genet Plant 47:S130–S134
Krattinger SG, Sucher J, Selter LL, Chauhan H, Zhou B, Tang M, Upadhyaya NM, Mieulet D, Guiderdoni E, Weidenbach D, Schaffrath U, Lagudah ES, Keller B (2015) The wheat durable, multipathogen resistance gene Lr34 confers partial blast resistance in rice. Plant Biotechnol J 14:1261–1268
Lantican MA, Payne TS, Sonder K, Singh R, Van Ginkel M, Baum M, Braun HJ, Erenstein O (2015) Impacts of international wheat improvement research in the World, 1994–2014. Mexico, D.F. CIMMYT, p 4 http://repository.cimmyt.org/xmlui/bitstream/handle/10883/4467/57020.pdf Accessed 6 Jun 2017
Levings CS 3rd (1990) The texas cytoplasm of maize: cytoplasmic male sterility and disease susceptibility. Science 250(4983):942–947
Maan SS, Carlson KM, Williams ND, Yang T (1987) Chromosomal arm location and gene-centromere distance of a dominant gene for male sterility in Wheat. Crop Sci 27:494–500
Maciel JLN, Ceresini PC, Castroagudin VL, Zala M, Kema GHJ, McDonald BA (2014) Population structure and pathotype diversity of the wheat blast pathogen Magnaporthe oryzae 25 years after its emergence in Brazil. Phytopathology 104(1):95–107
Malik SA, Khan MA (1943) Parasitic fungi of the North-West frontier province. Indian Agric Sci 13:522–527
Marais GF, Botes WC, Louw JH (2001) Wheat breeding based on recurrent mass selection. Cereal Res Commun 29(3/4):339–342
McRae W (1922) Report of the imperial mycologist. In: Pusa agricultural research institute scientific report 1921–1922, pp 44–50 (Rev Appl Mycol 2:258–260)
Morand S (2013) Une collection internationale de Magnaporthe oryzae pour améliorer la lutte contre la pyriculariosse. In: “les dossiers d’Agropolis International” (n° 17—octobre 2013—75 pages) ”Collections taxonomiques, collections vivantes et ressources génétiques pour la biodiversité”, p 27 http://www.agropolis.fr/pdf/publications/dossier-collections.pdf Accessed 6 Jun 2017
Notiboliviarural.com (2015) Campaña de trigo 2015 fue afectada por la enfermedad piricularia. notiboliviarural.com, Martes, 03 Noviembre 2015. http://www.notiboliviarural.com/index.php?option=com_content&view=article&id=13722:campana-de-trigo-2015-fue-afectada-por-la-enfermedad-piricularia&catid=293:agricola&Itemid=543 Accessed 6 Jun 2017
Notteghem J-L (1989) La création de variétés résistantes: cas du riz et de la pyriculariose. Bulletin de la Société Botanique de France. Actualités Botaniques 136(3–4):227–237
Pagani APS, Dianese AC, Café-Filho AC (2014) Management of wheat blast with synthetic fungicides, partial resistance and silicate and phosphite minerals. Phytoparasitica 42:609–617
Parisod C, Definod C, Sarr A, Arrigo N, Felber F (2012) Genome-specific introgression between wheat and its wild relative Aegilops triuncialis. J Evol Biol 26:223–228
Perelló A, Martinez I, Molina M (2015) First report of virulence and effects of Magnaporthe oryzae isolates causing wheat blast in Argentina. Plant Dis 99(8):1177
Pereyra S, Stewart S, Germán S (2013) Report on Magnaporthe sp. in Uruguay. INIA La Estanzuela, April 8th, 2013, p 1
Pratt K (2012) UK researchers find important new disease. UKAgNews, April 24, 2012. http://news.ca.uky.edu/article/uk-researchers-find-important-new-disease Accessed 6 Jun 2017
Rasul I, Khan AS, Ali Z (2002) Estimation of heterosis for yield and some yield components in bread Wheat. Int J Agric Biol 4(2):214–216
Romero Giraldo LE (2012) Introgression of QTLs for resistance to Hoja Blanca Virus into rice elite materials in Colombia (in Spanish). Tesis de Doctorado. Universidad Nacional de Colombia Facultad de Ciencias Agropecuarias Coordinación General de Postgrados, Palmira, Colombia, p 124
Rutkoski JE, Heffner EL, Sorrells ME (2011) Genomic selection for durable stem rust resistance in wheat. Euphytica 179(1):161–173
Salines J (2012) El cruzamiento en el mejoramiento genético de trigo. INTA Marcos Juárez: 14 min 31 s https://www.youtube.com/watch?v=xEE1sR2H1wE Accessed 6 Jun 2017
Sarkarung S (1991) A simplified crossing method for rice breeding. A manual. CIAT, p 32 https://cgspace.cgiar.org/handle/10568/69582 Accessed 6 Jun 2017
Sharma R (2017) Wheat blast research: status and imperatives. Afr J Agric Res 12(6):377–381
Spielmeyer W, Mago R, Wellings C, Ayliffe M (2013) Lr67 and Lr34 rust resistance genes have much incommon—they confer broad spectrum resistance to multiple pathogens in wheat. BMC Plant Biol 13(96):9
Springfield L (2014) Pyramiding of rust resistance genes in wheat utilizing male sterility mediated marker-assisted recurrent selection. Thesis (MSc). Stellenbosch University, p 130 http://scholar.sun.ac.za/handle/10019.1/96086 Accessed 6 Jun 2017
Stevens CJ, Murphy C, Roberts R, Lucas L, Silva F, Fuller DQ (2016) Between China and South Asia: a Middle Asian corridor of crop dispersal and agricultural innovation in the Bronze Age. Holocene 26(10):1541–1555
Taba S, van Ginkel M, Hoisington D, Poland D (2004) Wellhausen-anderson plant genetic resources center: operations manual. El Batan, Mexico, CIMMYT, p 29 http://libcatalog.cimmyt.org/download/cim/81069.pdf Accessed 6 Jun 2017
Taillebois J (1989) CNA-IRAT 5 upland rice popula-tion. Rice Res Newsl 14(3):8
Taillebois J, Castro E da M de (1986) A new crossing technique. Int Rice Res Newsl 11(6):6 https://eurekamag.com/pdf.php?pdf=001516445
Thépot S, Restoux G, Goldringer I, Hospital F, Gouache D, Mackay I, Enjalbert J (2015) Efficiently tracking selection in a multiparental population: the case of earliness in wheat. Genetics 199(2):609–623
Thomas KM (1940) Detailed administration Report of the Government Mycologist, Madras, for the year 1939–40, p 18 https://www.cabdirect.org/cabdirect/abstract/19411100313. Accessed 6 Jun 2017 https://eurekamag.com/research/013/351/013351018.php Accessed 6 Jun 2017
Trottet M (1988) Use of genic male sterility for breeding wheat lines resistant to Leptosphaeria nodorum Muller: results of a first cycle and prospect. In: Proceedings of the seventh international wheat genetics symposium, Cambridge, UK, pp 1199–1202 http://eurekamag.com/research/001/996/001996730.php Accessed 6 Jun 2017
Urashima AS, Leite SF, Galbieri R (2007) Eficiência da disseminação aérea em Pyricularia grisea. Summa Phytopathol 33(3):275–279
Urashima AS, Grosso CRF, Stabili A, Freitas EG, Silva CP, Netto DCS, Franco I, Bottan JHM (2009) Effect of Magnaporthe grisea on seed germination, yield and quality of wheat. In: Wang GL, Valent B (eds) Advances in genetics, genomics and control of rice blast disease. Springer, Dordrecht, The Netherlands, pp 267–277 https://link.springer.com/chapter/10.1007%2F978-1-4020-9500-9_27?LI=true Accessed 6 Jun 2017
Usatov AV, Kostylev PI, Azarin KV, Markin NV, Makarenko MS, Khachumov VA, Bibov MY (2016) Introgression of the rice blast resistance genes Pi1, Pi2 and Pi33 into Russian rice varieties by marker-assisted selection. Indian J Genet Plant Breed 76(1):18–23
Valent B (2016a) Novel strategies for managing blast diseases on rice and wheat. Progress report 01/01/15 to 12/31/15 http://www.reeis.usda.gov/web/crisprojectpages/0231543-novel-strategies-for-managing-blast-diseases-on-rice-and-wheat.html Accessed 6 Jun 2017
Valent B (2016b) Safeguarding U.S. wheat: Kansas State University researchers staying ahead of wheat blast disease. News and Communications Services. Kansas State University. http://www.k-state.edu/media/newsreleases/feb16/valent21116.html Accessed 6 Jun 2017
Vales M (1983) Des connaissances sur les relations hôte-parasite aux stratégies de lutte contre la pyriculariose du riz. Thèse en Amélioration et Développement des Végétaux. Université PARIS SUD, Centre d’Orsay. 2 mai 1983, p 310 http://cat.inist.fr/?aModele=afficheN&cpsidt=9626001 Accessed 6 Jun 2017, http://publications.cirad.fr/une_notice.php?dk=368523 Accessed 6 Jun 2017
Vales M (1987a) La résistance durable : cas de la pyriculariose du riz. I—Les qualités associées à la résistance durable. L’Agronomie Tropicale 42(2):103–111
Vales M (1987b) La résistance durable : cas de la pyriculariose du riz. II—Amélioration variétale de la résistance durable. L’Agronomie Tropicale 42(2):112–120
Vales M (1992) Breeding and genetic strategies to fight against phytoparasites. In: Interactions between plants and microorganisms (in French). IFS and ORSTOM, Dakar, Senegal, in February 17–22nd, 1992. IFS, Stockholm, pp 353–370 http://horizon.documentation.ird.fr/exl-doc/pleins_textes/divers15-06/40395.pdf Accessed 6 Jun 2017
Vales M (2003) Common errors in rice recurrent selection (in Spanish). In: Proc. 1st Venezuelan Congr. Plant Breeding and Agricultural Biotechnology. Central University of Venezuela, Maracay, Venezuela, 15–17 October 2003
Vales M (2004) Propuesta de Producción de semillas basicas de arroz según la reglamentación Francesa. Colaboración CIRAD-El Aceituno, p 6
Vales M (2005) Common errors in rice recurrent selection. Seminar. Food Crops Research Institute (FCRI) of Yunnan Academy of Agricultural Sciences (YAAS), Kunming, Yunnan, P. R. China
Vales M (2010) Some innovations in rice recurrent selection: The back recurrent selection (BCRS), the simplified and efficient rice breeding method (SERB), and the plant-parasite reciprocal recurrent selection (2P2RS). Crop Prot 29(4):311–317
Vales M (2012) Course on the most concrete and applied aspects of the methods of phytopathology that support the crops genetic improvement (in Spanish). March 29, 2012, CIAT, Santa Cruz de la Sierra, Santa Cruz Dept., Bolivia, p 173 https://agritrop.cirad.fr/564765/1/document_564765.pdf Accessed 6 Jun 2017
Vales M (2013) Efficient rice genetic improvement (in Spanish). Master Class (50 h) in Plant Production, January-February 2013, Autonomous Gabriel René Moreno University, Santa Cruz de la Sierra, Santa Cruz Dept., Bolivia, p 394
Vales M (2015) New prospects of collaboration YAAS-HAAS—CIRAD-Bolivian partners. Hainan Academy of Agricultural Sciences, Haiku, August 28, 2015; Yunnan Academy of Agronomical Sciences, Kunming, August 26, 2015, p 106
Vales M, Guzmán R (2013) Efficient and participatory rice genetic improvement with narrow-base recurrent populations (in Spanish). In: CD of 1st Bolivian Meeting of Agricultural and Forest Innovation—In novare 2013. August 22 and 23, 2013, Hotel Camino Real, Santa Cruz de la Sierra, Santa Cruz Dept., Bolivia, p 60
Vales M, Mello R (2013) Development of upland rice lines with wide blast resistance by marker assisted recurrent selection (MARS). MarketPlace Project [Collaboration INIAF-CIRAD—CNPAF/EMRAPA], p 4 http://www.mktplace.org/site/images/documents/ID250FinalReport.pdf Accessed 6 Jun 2017
Vales M, Vilaplana J, Kouman K, Vodouhé S (1985) Etude de la résistance complète à Pyricularia oryzae de cinq individus Oryza longistaminata et de dix hybrides interspécifiques O. sativa X O. longistaminata. L’Agronomie Tropicale 40(2):148–156
Vales M, Chatel M-H, Borrero J, Ospina Y (1998) Recurrent Selection using Rice (Oryza sativa) Populations with Narrow Genetic Base. 1st International Meeting of Rice—June 9–11, 98—La Habana, Cuba
Vales M, Dossmann J, Borrero J (2000) Delivery of the first recurrent population with narrow genetic base. Collaborative CIAT-CIRAD sub-project. Enhancement of the genetic resources for the Latin America and the Caribbean. In: Annual Report of the IP-4 Rice Project of CIAT. 2000. CIAT, Palmira. https://cgspace.cgiar.org/bitstream/handle/10568/69060/Annual%20Report%20Rice_2000.pdf Accessed 6 Jun 2017
Vales M, Borrero J, García J, Caicedo H, Cambindo F (2002) Rescue of the Traditional Rice Varieties Lost: Recovery of Genetic Resources and Traditional Knowledge. In: Annual Report 2002, International Center for Tropical Agriculture (CIAT), October 2002, pp 133–134 http://ciat-library.ciat.cgiar.org:8080/jspui/bitstream/123456789/5322/10/Annual%20Report%20Rice_2002.pdf Accessed 6 Jun 2017
Vales M, Caicedo H, Cambindo J, Alzate O, Borrero J, Arias J (2003) Genetic resources traditional and introduced in the Caucana Pacific Coast and perspective of use for the food security and sovereignty (in Spanish). In: VIII Congreso de la Sociedad Colombiana de Fitomejoramiento y Producción de Cultivos. Julio 2 al 5 del 2003, Universidad Nacional de Colombia, Bogota, Colombia, p 30 https://agritrop.cirad.fr/561676/1/document_561676.pdf Accessed 6 Jun 2017
Vales M, Seguy L, Dossmann J, Botero C, Rugeles H, Taillebois J, Bouzinac S (2006) CIRAD Rice Research Highlight: Release in Colombia of the Rice Variety ACD 25-28 in Direct Sowing Mulch Based Cropping Systems. CIRAD-El Aceituno, 3 p. Also in: Séguy, L., Bouzinac, S., 2006. Rapport annuel d’activités 2006. UR1/CIRAD-CA Brésil, 162 pp 85–87 http://open-library.cirad.fr/files/2/226__1166258880.pdf Accessed 6 Jun 2017
Vales M, Dossmann J, Delgado D, Duque MC (2009a) Parallel and interlaced recurrent selection (PAIRS): Demonstration of the feasibility of implementing PAIRS to improve complete and partial resistance to blast (Magnaporthe grisea) and some other main traits in rice. Field Crops Res 111(1–2):173–178
Vales M, Séguy L, Bouzinac S, Taillebois J (2009b) Improvement of cropping systems by integration of rice breeding: a novel genetic improvement strategy. Euphytica 167(2):161–164
Vales M, Guzmán R, Tharreau D, Adreit H, Milazzo J (2012) Bolivian experience in molecular biology for the development of the agronomy: the first results in rice (in Spanish). In: 2nd International Workshop: molecular tools for the identification of utile microorganisms—3rd Meeting of the National Network of the Scientific and Technological Research on the Food. April 11–13 of 2012, Santa Cruz de la Sierra, Bolivia: 37 pp http://agritrop.cirad.fr/564379/1/document_564379.pdf Accessed 6 Jun 2017
Vales MJ, Huallpa B, Anzoátegui T, Mostacedo B, Cazon MI (2016) Blast (Magnaporthe oryzae pv Triticum): the next major pathogen of wheat in China? The Bolivian breeding program. College of Agriculture and Biotechnology, Yunnan Agricultural University, Kunming, Yunnan, China, September 9th, p 148
Valès M (1984) Trip report in CNPAF-EMBRAPA, Goiânia, Brazil, March 7th to April 6th, IRAT, (Fr), p 30
Van der Plank JE (1963) Plant diseases; epidemics and control. Academic Press, New York & London, p 349
Viedma LQ (2005) Wheat blast occurrence in Paraguay. Centro Regional de Investigación Agrícola, Dirección de Investigación Agrícola, Ministerio de Agricultura y Ganadería, Km 16, Ruta VI, Capitán Miranda, Itapúa, Paraguay. In: Abstracts presented at the joint meeting of the APS Caribbean Division, APS Southern Division, Latin American Association of Plant Pathology, and Mexican Society for Plant Pathology in South Padre Island, Texas, April 6–11, 2003. Phytopathology 95(6 Supplement):S152. Publication no. P-2005-0020-CRA. http://apsjournals.apsnet.org/doi/pdf/10.1094/PHYTO.2005.95.6.S149 Accessed 6 Jun 2017
Vikram P, Burgueño J, Franco J, Reynolds M, Saint Pierre C, Crossa J, Guzmán García C, Payne T, Sansaloni C and Singh S (2015) Mexican and Iranian Wheat Landrace Core Collections Useful resources for the global wheat research community. Plant and Animal Genome Conference XXIII. January 10–14, 2015, San Diego, CA, USA. https://pag.confex.com/pag/xxiii/webprogram/Paper15777.html Accessed 6 Jun 2017
Wang GL, Valent B (2017) Durable resistance to rice blast. Science 355(6328):906–907
Warburton ML, Crossa J, Franco J, Kazi M, Trethowan R, Rajaram S, Pfeiffer W, Zhang P, Dreisigacker S, van Ginkel M (2006) Bringing wild relatives back into the family: recovering genetic diversity in CIMMYT improved wheat germplasm. Euphytica 149:289–301
Wingen LU, Orford S, Goram R, Leverington-Waite M, Bilham L, Patsiou TS, Ambrose M, Dicks J, Griffiths S (2014) Establishing the A. E. Watkins landrace cultivar collection as a resource for systematic gene discovery in bread wheat. Theor Appl Genet 127:1831–1842
Wulff BBH, Moscou MJ (2014) Strategies for transferring resistance into wheat: from wide crosses to GM cassettes. Front Plant Sci 5:11
Zellerhoff N, Jarosch B, Groenewald JZ, Crous PW, Schaffrath U (2006) Nonhost resistance of barley is successfully manifested against Magnaporthe grisea and a closely related Pennisetum-infecting lineage but is overcome by Magnaporthe oryzae. Mol Plant Microbe Interact 19(9):1014–1022
Acknowledgements
We would like to show our gratitude to Dr. Jerôme Enjalbert (DEAP team, GQE unit, INRA Le Moulon, France), Dr. François Balfourier (CRB team, GDEC unit, INRA Clermont Ferrand, France), and Dr. Daryl L. Klindworth (Northern Crop Sc. Lab., State University Station, NDSU, Fargo, ND, USA) for sharing very relevant wheat genetic resources needed for our proposed and initiated experiments mentioned in this review. These experiments comply with current Bolivian laws and regulations.
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Vales, M., Anzoátegui, T., Huallpa, B. et al. Review on resistance to wheat blast disease (Magnaporthe oryzae Triticum) from the breeder point-of-view: use of the experience on resistance to rice blast disease. Euphytica 214, 1 (2018). https://doi.org/10.1007/s10681-017-2087-x
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DOI: https://doi.org/10.1007/s10681-017-2087-x