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Journal of Crop Health

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22.12.2023 | Review Article / Übersichtsbeitrag

Insights into Wheat Blast: Its Epidemiology, Recent Advances and Management Strategies

verfasst von: Sunita Mahapatra, Sunanda Chakraborty, Debanjana Debnath, Chandan Roy

Erschienen in: Journal of Crop Health | Ausgabe 2/2024

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Abstract

The Wheat blast (WB) causing fungus Magnaporthe oryzae pathotype Triticum (MoT) is still a major challenge to researchers, despite its discovery in the 1980s in Brazil. The disease single-handedly compromised the food security of Latin American countries, after wiping out acres of wheat fields in the region in 1990s and early 2000s. The rapidly evolving ability of the fungus, its multitude of alternate hosts, development of fungicidal resistance and its acclimatization into newer geographical niches has converted it into a killer disease. The outbreak of WB in Bangladesh and its subsequent detection in Zambia has questioned the available knowledge on the pathogen, its biology, and management strategies. The dependence of WB on epidemiological factors has aggravated the situation further. The pathogen is air borne, which helps in easy transmission to uninfected areas. Additionally, lacunae in international seed movement policies have aided in tarns-continental transmission of infected seed, as seen in case of Bangladesh. The present review deals with the present status of wheat blast in the infected countries across the globe, and the management strategies employed by them to restrict the disease under the economic threshold. We describe the importance of epidemiological studies in WB management and recent advances made in developing suitable forecasting models against WB. A brief description has also been provided about the ongoing research regarding development of integrated management strategies, including quarantine, cultural practices, resistant sources and fungicidal applications, which would be immensely beneficial in preventing a disease outbreak in the future.

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Aghnoum R, Bvindi C, Menet G, Dhoop B, Maciel JL, Niks RE (2019) Host/nonhost status and genetics of resistance in barley against three pathotypes of Magnaporthe blast fungi. Euphytica 215(7):1–9CrossRef

Alberione E, Bainotti C, Cettour I, Salines J (2007) Evaluation of diseases in summer planting wheat in the Argentine-Campana NEA 2007/2008. In: 7th National Congress of Wheat La Pampa

Alves KJP, Fernandes JMC (2006) Influence of temperature and relative air humidity on the sporulation of Magnaporthe grisea on wheat. Fitopatol Brasil 31:579–584CrossRef

Anh VL, Inoue Y, Asuke S et al (2018) Rmg8 and Rmg7, wheat genes for resistance to the wheat blast fungus, recognize the same avirulence gene AVR-Rmg8. Mol Plant Pathol 19:1252–1256PubMedCrossRef

Ascari JP, Barro JP, Santana FM et al (2021) Sequential post-heading applications for controlling wheat blast: a 9-year summary of fungicide performance in Brazil. Plant Dis 105(12):4051–4059. https://doi.org/10.1094/pdis-06-21-1183-reCrossRefPubMed

Ashizawa T, Zenbayashi KS, Koizumi S, Sasahara M, Ohba A, Hori T, Ishikawa K, Sasaki K, Kuroda Y, Harasawa T (2005) Evaluation of a leaf blast simulation model (BLASTMUL) for rice multilines in different locations and cultivars, and effective blast control using the model. In: Proceedings of the world rice research conference Tokyo, pp 477–479

Bishnoi SK, Xinyao H, Mahapatra S, Singh G, Joshi AK, Singh GP, Singh PK (2021) Wheat Blast: frontiers and milestones. In: Bisnoi SK, Khan H, Singh SK, Singh GP (eds) Breeding frontiers in wheat. Agrobios, pp 241–268. ISBN 978-81-949237-5‑6

Bishnoi SK, Kumar S, Singh PK, Singh SK, Mahapatra S, Singh C, Singh G, Singh GP (2022) Wheat blast: a biosecurity threat looming large. In: Kashyap PL, Gupta V, Gupta OP, Sendhil R, Gopalreddy K, Jasrotia P, Singh GP (eds) New horizons in wheat and barley research. Springer, Singapore, pp 243–264 https://doi.org/10.1007/978-981-16-4449-8_11CrossRef

Buerstmayr H, Mohler V, Kohli M (2017) Advances in control of wheat diseases: Fusarium head blight, wheat blast and powdery mildew. In: Langridge P (ed) breeding, quality traits, pests and diseases. Achieving sustainable cultivation of wheat, vol 1. Burleigh Dodds Science Publishing, London, pp 345–337

Cabrera MG, Gutierrez SA (2007) Primer registro de Pyriculariaoryzae en cultivos de trigodel NE de Argentina. In: AstizGasso M, Molina M (eds) Jornada de Actualización en Enfermedades de Trigo. InstitutoFitotécnico de Santa Catalina, Lavallol, pp 18–180

Callaway E (2016) Devastating wheat fungus appears in Asia for first time. Nature 532:421–422PubMedCrossRef

Calvero SB Jr, Teng PS (1991) BLASTSIM. 2‑a model for tropical leaf blast-rice pathosystem. In: 22. Pest Management Council of the Philippines Manila

Cardoso CAA, Reis EM, Moreira EN (2008) Development of a warning system for wheat blast caused by Pyricularia grisea. Summa Phytopathol 34:216–221CrossRef

Castroagudín VL, Ceresini PC, de Oliveira SC et al (2015) Resistance to QoI fungicides is widespread in Brazilian populations of the wheat blast pathogen Magnaporthe oryzae. Phytopathology 105(3):284–294PubMedCrossRef

Ceresini PC, Castroagudín VL, Rodrigues FÁ et al (2018) Wheat blast: past, present, and future. Annu Rev Phytopathol 56:20.1–20.36CrossRef

Ceresini PC, Castroagudín VL, Rodrigues FÁ et al (2019) Wheat blast: from its origins in South America to its emergence as a global threat. Mol Plant Pathol 20:155–172PubMedCrossRef

Coelho MDO, Torres GM, Cecon PR, Santana FM (2016) Sowing date reduces the incidence of wheat blast disease. Pesq agropec bras 51:631–637CrossRef

CONAB (Cia. Nac. Abast.) (2017) Acompanhamento da Safra Brasileira: Graos. Safra 2016/2017 Oitavo Levantamento, Bras’ılia. vol 4. Braz (Cia. Nac. Abast)

Cruppe G, Cruz CD, Peterson G et al (2020) New sources of wheat head blight resistance in modern breeding lines and wheat wild relatives. Plant Dis 104:35–43PubMedCrossRef

Cruz CD, Bockus WW, Stack JP, Valent B, Maciel JN, Peterson GL (2016a) A standardized inoculation protocol to test wheat cultivars for reaction to head blast caused by Magnaporthe oryzae (Triticum pathotype). Plant Health Prog 17(3):186–187CrossRef

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 56:990–1000PubMedPubMedCentralCrossRef

Cruz MFA, Rios JA, Araujo L, Rodrigues FA (2016c) Infection process of Pyricularia oryzae on the leaves of wheat seedlings. Trop Plant Pathol 41:123–127CrossRef

Cruz CD, Santana FM, Todd TC et al (2018) Multi-environment assessment of fungicide performance for managing wheat head blast (WHB) in Brazil and Bolivia. Trop Plant Pathol 44:183–191. https://doi.org/10.1007/s40858-018-0262-9CrossRef

Debnath D, Chakraborty S, Mahapatra S (2021) Spot blotch: A journey from minor to major threat of wheat. J Cereal Res 13(3):255–269

FAOSTAT (Food and Agriculture Organization of the United Nations) (2018) Food balance: food balance sheet. Food and Agriculture Organization of the United Nations, Rome (http://www.fao.org/faostat/en/#data/FBS)

Farman M, Peterson G, Chen L, Starnes J, Valent B et al (2017) The Lolium pathotype of Magnaporthe oryzae recovered from a single blasted wheat plant in the United States. Plant Dis 101:684–692PubMedCrossRef

Fernandes JMC, Pavan W, Holbig CA, Karrei M, de Vargas F et al (2017) A weather-based model for predicting early season inoculum build-up and spike infection by the wheat blast pathogen. Trop Plant Pathol 42:230–237CrossRef

Filha MX, Rodrigues FA, Domiciano GP, Oliveira HV, Silveira PR, Moreira WR (2011) Wheat resistance to leaf blast mediated by silicon. Australas Plant Pathol 40:28–38CrossRef

Fowler G, Takeuchi Y (2012) 12 mapping, climate and geographic information for risk analysis. In: Devorshak C (ed) Plant pest risk analysis concepts and applications CR0 4YY. CPI Group, Croydon, pp 151–166CrossRef

Gao L, Koo DH, Juliana P, Rife T, Singh D, Lemes da Silva C, Lux T, Dorn KM, Clinesmith M, Silva P et al (2020) The Aegilops ventricosa 2NvS segment in bread wheat: Cytology, genomics and breeding. Theor Appl Genet 134:529–542PubMedPubMedCentralCrossRef

Goddard R, Steed A, Chinoy C et al (2020) Dissecting the genetic basis of wheat blast resistance in the Brazilian wheat cultivar BR 18-Terena. BMC Plant Biol 20:398. https://doi.org/10.1186/s12870-020-02592-0CrossRefPubMedPubMedCentral

Gomes DP, Rocha VS, Pereira OL, Souza MAD (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 39:66–74CrossRef

Goulart ACP, Paiva FA (1990) Transmision of Pyricularia oryzae by wheat (Triticum aestivum) seeds. Fitopatol Bras 15:359–362

Goulart ACP, Paiva FA (1992) Incidence of (Pyricularia oryzae) in different wheat cultivars under field conditions. Fitopatol Bras 17:321–325

Gunther H (1986) Simulation of the epidemiology of Pyricularia oryzae in rice. Department of Theoretical Production Ecology

Hayashi T, Koshimizu Y (1988) Computer program BLASTAM for forecasting occurrence of rice leaf blast (in Japanese). Bull Tohoku Natl Agric Exp Stn 78:123–138

Helguera M, Khan IA, Kolmer J, Lijavetzky D, Zhong-qi L, Dubcovsky J (2003) PCR assays for the Lr37-Yr17-Sr38 cluster of rust resistance genes and their use to develop isogenic hard red spring wheat lines. Crop Sci 43:1839–1847CrossRef

Hossain A, Jaime A, Da Silva T (2012) Phenology, growth and yield of three wheat (Triticum aestivum L.) varieties as affected by high temperature stress. Not Sci Biol 4:97–109CrossRef

ICAR-IIWBR (2019) Progress report of all India coordinated wheat and barley improvement project 2018–19, crop protection. ICAR—Indian Institute of Wheat and Barley Research, Karnal, p 214 (Eds: Sudheer Kumar, D.P. Singh, Poonam Jasrotia, Prem LalKashyap and Gyanendra Pratap Singh)

Igarashi S, Utiamada CM, Igarashi LC, Kazuma AH, Lopes RS (1986) Ocurrence of Pyrcularia sp. in wheat (Triticum aestivum L.) in the State of Paran’a, Brazil. 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 (2016) Emergence of wheat blast in Bangladesh was caused by a South American lineage of Magnaporthe oryzae. BMC Biol 14:1–11CrossRef

Islam MT, Kim KH, Choi J (2019) Wheat blast in Bangladesh: the current situation and future impacts. Plant Pathol J 35(1):1–10PubMedPubMedCentralCrossRef

Islam MT, Gupta DR, Hossain A, Roy KK, He X, Kabir MR, Singh PK, Khan M, Rahman A, Rahman M, Wang GL (2020) Wheat blast: a new threat to food security. Phytopathol Res 2(1):1–3CrossRef

Jahier A, Tanguy D, Rivoal K, Bariana HS (2001) The Aegilops ventricose segment on chromosome 2AS of the wheat cultivar ‘VPM1’ carries the cereal cyst nematode resistance gene Cre5. Plant Breed 120:125–128CrossRef

Juliana P, Singh RP, Singh PK, Crossa J, Huerta-Espino J et al (2017) Genomic and pedigree-based prediction for leaf, stem, and stripe rust resistance in wheat. Theor Appl Genet 130:1415–1430. https://doi.org/10.1007/s00122-017-2897-1CrossRefPubMedPubMedCentral

Juliana P, He X, Poland J, Roy KK, Malaker PK, Mishra VK et al (2022) Genomic selection for spot blotch in bread wheat breeding panels, full-sibs and half-sibs and index-based selection for spot blotch, heading and plant height. Theor Appl Genet 135:1965–1983. https://doi.org/10.1007/s00122-022-04087-yCrossRefPubMedPubMedCentral

Kashyap PL, Kumar S, Mahapatra S, Hembram S, Singh GP (2021a) Population biology of wheat blast pathogen. In: Sudheer Kumar, Kashyap PL, Singh by GP (eds) Wheat blast. CRC Press, Taylor & Francis ISBN 9781138599970,

Kashyap PL, Kumar S, Mahapatra S, Hembram S, Singh GP (2021b) Identification and diagnosis of wheat blast. In: Sudheer Kumar, Kashyap PL, Singh by GP (eds) Wheat blast. CRC Press, Taylor & Francis,

Khan H, Wani SH, Bhardwaj SC et al (2022) Wheat spike blast: genetic interventions for effective management. Mol Biol Rep 27:1–2

Kim CK, Kim CH (1993) The rice leaf blast simulation model EPIBLAST. In: Penning de Vries F, Teng P, Metselaar K (eds) Systems approaches for agricultural development. Springer, Dordrecht, pp 309–321 https://doi.org/10.1007/978-94-011-2840-7_18CrossRef

Kim KH, Cho J, Lee YH, Lee WS (2015) Predicting potential epidemics of rice leaf blast and sheath blight in South Korea under the RCP 4.5 and RCP 8.5 climate change scenarios using a rice disease epidemiology model, EPIRICE. Agric For Meteorol 203:191–207CrossRef

Kohli MM, Mehta YR, Guzman E et al (2011) Pyricularia blast—a threat to wheat cultivation. Czech J Genet Plant Breed 47:130–134CrossRef

Kumar S, Kashyap PL, Mahapatra S, Jasrotia P, Singh GP (2021) New and emerging technologies for detecting Magnaporthe oryzae causing blast disease in crop plants. Crop Prot. https://doi.org/10.1016/j.cropro.2020.105473CrossRef

Ma J, Chen J, Wang M, Ren Y, Wang S, Lei C et al (2017) Disruption of OsSEC3A increases the content of salicylic acid and induces plant defense responses in rice. J Exp Bot 69:1051–1064. https://doi.org/10.1093/jxb/erx458CrossRefPubMedCentral

Magarey RD, Sutton TB, Thayer CL (2005) A simple generic infection model for foliar fungal plant pathogens. Phytopathology 95:92–100PubMedCrossRef

Magarey RD, Fowler GA, Borchert DM, Sutton TB, Colunga-Garcia M, Simpson JA (2007) NAPPFAST: an internet system for the weather-based mapping of plant pathogens. Plant Dis 91(4):336–345PubMedCrossRef

Magarey RD, Borchert DM, Engle JS, Colunga-Garcia M, Koch FH, Yemshanov D (2011) Risk maps for targeting exotic plant pest detection programs in the United States. EPPO Bull 41(1):46–56CrossRef

Mahapatra S,Saha P and Das S (2018) Recent Approaches for Management of Plant Diseases edited Srikanta Das. Subrata Dutta, B.N.Chakroborty and Dinesh Singh by Indian Phytopathological Society ISBN 81-7019-599‑X (India) ISBN 1‑55528-443‑4 (USA)

Mahapatra S, Rayanoothala P, Solanki MK, Das S (2020) Wheat Microbiome: present status and future perspective. In: Solanki M, Kashyap P, Kumari B (eds) Phytobiomes: current insights and future vistas. Springer, Singapore https://doi.org/10.1007/978-981-15-3151-4_8CrossRef

Malaker PK, Barma NCD, Tiwari TP et al (2016) First report of wheat blast caused by Magnaporthe oryzae pathotype Triticum in Bangladesh. Plant Dis 100(11):2330CrossRef

Manibhushanrao K, Krishnan P (1991) Epidemiology of blast (EPIBLA): a simulation model and forecasting system for tropical rice in India. International Rice Research Conference, Seoul, pp 27–31

Mezzalama M (2016) Seed health: fostering the safe distribution of maize and wheat seed—general guidelines, 4th edn. CIMMYT, Mexico

MoAFW (Ministry of Agriculture and Farmers Welfare) (2018) Area and production statistics New Delhi: National Informatics Centre, Directorate of Economics and Statistics, Ministry of Agriculture and Farmers Welfare, Government of India. https://aps.dac.gov.in/Home.aspx?ReturnUrl=/

Mottaleb KA, Singh PK, Sonder K, Kruseman G, Tiwari TP, Barma NCD et al (2018) Threat of wheat blast to South Asia’s food security: an ex-ante analysis. PLoS ONE 13:e197555PubMedPubMedCentralCrossRef

Ohta K, Chiba S, Shimada K (1982) Simulation of rice leaf blast using BLASTCAST, a plant disease simulator. Annu Rep Plant Prot 33:9–11

Oliveira TB, Aucique-Pérez CE, Rodrigues FD (2019) Foliar application of silicon decreases wheat blast symptoms without impairing photosynthesis. Bragantia 78:423–431CrossRef

Pagani AP, Dianese AC, Café-Filho AC (2014) Management of wheat blast with synthetic fungicides, partial resistance and silicate and phosphite minerals. Phytoparasitica 42(5):609–617CrossRef

Paul SK, Chakraborty M, Rahman M et al (2022) Marine natural product antimycin A suppresses wheat blast disease caused by Magnaporthe oryzae triticum. J Fungi 8(6):618–638CrossRef

Perello AE, Martinez I, Molina M (2015) First report of virulence and effects of Magnaporthe oryzae isolates causing wheat blast in Argentina. Plant Dis 99(7):904–1042

Phuke RM, He X, Juliana P, Kabir MR, Roy KK, Marza F, Roy C, Singh GP, Chawade A, Joshi AK et al (2022) Identification of genomic regions and sources for wheat blast resistance through GWAS in Indian wheat genotypes. Genes 13:596. https://doi.org/10.3390/genes13040596CrossRefPubMedPubMedCentral

Poloni NM, Carvalho G, Nunes Campos Vicentini S et al (2021) Widespread distribution of resistance to triazole fungicides in Brazilian populations of the wheat blast pathogen. Plant Pathol 70(2):436–448CrossRef

Press Trust of India (2017) Deadly wheat blast disease spreads to Bengal districts. In: Joshi V (ed) The New Indian Express. Express Publications, Chennai

Rafoss T (2003) Spatial stochastic simulation offers potential as a quantitative method for pest risk analysis. Risk Anal 23(4):651–661PubMedCrossRef

Ribot C, Hirsch J, Balzergue S et al (2008) Susceptibility of rice to the blast fungus, Magnaporthe grisea. J Plant Physiol 165(1):114–124PubMedCrossRef

Rios JA, Rios VS, Paul PA et al (2016) Fungicide and cultivar effects on the development and temporal progress of wheat blast under field conditions. J Crop Prot 89:152–160CrossRef

Rios JA, Rios VS, Paul PA, Souza MA, Neto LB, Rodrigues FA (2017) Effects of blast on components of wheat physiology and grain yield as influenced by fungicide treatment and host resistance. Plant Pathol 66(6):877–889CrossRef

Roy C, Juliana P, Kabir MR, Roy KK, Gahtyari NC, Marza F, He X, Singh GP, Chawade A, Joshi AK et al (2021) New genotypes and genomic regions for resistance to wheat blast in south Asian germplasm. Plants. https://doi.org/10.3390/plants10122693CrossRefPubMedPubMedCentral

Roy KK, Anwar MB, Mustarin KE et al (2021a) Evaluation of different fungicides (chemical, botanical and bio-agent) in controlling wheat blast in a blast prone area in Bangladesh. Arch Phytopathol Plant Prot 54(5–6):252–260CrossRef

Roy KK, Rahman M, Reza M, Ali M, Hossain M (2021b) Surveillance and monitoring of some major diseases of wheat in Bangladesh with special emphasis on wheat blast—a new disease in Bangladesh. J Plant Pathol 103(2):473–481CrossRef

Rutkoski J, Benson J, Jia Y, Brown-Guedira G, Jannink JL, Sorrells M et al (2012) Evaluation of genomic prediction methods for Fusarium head blightresistance in wheat. Plant Genome 5:51–61. https://doi.org/10.3835/plantgenome2012.02.0001CrossRef

Saltelli A, Tarantola S, Campolongo F (2000) Sensitivity analysis as an ingredient of modeling. Stat Sci 1:377–395

Savary S, Nelson A, Willocquet L, Pangga I, Aunario J (2012) Modeling and mapping potential epidemics of rice diseases globally. Crop Prot 34:6–17CrossRef

Scholthof KB (2007) The disease triangle: pathogens, the environment and society. Nat Rev Microbiol 5(2):152–156PubMedCrossRef

Shamim AH (2021) Medicinal plants, A promising source of natural fungicides against Magnaporthe oryzae Triticum, causal agent of wheat blast. Am J Plant Sci 12(5):748–758CrossRef

Sharma RK, Singh PK (2020) Wheat blast: A global threat to wheat production. In: Kumar S, Kashyap PL, Singh GP (eds) Wheat Blast. CRC Press, pp 1–18. ISBN 978-0-429-47055‑4

Shude S, Yobo KS, Mbili NC (2020) Progress in the management of Fusarium head blight of wheat: An overview. S Afr J Sci 116(11–12):1–7

Silva WL, Cruz MF, Fortunato AA, Rodrigues FÁ (2015) Histochemical aspects of wheat resistance to leaf blast mediated by silicon. Sci Agric 72:322–327CrossRef

Singh D, Wang X, Kumar U, Gao L, Noor M, Imtiaz M, Singh RP, Poland J (2019) High-throughput phenotyping enabled genetic dissection of crop lodging in wheat. Front Plant Sci 10:394PubMedPubMedCentralCrossRef

Singh PK, Gahtyari NC, Roy C, Roy KK, He X, Tembo B, Xu K, Juliana P, Sonder K, Kabir MR, Chawade A (2021) Wheat blast: a disease spreading byintercontinental jumps and its management strategies. Front Plant Sci 12:710707. https://doi.org/10.3389/fpls.2021.710707CrossRefPubMedPubMedCentral

Tastra IK, Irmansyah R, Yunizar ZH (1987) Epidemiology of leaf blast (Pyricularia oryzae) under various abiotic and biotic conditions. In: Preliminary report of the SARIF team case study for Systems Analysis in Rice Production (SARP) group. International Rice Research Institute, Manila

Tembo B, Mulenga RM, Sichilima S et al (2020) Detection and characterization of fungus (Magnaporthe oryzae pathotype Triticum) causing wheat blast disease on rain-fed grown wheat (Triticum aestivum L.) in Zambia. PLoS ONE 15(9):e238724PubMedPubMedCentralCrossRef

Tredway LP, Stevenson KL, Burpee LL (2005) Genetic structure of Magnaporthe grisea populations associated with St. Augustine grass and tall fescue in Georgia. Phytopathology 95:463–471PubMedCrossRef

Tufan HA, McGrann GR, Magusin A et al (2009) Wheat blast: histopathology and transcriptome reprogramming in response to adapted and nonadapted Magnaporthe isolates. New Phytol 184(2):473–484PubMedCrossRef

Urashima AS, Kato H (1994) Varietal resistance and chemical control of wheat blast fungus. Summa Phytopathol 20:107–112

Urashima AS, Hashimoto Y, Don LD, Kusaba M, Tosa Y, Nakayashiki H, Mayama S (1999) Molecular analysis of the wheat blast population in Brazil with A homolog of retrotransposon Mgr583. Jpn J Phytopathol 65:429–436CrossRef

Valent B, Farrall L, Chumley FG (1991) Magnaporthe grisea genes for pathogenicity and virulence identified through a series of backcrosses. Nat Genet 127(1):87–101

Valent B, Cruppe G, Stack JP et al (2021) Recovery plan for wheat blast caused by Magnaporthe oryzae pathotype triticum. Plant Health Prog 22(2):182–212CrossRef

Vicentini SN, Casado PS, de Carvalho G et al (2022) Monitoring of Brazilian wheat blast field populations reveals resistance to QoI, DMI, and SDHI fungicides. Plant Pathol 71(2):304–321CrossRef

Wang H, Mongiano G, Fanchini D, Titone P, Tamborini L, Bregaglio S (2021) Varietal susceptibility overcomes climate change effects on the future trends of rice blast disease in Northern Italy. Agric Syst 193:103223CrossRef

West JS, Canning GGM, Perryman SA, King K (2017) Novel technologies for the detection of Fusarium head blight disease and airborne inoculum. Trop Plant Pathol 42:203–209PubMedPubMedCentralCrossRef

Williamson VM, Thomas V, Ferris H, Dubcovsky J (2013) An Aegilops ventricosa translocation confers resistance against root-knot nematodes to common wheat. Crop Sci.53. 1412–1418

Titel: Insights into Wheat Blast: Its Epidemiology, Recent Advances and Management Strategies
verfasst von: Sunita Mahapatra
Sunanda Chakraborty
Debanjana Debnath
Chandan Roy
Publikationsdatum: 22.12.2023
Verlag: Springer Berlin Heidelberg
Erschienen in: Journal of Crop Health / Ausgabe 2/2024
Print ISSN: 2948-264X
Elektronische ISSN: 2948-2658
DOI: https://doi.org/10.1007/s10343-023-00964-8

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