Abstract:
Rice blast, caused by the fungus Pyricularia oryzae L., is considered one of the main threats to world rice production. The development of resistant cultivars is one of the best and sustainable control alternatives. Plant breeding efforts have been accelerated by genetic mapping (linkage and associative) and marker assisted selection. On the other hand, genomic editing techniques, such as meganucleases (MNs), Zinc-finger nucleases (ZFNs), Transcription Activator-like Effector Nucleases (TALENs) and Clustered Regularly Interspaced Short Palindrome Repeats/CRISPR-associated protein 9 (CRISPR/Cas9), can be used to promote specific genetic modifications. Likewise, transgenics can also be used to manipulate specific genes. In this sense, this work aims to characterize rice blast and elucidate available biotechnological alternatives to accelerate the development of improved rice cultivars resistant to rice blast.
Keywords:
Abiotic stress; biotechnology tools; Oryza sativa L.; Pyricularia oryzae L.
INTRODUCTION
Rice (Oryza sativa L.) has a high social and economic importance, playing a major role in the world production of cereals, serving approximately three billion people around the world, with a total production of ca. 756.5 million tons of husked grains (Filippi et al. 2009Filippi MCC, Lobo VDS and Prabh A (2009) Aplicação da biotecnologia na busca de resistência estável à brusone em arroz irrigado. In Congresso brasileiro de arroz irrigado. Estresses e sustentabilidade: desafios para a lavoura arrozeira: anais. Embrapa Arroz e Feijão/Palotti, Porto Alegre, p. 1-9., SOSBAI 2018SOSBAI - Sociedade Sul-Brasileira de Arroz Irrigado (2018) Arroz irrigado: Recomendações técnicas da pesquisa para o Sul do Brasil. Sociedade Sul-Brasileira de Arroz Irrigado, Farroupilha, p. 205.). Breeders have intensified efforts to develop superior cultivars, in view of the main challenges for cultivation, which are often aggravated by climate change, as is the case with plant diseases (Hirabayashi 2013Hirabayashi Y, Mahendran R, Koirala S, Konoshima L, Yamazaki D, Watanabe S, Kim H and Kanae S (2013) Global flood risk under climate change. Nature Climate Change 3: 816-821.). Rice cultivation has a range of diseases that have a significant impact on yield. In Brazil, diseases of fungal origin are the majority due to the predominant irrigated production system (Prabhu et al. 1995Prabhu AS, Bedendo IP and Filippi MC (1995) Principais doenças do arroz no Brasil. EMBRAPA-CNPAF, Santo Antônio de Goiás, p. 31.). Blast, caused by the fungus Pyricularia oryzae L., is among the most important diseases that affect rice (Miah et al. 2013Miah G, Rafii MY, Ismail MR, Puteh AB, Rahim HA, Asfaliza R and Latif MA (2013) Blast resistance in rice: a review of conventional breeding to molecular approaches. Molecular Biology Reports 40: 2369-2388., Srivastava et al. 2017Srivastava D, Shamim M, Kumar M, Mishra A, Pandey P, Kumar D, Yadav P, Siddiqui MH and Singh KN (2017) Current status of conventional and molecular interventions for blast resistance in rice. Rice Science 24: 299-321.).
Phytopathogens such as P. oryzae, are constantly evolving and are therefore considered a threat to food security. Among the alternatives to control plant diseases, genetic resistance is considered the most efficient and sustainable, which is due both to its economic and environmental advantages (Bonman 1992Bonman JM (1992) Durable resistance to rice blast disease - environmental influences. In Johnson R and Jellis GJ (eds) Breeding for disease resistance. Developments in plant pathology. Springer, Dordrecht, p. 115-123.). However, the durability of blast resistance is a major challenge for plant breeders and pathologists due to the high variability of P. oryzae (Devi et al. 2015Devi SR, Singh K, Umakanth B, Vishalakshi B, Renuka P, Sudhakar KV, Prasad MS, Viraktamath BC, Babu VR and Madhav MS (2015) Development and identification of novel rice blast resistant sources and their characterization using molecular markers. Rice Science 22: 300-308., Maciel and Danelli et al. 2018Maciel JLN and Danelli ALD (2018) Resistência genética de plantas a fungos. In Dallagnol LJ (Org) Resistência genética de plantas a patógenos. UFPel, Pelotas, p. 359- 393., Li et al. 2009Li H, Zhou SY, Zhao WS, Su SC and Peng YL (2009) A novel wall-associated receptor-like protein kinase gene, OsWAK1, plays important roles in rice blast disease resistance. Plant Molecular Biology 69: 337-346.).
Conventional breeding techniques for biotic factor resistance can have their efficiency increased if complemented by biotechnology approaches (Miah et al. 2013Miah G, Rafii MY, Ismail MR, Puteh AB, Rahim HA, Asfaliza R and Latif MA (2013) Blast resistance in rice: a review of conventional breeding to molecular approaches. Molecular Biology Reports 40: 2369-2388., Ashkani et al. 2015Ashkani S, Rafii MY, Shabanimofrad M, Miah G, Sahebi M, Azizi P, Tanweer FA, Akhtar MS and Nasehi A (2015) Molecular breeding strategy and challenges towards improvement of blast disease resistance in rice crop. Frontiers in Plant Science 6: 886.). Marker-assisted selection, for example, has long been used as a strategy for improving germplasm, screening, selection and developing new blast resistant cultivars in rice (Miah et al. 2013Miah G, Rafii MY, Ismail MR, Puteh AB, Rahim HA, Asfaliza R and Latif MA (2013) Blast resistance in rice: a review of conventional breeding to molecular approaches. Molecular Biology Reports 40: 2369-2388., Ashkani et al. 2015Ashkani S, Rafii MY, Shabanimofrad M, Miah G, Sahebi M, Azizi P, Tanweer FA, Akhtar MS and Nasehi A (2015) Molecular breeding strategy and challenges towards improvement of blast disease resistance in rice crop. Frontiers in Plant Science 6: 886.).
Another strategy is genetic mapping, which makes it possible to observe the physical association between genes or genome fragments and phenotypic variations, accelerating the identification of genotypes with favorable alleles and durable resistance (Desta and Ortiz 2014Desta ZA and Ortiz R (2014) Genomic selection: genome-wide prediction in plant improvement. Trends in Plant Science 19: 592-601.). Likewise, association or linkage disequilibrium mapping, also known as genome wide association, is another approach that is effective when applied to complex traits, providing valuable information when choosing strategies to increase the resistance to blast (Korinsak et al. 2019Korinsak S, Tangphatsornruang S, Pootakham W, Wanchana S, Plabpla A, Jantasuriyarat C, Patarapuwadol S, Vanavichit A and Toojinda T (2019) Genome-wide association mapping of virulence gene in rice blast fungus Magnaporthe oryzae using a genotyping by sequencing approach. Genomics 111: 661-668.).
Genome edition is also a powerful tool that allows the introduction of precise changes in a cultivar (Andolfo et al. 2016Andolfo G, Iovieno P, Frusciante L and Ercolano MR (2016) Genome-editing technologies for enhancing plant disease resistance. Frontiers in Plant Science 7: 1813.). Directed nucleases are used, such as Meganucleases (MNs), Zinc-Finger Nucleases (ZFNs), Transcription Activator-like Effector Nucleases (TALENs) and Clustered Regularly Interspaced Short Palindromic Repeats/CRISPR-associated protein 9 (CRISPR/Cas9) is a tool that allows the introduction of precise modifications in specific genes or sequences (Kim et al. 1996Kim YG, Cha J and Chandrasegaran S (1996) Hybrid restriction enzymes: zinc finger fusions to Fok I cleavage domain. Proceedings of the National Academy of Sciences 93: 1156-1160., Christian et al. 2010Christian M, Cermak T, Doyle EL, Schmidt C, Zhang F, Hummel A, Bogdanove AJ and Voytas DF (2010) Targeting DNA double-strand breaks with TAL effector nucleases. Genetics 186: 757-761., Ashkani et al. 2016Ashkani S, Rafii MY, Shabanimofrad M, Ghasemzadeh A, Ravanfar SA and Latif MA (2016) Molecular progress on the mapping and cloning of functional genes for blast disease in rice (Oryza sativa L.): current status and future considerations. Critical Reviews in Biotechnology 36: 353-367., Andolfo et al. 2016Andolfo G, Iovieno P, Frusciante L and Ercolano MR (2016) Genome-editing technologies for enhancing plant disease resistance. Frontiers in Plant Science 7: 1813.) and can be used to improve tolerance to blast in rice (Wang et al. 2016Wang F, Wang C, Liu P, Lei C, Hao W, Gao Y, Liu YG and Zhao K (2016) Enhanced rice blast resistance by CRISPR/Cas9-targeted mutagenesis of the ERF transcription factor gene OsERF922. PloS one 11: 0154027.). Similarly, transgenics is another approach with a potential impact to assist breeding for blast resistance (Liu et al. 2012Liu DF, Chen XJ, Liu JQ, Ye JC, and Guo ZJ (2012) The rice ERF transcription factor OsERF922 negatively regulates resistance to Magnaporthe oryzae and salt tolerance. Journal of Experimental Botany 63: 3899-3911. , Helliwell et al. 2013Helliwell EE, Wang Q and Yang Y (2013) Transgenic rice with inducible ethylene production exhibits broad-spectrum disease resistance to the fungal pathogens Magnaporthe oryzae and Rhizoctonia solani. Plant Biotechnology Journal 11: 33-42.).
Strategies such as the above mentioned can be used to solve problems that have the potential to affect world food security. Thus, in this article the importance of rice blast, the major biotechnological tools available to assist improvement and advances in blast durable resistance research will be addressed.
PERSPECTIVES REGARDING BLAST IMPACT ON RICE
The causal agent of rice blast has been referred to by different names over the years. Its asexual phase was named Pyricularia grisea by Saccardo in 1880, later the name Pyricularia oryzae was established by Cavara in 1892. In its sexual phase, the pathogen was first named Magnaporthe grisea (Hebert) Barr in 1970, but soon was changed to Magnaporthe oryzae (Couch and Kohn 2002Couch BC and Kohn LM (2002) A multilocus gene genealogy concordant with host preference indicates segregation of a new species, Magnaporthe oryzae, from M. grisea. Mycologia 94: 683-693., Zhang et al. 2016Zhang N, Luo J, Rossman AY, Aoki T, Chuma I, Crous PW, Dean R, De Vrie RP, Donofrio N, Hyde KD and Lebrun MH (2016) Generic names in Magnaporthales. IMA fungus 7: 155-159.). However, recent studies point to Pyricularia oryzae Cavara, both for the asexual and for the sexual phase, as the correct way to name the causative agent of rice blast, due to its pathogenicity and ecological and evolutionary traits (Moreira et al. 2015Moreira SI, Ceresini PC and Alves E (2015) Reprodução sexuada em Pyricularia oryzae. Summa Phytopathologica 41: 175-182., Zhang et al. 2016Zhang N, Luo J, Rossman AY, Aoki T, Chuma I, Crous PW, Dean R, De Vrie RP, Donofrio N, Hyde KD and Lebrun MH (2016) Generic names in Magnaporthales. IMA fungus 7: 155-159.). It is recommended that the synonym Magnaporthe oryzae be mentioned in publications such as "Pyricularia oryzae (syn. Magnaporthe oryzae)" (Zhang et al. 2016). In its asexual (anamorphic) phase, which is usually found in the field, P. oryzae presents spores called conidia, characterized by its pear-shaped, obclave shape. Conidia often have two septa, with a circular base and a thin apex, slightly dark or hyaline in color, and having a small hilum at the base with which it attaches to the conidiophore (Couch and Kohn 2002Couch BC and Kohn LM (2002) A multilocus gene genealogy concordant with host preference indicates segregation of a new species, Magnaporthe oryzae, from M. grisea. Mycologia 94: 683-693.). Its sexual phase (teleomorphic) is not observed naturally but can be performed by pairing compatible individuals in vitro (Moreira et al. 2015Moreira SI, Ceresini PC and Alves E (2015) Reprodução sexuada em Pyricularia oryzae. Summa Phytopathologica 41: 175-182.).
The pathogen that causes blast is hemibiotrophic, a survival mode in which the fungus starts in a biotrophic stage during which the plant's immune system is suppressed and then passes to a necrotrophic stage in which it promotes cell death (Fernandez and Orth 2018Fernandez J and Orth K (2018) Rise of a cereal killer: the biology of Magnaporthe oryzae biotrophic growth. Trends in Microbiology 26: 582-597.).
Impact on the rice crop since blast first appearances
The first records of blast occurrence date from the year 1600 and were found in China and Japan, where it was first described as “rice fever” (Bedendo and Prabhu 2005Bedendo IP and Prabhu AS (2005) Doenças do arroz (Oryza sativa L.). In Kimati H, Amorim L, Rezendo JAM, Bergamin Filho A and Camargo LEA (eds) Manual de fitopatologia. Agronômica Ceres, São Paulo, p. 79-90.). In Brazil, the first diagnosis of rice blast occurred in 1912 in São Paulo and in Rio Grande do Sul in 1918 (Prabhu and Filippi 2006Prabhu AS and Filippi MD (2006) Brusone em arroz: controle genético, progresso e perspectivas. Embrapa Arroz e Feijão, Santo Antônio de Goiás, 387p.). Since then, the disease has been found in virtually all regions where rice is grown on a commercial scale. Losses are variable depending on the cultivar and environmental conditions, reaching 100% under favorable conditions and susceptible cultivars (Agbowuro et al. 2020Agbowuro GO, Afolabi MS, Olamiriki EF and Awoyemi SO (2020) Rice blast disease (Magnaporthe oryzae): A menace to rice production and humanity. International Journal of Pathogen Research: 32-39. ).
Rice blast has never been fully eradicated, but it is possible to significantly reduce the damage caused by the disease through integrated crop management (Prabhu and Filippi 2006Prabhu AS and Filippi MD (2006) Brusone em arroz: controle genético, progresso e perspectivas. Embrapa Arroz e Feijão, Santo Antônio de Goiás, 387p.). The continuous use of fungicides to its control is a potential danger to health and the environment and can lead to the emergence resistant races (Srivastava et al. 2017Srivastava D, Shamim M, Kumar M, Mishra A, Pandey P, Kumar D, Yadav P, Siddiqui MH and Singh KN (2017) Current status of conventional and molecular interventions for blast resistance in rice. Rice Science 24: 299-321., Maciel and Danelli 2018Maciel JLN and Danelli ALD (2018) Resistência genética de plantas a fungos. In Dallagnol LJ (Org) Resistência genética de plantas a patógenos. UFPel, Pelotas, p. 359- 393.). Therefore, it is recommended to use resistant cultivars and good crop management practices (Filippi et al. 2009Filippi MCC, Lobo VDS and Prabh A (2009) Aplicação da biotecnologia na busca de resistência estável à brusone em arroz irrigado. In Congresso brasileiro de arroz irrigado. Estresses e sustentabilidade: desafios para a lavoura arrozeira: anais. Embrapa Arroz e Feijão/Palotti, Porto Alegre, p. 1-9.).
In the southern region of Brazil there are irrigated rice cultivars available with different levels of blast resistance (Ogoschi et al. 2018Ogoschi C, Carlos FS, Ulguim ADR, Zanon AJ, Nunes CDM, Bittencourt CDC, Almeida RD and Martins JDS (2018) Potencial de cultivares de arroz irrigado resistentes à brusone para redução do uso de fungicidas no litoral norte do Rio Grande do Sul. Embrapa Clima Temperado, Pelotas (Circular Técnica 192).). It is recommended to change cultivars that have resistance every three or four years to avoid the strong pressure of selection of virulent races of the pathogen (Maciel and Danelli 2018Maciel JLN and Danelli ALD (2018) Resistência genética de plantas a fungos. In Dallagnol LJ (Org) Resistência genética de plantas a patógenos. UFPel, Pelotas, p. 359- 393.). In southern Brazil there are blast resistant irrigated rice cultivars available, such as IRGA 423, IRGA 424 and IRGA 424 CL, IRGA 426, IRGA 431 CL, SCSBRS Tio Taka, SCS122 Miura and BRS 7 “Taim” (Ogoschi et al. 2018Ogoschi C, Carlos FS, Ulguim ADR, Zanon AJ, Nunes CDM, Bittencourt CDC, Almeida RD and Martins JDS (2018) Potencial de cultivares de arroz irrigado resistentes à brusone para redução do uso de fungicidas no litoral norte do Rio Grande do Sul. Embrapa Clima Temperado, Pelotas (Circular Técnica 192).). One of the technical recommendations for the crop is to change the cultivars that have resistance every three or four years to avoid an increase in the selection pressure of virulent races of the pathogen (Ogoschi et al. 2018). The breakdown of resistance, after a few years, occurs due to increased exposure and high genetic variability of the pathogen (Bonman 1992Bonman JM (1992) Durable resistance to rice blast disease - environmental influences. In Johnson R and Jellis GJ (eds) Breeding for disease resistance. Developments in plant pathology. Springer, Dordrecht, p. 115-123., Devi et al. 2015Devi SR, Singh K, Umakanth B, Vishalakshi B, Renuka P, Sudhakar KV, Prasad MS, Viraktamath BC, Babu VR and Madhav MS (2015) Development and identification of novel rice blast resistant sources and their characterization using molecular markers. Rice Science 22: 300-308., Li et al. 2019Li W, Chern M, Yin J, Wang J and Chen X (2019) Recent advances in broad-spectrum resistance to the rice blast disease. Current Opinion in Plant Biology 50: 114-120.).
How the pathogen acts in the plant
Microorganisms are in constant evolution and can frequently develop strategies to overcome plant defenses in order to become pathogens (Vale et al. 2001Vale FXR, Parlevliet JE and Zambolim L (2001) Concepts in plant disease resistance. Fitopatologia Brasileira 26: 577-589., Fernandez and Orth 2018Fernandez J and Orth K (2018) Rise of a cereal killer: the biology of Magnaporthe oryzae biotrophic growth. Trends in Microbiology 26: 582-597.). Rice plant infection begins with P. oryzae spore adhering to the hydrophobic surface of the leaf. The pathogen recognizes the cuticle constituents and, only then, induces spore germination and formation of specialized structures for penetration (Martin-Urdiroz et al. 2016Martin-Urdiroz M, Oses-Ruiz M, Ryder LS and Talbot NJ (2016) Investigating the biology of plant infection by the rice blast fungus Magnaporthe oryzae. Fungal Genetics and Biology 90: 61-68.). It is the germ tube that recognizes the surface of the leaf on which a specialized cell, the appressorium, is formed, which allows the fungus to penetrate the host plant tissues through mechanical force and enzymatic activity (Martin-Urdiroz et al. 2016, Yan and Talbot 2016Yan X and Talbot NJ (2016) Investigating the cell biology of plant infection by the rice blast fungus Magnaporthe oryzae. Current Opinion in Microbiology 34: 147-153., Fernandez and Orth 2018Fernandez J and Orth K (2018) Rise of a cereal killer: the biology of Magnaporthe oryzae biotrophic growth. Trends in Microbiology 26: 582-597.). The appressorium is present in an apical spore compartment that is released after conidium hydration (Yan and Talbot 2016Yan X and Talbot NJ (2016) Investigating the cell biology of plant infection by the rice blast fungus Magnaporthe oryzae. Current Opinion in Microbiology 34: 147-153., Fernandez and Orth 2018Fernandez J and Orth K (2018) Rise of a cereal killer: the biology of Magnaporthe oryzae biotrophic growth. Trends in Microbiology 26: 582-597.). This interaction occurs within epidermal and mesophilic cells and results in tissue colonization and the formation of lesions that become apparent after 72 hours (Prabhu and Filippi 2006Prabhu AS and Filippi MD (2006) Brusone em arroz: controle genético, progresso e perspectivas. Embrapa Arroz e Feijão, Santo Antônio de Goiás, 387p., Martin-Urdiroz et al. 2016Martin-Urdiroz M, Oses-Ruiz M, Ryder LS and Talbot NJ (2016) Investigating the biology of plant infection by the rice blast fungus Magnaporthe oryzae. Fungal Genetics and Biology 90: 61-68.). In resistant cultivars this process is mostly inhibited (Fernandez and Orth 2018Fernandez J and Orth K (2018) Rise of a cereal killer: the biology of Magnaporthe oryzae biotrophic growth. Trends in Microbiology 26: 582-597.). The plant colonization depends on the environmental and climatic conditions favorable to the pathogen. Leaf moisture and temperature around 25 to 28 ºC favor the germination of the conidia and the beginning of the infection (Filippi et al. 2009Filippi MCC, Lobo VDS and Prabh A (2009) Aplicação da biotecnologia na busca de resistência estável à brusone em arroz irrigado. In Congresso brasileiro de arroz irrigado. Estresses e sustentabilidade: desafios para a lavoura arrozeira: anais. Embrapa Arroz e Feijão/Palotti, Porto Alegre, p. 1-9.). Sporulation is increased with air humidity above 90%, and cloudiness, excess nitrogen and late sowing, also favor the establishment of the pathogen (Prabhu and Filippi 2006Prabhu AS, Bedendo IP and Filippi MC (1995) Principais doenças do arroz no Brasil. EMBRAPA-CNPAF, Santo Antônio de Goiás, p. 31.).
Symptoms occur in the form of lesions throughout the shoots, including leaves, leaf sheath, neck, panicles, pedicels and seeds, however, there is still no consensus on effects on the roots (Ribot et al. 2008Ribot C, Hirsch J, Balzergue S, Tharreau D, Nottéghem JL, Lebrun MH and Morel JB (2008) Susceptibility of rice to the blast fungus, Magnaporthe grisea. Journal of Plant Physiology 165: 114-124.). Small brown necrotic spots appear on the leaves and evolve to an elliptical shape with a brown margin and a gray or whitish center (Agbowuro et al. 2020Agbowuro GO, Afolabi MS, Olamiriki EF and Awoyemi SO (2020) Rice blast disease (Magnaporthe oryzae): A menace to rice production and humanity. International Journal of Pathogen Research: 32-39. ). Over time, these lesions increase in size in the direction of the veins and, in more advanced cases, present a yellowish halo circling the lesion until the tissue dies (Agbowuro et al. 2020Agbowuro GO, Afolabi MS, Olamiriki EF and Awoyemi SO (2020) Rice blast disease (Magnaporthe oryzae): A menace to rice production and humanity. International Journal of Pathogen Research: 32-39. ).
The main consequence of the severity of the disease is the reduction in grain yield caused by the direct effect of blocking the passage of nutrients, causing poor grain formation, or even in the sterility of the panicle (Prabhu et al. 1995Prabhu AS, Bedendo IP and Filippi MC (1995) Principais doenças do arroz no Brasil. EMBRAPA-CNPAF, Santo Antônio de Goiás, p. 31.). In the vegetative phase it affects the plant's stature and the number of tillers, consequently impacting productivity (Ribot et al. 2008Ribot C, Hirsch J, Balzergue S, Tharreau D, Nottéghem JL, Lebrun MH and Morel JB (2008) Susceptibility of rice to the blast fungus, Magnaporthe grisea. Journal of Plant Physiology 165: 114-124.). The greatest losses in rice grain yield are associated with neck blast (Filippi et al. 2009Filippi MCC, Lobo VDS and Prabh A (2009) Aplicação da biotecnologia na busca de resistência estável à brusone em arroz irrigado. In Congresso brasileiro de arroz irrigado. Estresses e sustentabilidade: desafios para a lavoura arrozeira: anais. Embrapa Arroz e Feijão/Palotti, Porto Alegre, p. 1-9.).
Plant defenses against the pathogen
During their life cycle, cultivated plants are constantly challenged by a wide variety of microorganisms. To survive, plants must be able to detect pathogens and activate their defense responses (Maciel and Danelli 2018Maciel JLN and Danelli ALD (2018) Resistência genética de plantas a fungos. In Dallagnol LJ (Org) Resistência genética de plantas a patógenos. UFPel, Pelotas, p. 359- 393.). The plant defenses are controlled by major and minor resistance genes (R), which are responsible for activating a signaling cascade in the hosts (Srivastava et al. 2017Srivastava D, Shamim M, Kumar M, Mishra A, Pandey P, Kumar D, Yadav P, Siddiqui MH and Singh KN (2017) Current status of conventional and molecular interventions for blast resistance in rice. Rice Science 24: 299-321., Maciel and Danelli 2018). These operate through a classical gene-to-gene interaction, resistance to conditioning to a single corresponding dominant avirulence (AVR) gene in a particular pathogen strain (Srivastava et al 2017, Maciel and Danelli 2018). In other words, the plant hypersensitivity response is caused by the effect of the AVR gene present in the pathogen together with the effect of the R gene on the host. Both genes need to be present for resistance to occur (Srivastava et al. 2017Srivastava D, Shamim M, Kumar M, Mishra A, Pandey P, Kumar D, Yadav P, Siddiqui MH and Singh KN (2017) Current status of conventional and molecular interventions for blast resistance in rice. Rice Science 24: 299-321., Maciel and Danelli 2018Maciel JLN and Danelli ALD (2018) Resistência genética de plantas a fungos. In Dallagnol LJ (Org) Resistência genética de plantas a patógenos. UFPel, Pelotas, p. 359- 393.). Qualitative or complete resistance is controlled by one or few genes which tend to be highly effective but are vulnerable to attack by different races of the pathogen. Quantitative or partial resistance, on the other hand, is governed by many genes, located in QTLs (Young 1996Young ND (1996) QTL mapping and quantitative disease resistance in plants. Annual Review of Phytopathology 34: 479-501., Srivastava et al. 2017Srivastava D, Shamim M, Kumar M, Mishra A, Pandey P, Kumar D, Yadav P, Siddiqui MH and Singh KN (2017) Current status of conventional and molecular interventions for blast resistance in rice. Rice Science 24: 299-321., Maciel and Danelli 2018Maciel JLN and Danelli ALD (2018) Resistência genética de plantas a fungos. In Dallagnol LJ (Org) Resistência genética de plantas a patógenos. UFPel, Pelotas, p. 359- 393.).
In rice both qualitative and quantitative blast resistance genes have been reported (reviewed in Srivastava et al. 2017Srivastava D, Shamim M, Kumar M, Mishra A, Pandey P, Kumar D, Yadav P, Siddiqui MH and Singh KN (2017) Current status of conventional and molecular interventions for blast resistance in rice. Rice Science 24: 299-321.). For a better result in the control of the disease, the incorporation of genes of both effects in the development of new resistant varieties can be a great alternative (Miah et al. 2013Miah G, Rafii MY, Ismail MR, Puteh AB, Rahim HA, Asfaliza R and Latif MA (2013) Blast resistance in rice: a review of conventional breeding to molecular approaches. Molecular Biology Reports 40: 2369-2388.). The complexity of the inheritance of resistance is related to its durability and is determined by a test in which different plant genotypes are tested against different pathogen races. According to Van der Plank, horizontal resistance (uniform, race-non-specific) is stable, on the other hand, vertical resistance (differential, race-specific) is unstable (Parlevliet and Zadoks 1977Parlevliet JE and Zadoks JC (1977) The integrated concept of disease resistance: a new view including horizontal and vertical resistance in plants. Euphytica 26: 5-21.).
GENETIC RESISTANCE OF THE RICE PLANT AGAINST BLAST CAUSING PATHOGEN
Rice (Oryza sativa L.) was the first plant species of agricultural importance to have its genome completely sequenced and is considered a model for research among plants of the same family (Arumuganathan and Earle 1991Arumuganathan K and Earle ED (1991) Nuclear DNA content of some important plant species. Plant Molecular Biology Reporter 9: 208-218.). The species genome comprises approximately 430 million base pairs, with an estimated 46 to 56 thousand genes for the indica subspecies, and 32 to 50 thousand genes for the japonica subspecies (Goff et al. 2002Goff SA, Ricke D, Lan TH, Presting G, Wang R, Dunn M, Glazebrook J, Sessions A, Oeller P, Varma H and Hadley D (2002) A draft sequence of the rice genome (Oryza sativa L. ssp. japonica). Science 296: 92-100., Yu et al. 2002Yu J, Hu S, Wang J, Wong GKS, Li S, Liu B, Deng Y, Dai L, Zhou Y, Zhang X and Cao M (2002) A draft sequence of the rice genome (Oryza sativa L. ssp. indica). Science 296: 79-92., IRGSP 2005IRGSP - International Rice Genome Sequencing Project (2005) The map-based sequence of the rice genome. Nature 436: 793., The RAP 2007The RAP - Rice Annotation Project (2007) Curated genome annotation of Oryza sativa ssp. japonica and comparative genome analysis with Arabidopsis thaliana. Genome Research 17: 175-183.). This information enables numerous advances in understanding the molecular mechanisms that govern genetic resistance to diseases that affect the crop, such as blast.
The genome of P. oryzae encodes hundreds of effectors that lead to blast resistance, some of which are recognized by intracellular immune receptors belonging to the nucleotide-binding, leucine-rich repeat (NLR) (Stein et al. 2018Stein JC, Yu Y, Copetti D, Zwick DJ, Zhang L, Zhang C, Chougule K, Gao D, Iwata A, Goicoechea JL, Wei S, Wang J, Wang LYM, Jacquemin J, Becker C, Kudrna D, Zhang J, Londono CEM, Song X, Lee S, Sanchez P, Zuccolo A, Ammiraju JSS, Talag J, Danowitz A, Rivera LF, Gschwend AR, Noutsos C, Wu C-C, Kao S-M, Zeng J-W, Wei F-J, Zhao Q, Feng Q, Baidouri ME, Carpentier M-C, Lasserre E, Cooke R, Farias D da R, da Maia LC, dos Santos RS, Nyberg KG, McNally KL, Mauleon R, Alexandrov N3, Schmutz J, Flowers D, Fan C, Weigel D, Jena KK, Wicker T, Chen M, Han B, Henry R, Hsing Y-I C, Kurata N, Costa de Oliveira A, Panaud A, Jackson SA, Machado CA, Sanderson MJ, Long M, Ware D and Wing RA (2018) Genomes of 13 domesticated and wild rice relatives highlight genetic conservation, turnover and innovation across the genus Oryza. Nature Genetics 50: 285-296., De la Concepcion et al. 2021De la Concepcion JC, Maidment JH, Longya A, Xiao G, Franceschetti M and Banfield MJ (2021) The allelic rice immune receptor Pikh confers extended resistance to strains of the blast fungus through a single polymorphism in the effector binding interface. PLoS Pathogens 17: 1009368.). Plants have developed a set of NLRs in order to neutralize virulence factors, effector molecules secreted by pathogens (De la Concepcion et al. 2021De la Concepcion JC, Maidment JH, Longya A, Xiao G, Franceschetti M and Banfield MJ (2021) The allelic rice immune receptor Pikh confers extended resistance to strains of the blast fungus through a single polymorphism in the effector binding interface. PLoS Pathogens 17: 1009368.). After detecting pathogens, NLRs trigger the activation of immune responses capable of interrupting the spread of the pathogen. The architecture of plant NLRs consists of integrated non-canonical domains. These integrated domains mimic effector-directed host proteins and serve as baits for the detection of pathogens (Stein et al. 2018Stein JC, Yu Y, Copetti D, Zwick DJ, Zhang L, Zhang C, Chougule K, Gao D, Iwata A, Goicoechea JL, Wei S, Wang J, Wang LYM, Jacquemin J, Becker C, Kudrna D, Zhang J, Londono CEM, Song X, Lee S, Sanchez P, Zuccolo A, Ammiraju JSS, Talag J, Danowitz A, Rivera LF, Gschwend AR, Noutsos C, Wu C-C, Kao S-M, Zeng J-W, Wei F-J, Zhao Q, Feng Q, Baidouri ME, Carpentier M-C, Lasserre E, Cooke R, Farias D da R, da Maia LC, dos Santos RS, Nyberg KG, McNally KL, Mauleon R, Alexandrov N3, Schmutz J, Flowers D, Fan C, Weigel D, Jena KK, Wicker T, Chen M, Han B, Henry R, Hsing Y-I C, Kurata N, Costa de Oliveira A, Panaud A, Jackson SA, Machado CA, Sanderson MJ, Long M, Ware D and Wing RA (2018) Genomes of 13 domesticated and wild rice relatives highlight genetic conservation, turnover and innovation across the genus Oryza. Nature Genetics 50: 285-296., De la Concepcion et al. 2021De la Concepcion JC, Maidment JH, Longya A, Xiao G, Franceschetti M and Banfield MJ (2021) The allelic rice immune receptor Pikh confers extended resistance to strains of the blast fungus through a single polymorphism in the effector binding interface. PLoS Pathogens 17: 1009368.). NLR receptors harboring integrated domains are responsible for some of the best characterized resistance genes against rice blast (De la Concepcion et al. 2021De la Concepcion JC, Maidment JH, Longya A, Xiao G, Franceschetti M and Banfield MJ (2021) The allelic rice immune receptor Pikh confers extended resistance to strains of the blast fungus through a single polymorphism in the effector binding interface. PLoS Pathogens 17: 1009368.). However, this mechanism ends up driving the evolution of new effector variants that escape immunological detection. For this reason, the use of NLR information in reference genomes represents a great opportunity for crop improvement programs. In a study using 13 reference genomes covering the Oryza species tree, 5.408 NLR genes were identified, being 535 in O. sativa vg. indica (Stein et al. 2018Stein JC, Yu Y, Copetti D, Zwick DJ, Zhang L, Zhang C, Chougule K, Gao D, Iwata A, Goicoechea JL, Wei S, Wang J, Wang LYM, Jacquemin J, Becker C, Kudrna D, Zhang J, Londono CEM, Song X, Lee S, Sanchez P, Zuccolo A, Ammiraju JSS, Talag J, Danowitz A, Rivera LF, Gschwend AR, Noutsos C, Wu C-C, Kao S-M, Zeng J-W, Wei F-J, Zhao Q, Feng Q, Baidouri ME, Carpentier M-C, Lasserre E, Cooke R, Farias D da R, da Maia LC, dos Santos RS, Nyberg KG, McNally KL, Mauleon R, Alexandrov N3, Schmutz J, Flowers D, Fan C, Weigel D, Jena KK, Wicker T, Chen M, Han B, Henry R, Hsing Y-I C, Kurata N, Costa de Oliveira A, Panaud A, Jackson SA, Machado CA, Sanderson MJ, Long M, Ware D and Wing RA (2018) Genomes of 13 domesticated and wild rice relatives highlight genetic conservation, turnover and innovation across the genus Oryza. Nature Genetics 50: 285-296.). Also in the same study, the sequencing of seven wild relatives of agricultural species enriches the collection of new haplotypes and resistance loci, including the Pi-ta2 locus, which in combination with Pi-ta provides resistance with broad specificity for P. oryzae, information that is critical in strategies such as gene pyramiding (Stein et al. 2018Stein JC, Yu Y, Copetti D, Zwick DJ, Zhang L, Zhang C, Chougule K, Gao D, Iwata A, Goicoechea JL, Wei S, Wang J, Wang LYM, Jacquemin J, Becker C, Kudrna D, Zhang J, Londono CEM, Song X, Lee S, Sanchez P, Zuccolo A, Ammiraju JSS, Talag J, Danowitz A, Rivera LF, Gschwend AR, Noutsos C, Wu C-C, Kao S-M, Zeng J-W, Wei F-J, Zhao Q, Feng Q, Baidouri ME, Carpentier M-C, Lasserre E, Cooke R, Farias D da R, da Maia LC, dos Santos RS, Nyberg KG, McNally KL, Mauleon R, Alexandrov N3, Schmutz J, Flowers D, Fan C, Weigel D, Jena KK, Wicker T, Chen M, Han B, Henry R, Hsing Y-I C, Kurata N, Costa de Oliveira A, Panaud A, Jackson SA, Machado CA, Sanderson MJ, Long M, Ware D and Wing RA (2018) Genomes of 13 domesticated and wild rice relatives highlight genetic conservation, turnover and innovation across the genus Oryza. Nature Genetics 50: 285-296.).
QTLs associated to blast resistance
Approximately 350 Quantitative Trait Loci (QTL) are known to be associated with rice resistance, and there are 85 described resistance loci (reviewed in Ashkani et al. 2016Ashkani S, Rafii MY, Shabanimofrad M, Ghasemzadeh A, Ravanfar SA and Latif MA (2016) Molecular progress on the mapping and cloning of functional genes for blast disease in rice (Oryza sativa L.): current status and future considerations. Critical Reviews in Biotechnology 36: 353-367., and Srivastava et al. 2017Srivastava D, Shamim M, Kumar M, Mishra A, Pandey P, Kumar D, Yadav P, Siddiqui MH and Singh KN (2017) Current status of conventional and molecular interventions for blast resistance in rice. Rice Science 24: 299-321.). The first QTLs associated with blast resistance were mapped by Wang et al. (1994Wang GL, Mackill DJ, Bonman JM, McCouch SR, Champoux MC and Nelson RJ (1994) RFLP mapping of genes conferring complete and partial resistance to blast in a durably resistant rice cultivar. Genetics 136: 1421-1434.), and since then, the search for QTLs has been increasing, which can be explained by the fact that partial resistance implies a more durable resistance (Ashkani et al. 2016Ashkani S, Rafii MY, Shabanimofrad M, Ghasemzadeh A, Ravanfar SA and Latif MA (2016) Molecular progress on the mapping and cloning of functional genes for blast disease in rice (Oryza sativa L.): current status and future considerations. Critical Reviews in Biotechnology 36: 353-367.). Multiple QTLs would mean many sources of partial resistance and could reduce the spread of the pathogen and keep a low selection pressure in the P. oryzae population, keeping a durable resistance (Sharma et al. 2012Sharma TR, Rai AK, Gupta SK, Vijayan J, Devanna BN and Ray S (2012) Rice blast management through host-plant resistance: retrospect and prospects. Agricultural Research 1: 37-52., Maciel and Danelli 2018Maciel JLN and Danelli ALD (2018) Resistência genética de plantas a fungos. In Dallagnol LJ (Org) Resistência genética de plantas a patógenos. UFPel, Pelotas, p. 359- 393.). QTLs are used for the identification of resistance genes and also for the development of markers related to these genes. For blast resistance in rice, QTLs effective against several races of P. oryzae have been identified, and most are associated with qualitative genes (Srivastava et al. 2017Srivastava D, Shamim M, Kumar M, Mishra A, Pandey P, Kumar D, Yadav P, Siddiqui MH and Singh KN (2017) Current status of conventional and molecular interventions for blast resistance in rice. Rice Science 24: 299-321.). Several QTLs were used for gene pyramiding (Sharma et al. 2012Sharma TR, Rai AK, Gupta SK, Vijayan J, Devanna BN and Ray S (2012) Rice blast management through host-plant resistance: retrospect and prospects. Agricultural Research 1: 37-52.).
Genes associated to blast resistance in rice
Currently, approximately 100 genes of resistance (R) to rice blast are known, of these 51% are from indica genotypes, 45% from japonica genotypes and 4% from wild species of rice (Sharma et al. 2012Sharma TR, Rai AK, Gupta SK, Vijayan J, Devanna BN and Ray S (2012) Rice blast management through host-plant resistance: retrospect and prospects. Agricultural Research 1: 37-52.) (Table 1?). The identified R genes have broad nomenclature and, often, the same resistance gene can have different names (Koide et al. 2009Koide Y, Kobayashi N, Xu D and Fukuta Y (2009) Resistance genes and selection DNA markers for blast disease in rice (Oryza sativa L.). Japan Agricultural Research Quarterly (JARQ) 43: 255-280.).
The advances in molecular technologies and the sequencing of the rice genome have made it possible to clone and characterize blast resistance genes, namely Pib, Pita, Pik-h, Pi9, Pi2, Piz-t, Pid2, Pi36, Pi37, Pik-m, Pit, Pi5, Pid3, Pi21, Pb1, Pish, Pik, Pik-p, Pia, NLS1, Pi25 and Pi54rh, allow understanding the resistance spectrum and use in several breeding programs (Liu et al. 2010Liu J, Wang X, Mitchell T, Hu Y, Liu X, Dai L and Wang GL (2010) Recent progress and understanding of the molecular mechanisms of the rice-Magnaporthe oryzae interaction. Molecular Plant Pathology 11: 419-427.). The Pi-1 (t), Pi2, Pi9, Pi20 (t), Pi27 (t), Pi39 (t), Pi40 (t) and Pikh genes confer a broad spectrum of resistance, whereas the Pia, Pib, Pii, Pi- km, Pi-t, Pi12 (t) and Pi19 (t) provide resistance to specific races of the pathogen (Koide et al. 2009Koide Y, Kobayashi N, Xu D and Fukuta Y (2009) Resistance genes and selection DNA markers for blast disease in rice (Oryza sativa L.). Japan Agricultural Research Quarterly (JARQ) 43: 255-280.). The largest class of R genes encodes NBS-LRR (nucleotide binding-leucine rich repeats) protein class. The C-terminal LRR participates in protein-protein interactions of R and Avr genes (Takken and Tameling 2009Takken FLW and Tameling WIL (2009) To nibble at plant resistance proteins. Science 324: 744-746. ).
In rice, the addition of broad-spectrum resistance R genes is able to confer resistance to different strains of P. oryzae (Skamnioti and Gurr 2009Skamnioti P and Gurr SJ (2009) Against the grain: safeguarding rice from rice blast disease. Trends in Biotechnology 27: 141-150.). This strategy was successfully applied with the broad-spectrum Pi2 gene that conferred resistance to 455 P. oryzae isolates from different regions of the Philippines and to most of the 792 isolates from 13 important rice growing regions in China (Chen et al. 1996Chen DH, Zeigler RS, Ahn SW and Nelson RJ (1996) Phenotypic characterization of the rice blast resistance gene Pi-2 (t). Plant Disease 80: 52-56.). In another study, the first cloned broad-spectrum gene, Pi9, conferred resistance to 43 blast-causing pathogen isolates from 13 countries (Qu et al. 2006Qu S, Liu G, Zhou B, Bellizzi M, Zeng L, Dai L, Han B and Wang GL (2006) The broad-spectrum blast resistance gene Pi9 encodes a nucleotide-binding site-leucine-rich repeat protein and is a member of a multigene family in rice. Genetics 172: 1901-1914.). In addition to having proven resistance, this strategy is considered friendlier to the environment and more economical to control the disease in the crop. Regarding durability, broad spectrum genes in native rice were widely used in introgressions, showing durable resistance (Deng et al. 2006Deng Y, Zhu X, Shen Y and He Z (2006) Genetic characterization and fine mapping of the blast resistance locus Pigm (t) tightly linked to Pi2 and Pi9 in a broad-spectrum resistant Chinese variety. Theoretical and Applied Genetics 113: 705-713.). Still, the other genes must be evaluated for durability of resistance. For this reason, much research is underway to further characterize broad-spectrum R genes (Skamnioti and Gurr 2009Skamnioti P and Gurr SJ (2009) Against the grain: safeguarding rice from rice blast disease. Trends in Biotechnology 27: 141-150.). After the characterization of the resistance spectrum of the genes, the develop of broad spectrum and durable resistance to rice blast can be achieved using gene pyramiding (Sharma et al. 2012Sharma TR, Rai AK, Gupta SK, Vijayan J, Devanna BN and Ray S (2012) Rice blast management through host-plant resistance: retrospect and prospects. Agricultural Research 1: 37-52.).
The role of R genes in rice blast resistance has been widely studied. An RNA gel blot analysis of Pib family members (Pib, PibH8, HPibH8-1 and HPibH8-2) revealed that their expression is tightly regulated by environmental signals such as temperature, light, water availability and chemical treatments such as jasmonic acid, salicylic acid, ethylene and probenazol (Wang et al. 2001Wang ZX, Yamanouchi U, Katayose Y, Sasaki T and Yano M (2001) Expression of the Pib rice-blast-resistance gene family is up-regulated by environmental conditions favouring infection and by chemical signals that trigger secondary plant defences. Plant Molecular Biology 47: 653-661.). In another study, the relationship between blast resistance and the expression of a key gene in jasmonic acid biosynthesis was explored (Mei et al. 2006Mei C, Qi M, Sheng G and Yang Y (2006) Inducible overexpression of a rice allene oxide synthase gene increases the endogenous jasmonic acid level, PR gene expression, and host resistance to fungal infection. Molecular Plant-Microbe Interactions 19: 1127-1137.). Even though many R genes were identified and even cloned, it is a difficult task to establish what are the real factors that make a resistance effective and lasting (Sharma et al. 2012Sharma TR, Rai AK, Gupta SK, Vijayan J, Devanna BN and Ray S (2012) Rice blast management through host-plant resistance: retrospect and prospects. Agricultural Research 1: 37-52., Maciel and Danelli 2018Maciel JLN and Danelli ALD (2018) Resistência genética de plantas a fungos. In Dallagnol LJ (Org) Resistência genética de plantas a patógenos. UFPel, Pelotas, p. 359- 393.). The problem lies in the fact that one would need to use multiple genes for resistance to address more than one race of the pathogen, which is often limited due to epistatic interactions between genes (Maciel and Danelli 2018).
BREEDING FOR BLAST RESISTANCE
Conventional breeding
Conventional breeding is mainly based on the phenotypic selection of varieties or lines in selected locations (Ashkani et al. 2015Ashkani S, Rafii MY, Shabanimofrad M, Miah G, Sahebi M, Azizi P, Tanweer FA, Akhtar MS and Nasehi A (2015) Molecular breeding strategy and challenges towards improvement of blast disease resistance in rice crop. Frontiers in Plant Science 6: 886.), a process highly influenced by environmental interactions and the complexity of resistance inheritance. In this case, the breeder should consider the genotype of the plant, the race or races of the pathogen and whether the resistance is qualitative or quantitative (Wang et al. 2017Wang Z, Han Q, Zi Q, Lv S, Qiu D and Zeng H (2017) Enhanced disease resistance and drought tolerance in transgenic rice plants overexpressing protein elicitors from Magnaporthe oryzae. PLoS One 12: 0175734.).
In the case of qualitative resistance, backcrossing is the most widely used breeding method. Improvement methods for quantitative resistance do not differ from those used in other agronomic traits with the same genetic inheritance. For self-cross species, such as rice, the most used selection methods are genealogical (Pedigree), population (Bulk), recurrent selection and mutation breeding (Wang et al. 2017Wang Z, Han Q, Zi Q, Lv S, Qiu D and Zeng H (2017) Enhanced disease resistance and drought tolerance in transgenic rice plants overexpressing protein elicitors from Magnaporthe oryzae. PLoS One 12: 0175734., Srivastava et al. 2017Srivastava D, Shamim M, Kumar M, Mishra A, Pandey P, Kumar D, Yadav P, Siddiqui MH and Singh KN (2017) Current status of conventional and molecular interventions for blast resistance in rice. Rice Science 24: 299-321.). As an alternative to the addition of only one gene, quantitative pyramiding strategy of R genes with different resistance spectra tends to have a better outcome (Skamnioti and Gurr 2009Skamnioti P and Gurr SJ (2009) Against the grain: safeguarding rice from rice blast disease. Trends in Biotechnology 27: 141-150.). However, backcrossing and relying on phenotypic assays only can sometimes be a cumbersome task. Despite its huge contribution to breeding programs, Conventional breeding takes longer when the nature of the resistance is quantitative, it requires crossings, many generations of self-crossing, and many plants to test the resistance. For this reason, the use of molecular biology techniques has become a great option to assist in the process of releasing new cultivars (Miah et al. 2013Miah G, Rafii MY, Ismail MR, Puteh AB, Rahim HA, Asfaliza R and Latif MA (2013) Blast resistance in rice: a review of conventional breeding to molecular approaches. Molecular Biology Reports 40: 2369-2388., Ashkani et al. 2015Ashkani S, Rafii MY, Shabanimofrad M, Miah G, Sahebi M, Azizi P, Tanweer FA, Akhtar MS and Nasehi A (2015) Molecular breeding strategy and challenges towards improvement of blast disease resistance in rice crop. Frontiers in Plant Science 6: 886.).
Molecular breeding
With advances in plant genomics, breeders have a range of biotechnological tools, as well as fundamental information about the molecular biology involved in disease resistance and the virulence of pathogens (Ashkani et al. 2015Ashkani S, Rafii MY, Shabanimofrad M, Miah G, Sahebi M, Azizi P, Tanweer FA, Akhtar MS and Nasehi A (2015) Molecular breeding strategy and challenges towards improvement of blast disease resistance in rice crop. Frontiers in Plant Science 6: 886.). In the rice crop, understanding and applying molecular biology is important to accelerate the development of cultivars resistant to blast (Miah et al. 2013Miah G, Rafii MY, Ismail MR, Puteh AB, Rahim HA, Asfaliza R and Latif MA (2013) Blast resistance in rice: a review of conventional breeding to molecular approaches. Molecular Biology Reports 40: 2369-2388., Ashkani et al. 2015Ashkani S, Rafii MY, Shabanimofrad M, Miah G, Sahebi M, Azizi P, Tanweer FA, Akhtar MS and Nasehi A (2015) Molecular breeding strategy and challenges towards improvement of blast disease resistance in rice crop. Frontiers in Plant Science 6: 886., Srivastava et al. 2017Srivastava D, Shamim M, Kumar M, Mishra A, Pandey P, Kumar D, Yadav P, Siddiqui MH and Singh KN (2017) Current status of conventional and molecular interventions for blast resistance in rice. Rice Science 24: 299-321.). To slow the pathogen's evolution, it is necessary to think about research in a strategic way, aiming to fill gaps in the existing knowledge in the improvement and molecular genetics of blast resistance (Ashkani et al. 2015Ashkani S, Rafii MY, Shabanimofrad M, Miah G, Sahebi M, Azizi P, Tanweer FA, Akhtar MS and Nasehi A (2015) Molecular breeding strategy and challenges towards improvement of blast disease resistance in rice crop. Frontiers in Plant Science 6: 886.).
BIOTECHNOLOGICAL TOOLS IN BREEDING FOR RESISTANCE
Marker assisted selection (MAS)
Molecular markers started in the 80’s, with RFLPs, followed by many variations of fragmente detection (Botstein et al. 1980Botstein D, White RL, Skolnick M and Davis RW (1980) Construction of a genetic linkage map in man using restriction fragment length polymorphisms. American Journal of Human Genetics 32: 314., Mohan et al. 1997Mohan M, Nair S, Bhagwat A, Krishna TG, Yano M, Bhatia CR and Sasaki T (1997) Genome mapping, molecular markers and marker-assisted selection in crop plants. Molecular Breeding 3: 87-103., Shanti et al. 2010Shanti ML, Shenoy VV, Devi GL, Kumar VM, Premalatha P, Kumar GN, Shashidhar HE, Zehr UB and Freeman WH (2010) Marker-assisted breeding for resistance to bacterial leaf blight in popular cultivar and parental lines of hybrid rice. Journal of Plant Pathology: 495-501.). The application of molecular markers in plant breeding is intended to assist breeders by allowing indirect selection (Shanti et al. 2010Shanti ML, Shenoy VV, Devi GL, Kumar VM, Premalatha P, Kumar GN, Shashidhar HE, Zehr UB and Freeman WH (2010) Marker-assisted breeding for resistance to bacterial leaf blight in popular cultivar and parental lines of hybrid rice. Journal of Plant Pathology: 495-501.). Some of the main advantages of these are the reliability of the information, the saving of time and space, the possibility of early selection and the pattern of Mendelian inheritance (Mohan et al. 1997). Some of the main advantages of these are information reliability, time and space savings, the possibility of early selection and the Mendelian inheritance pattern (Mohan et al. 1997Mohan M, Nair S, Bhagwat A, Krishna TG, Yano M, Bhatia CR and Sasaki T (1997) Genome mapping, molecular markers and marker-assisted selection in crop plants. Molecular Breeding 3: 87-103., Heffner et al. 2010Heffner EL, Lorenz AJ, Jannink JL and Sorrells ME (2010) Plant breeding with genomic selection: gain per unit time and cost. Crop Science 50: 1681-1690.). Objectively, molecular markers can be defined as genetic loci that can be easily identified and quantified in a population and are linked to one or more genes (Mohan et al. 1997Mohan M, Nair S, Bhagwat A, Krishna TG, Yano M, Bhatia CR and Sasaki T (1997) Genome mapping, molecular markers and marker-assisted selection in crop plants. Molecular Breeding 3: 87-103.). With the use of markers, it is possible to carry out an indirect selection, which is carried out based on a molecular analysis, as they are involved in the genetic control of traits that enable the distinction between contrasting individuals (Mohan et al. 1997Mohan M, Nair S, Bhagwat A, Krishna TG, Yano M, Bhatia CR and Sasaki T (1997) Genome mapping, molecular markers and marker-assisted selection in crop plants. Molecular Breeding 3: 87-103., Heffner et al. 2010Heffner EL, Lorenz AJ, Jannink JL and Sorrells ME (2010) Plant breeding with genomic selection: gain per unit time and cost. Crop Science 50: 1681-1690.). They can be identified through use of techniques of Electrophoresis, Hybridization, Restriction Enzymes, Polymerase Chain Reaction (PCR), Sequencing, or even by combining some of these techniques (Ashkani et al. 2015Ashkani S, Rafii MY, Shabanimofrad M, Miah G, Sahebi M, Azizi P, Tanweer FA, Akhtar MS and Nasehi A (2015) Molecular breeding strategy and challenges towards improvement of blast disease resistance in rice crop. Frontiers in Plant Science 6: 886.). The available markers are classified into dominant and codominant, according to the allelic information provided. Initially, the use was predominant of Restriction Fragment Length Polymorphism (RFLP) (Botstein et al. 1980Botstein D, White RL, Skolnick M and Davis RW (1980) Construction of a genetic linkage map in man using restriction fragment length polymorphisms. American Journal of Human Genetics 32: 314.), codominant, and Randomly Amplified Polymorphic DNA (RAPD) (Williams et al. 1990Williams JG, Kubelik AR, Livak KJ, Rafalski JA and Tingey SV (1990) DNA polymorphisms amplified by arbitrary primers are useful as genetic markers. Nucleic Acids Research 18: 6531-6535.), dominant markers. Subsequently, codominant Simple Sequence Repeats (SSR) markers (Akkaya et al. 1992Akkaya MS, Bhagwat AA and Cregan PB (1992) Length polymorphisms of simple sequence repeat DNA in soybean. Genetics 132: 1131-1139., Ashkani et al. 2015Ashkani S, Rafii MY, Shabanimofrad M, Miah G, Sahebi M, Azizi P, Tanweer FA, Akhtar MS and Nasehi A (2015) Molecular breeding strategy and challenges towards improvement of blast disease resistance in rice crop. Frontiers in Plant Science 6: 886.) were developed. Markers generated by analysis of Amplified Fragment Length Polymorphisms (AFLP) and Retrotransposon-Microsatellite Amplified Polymorphism (REMAP) markers (Kalendar et al. 1999Kalendar R, Grob T, Regina M, Suoniemi A and Schulman A (1999) IRAP and REMAP: two new retrotransposon-based DNA fingerprinting techniques. Theoretical and Applied Genetics 98: 704-711.) were also widely used. The most commonly used markers today are Single Nucleotide Polymorphism (SNP), which are considered to be highly efficient (Korinsak et al. 2019Korinsak S, Tangphatsornruang S, Pootakham W, Wanchana S, Plabpla A, Jantasuriyarat C, Patarapuwadol S, Vanavichit A and Toojinda T (2019) Genome-wide association mapping of virulence gene in rice blast fungus Magnaporthe oryzae using a genotyping by sequencing approach. Genomics 111: 661-668.). In this case, a large number of markers that are spread across the genome are analyzed simultaneously in automated systems, increasing the probability that regions associated with traits of interest are in strong linkage disequilibrium (Miah et al. 2013Miah G, Rafii MY, Ismail MR, Puteh AB, Rahim HA, Asfaliza R and Latif MA (2013) Blast resistance in rice: a review of conventional breeding to molecular approaches. Molecular Biology Reports 40: 2369-2388.).
The use of a marker for indirect selection of a trait of interest is called marker assisted selection (MAS) (Das et al. 2017Das G, Patra JK and Baek KH (2017) Insight into MAS: a molecular tool for development of stress resistant and quality of rice through gene stacking. Frontiers in Plant Science 8: 985.). MAS integrates molecular genetics with phenotypic selection and is based on the presence of a marker linked to a region of the genome that controls a certain characteristic to perform the selection (Ashkani et al. 2015Ashkani S, Rafii MY, Shabanimofrad M, Miah G, Sahebi M, Azizi P, Tanweer FA, Akhtar MS and Nasehi A (2015) Molecular breeding strategy and challenges towards improvement of blast disease resistance in rice crop. Frontiers in Plant Science 6: 886.), and in some specific cases, the markers may be part of the gene of interest. In plant breeding programs for resistance to diseases such as blast, which use MAS as an auxiliary tool, it is necessary to continuously characterize the genetic variability of pathogens and the host, the introduction and characterization of new sources of resistance, and the identification of new molecular markers linked to resistance alleles (Ashkani et al. 2015Ashkani S, Rafii MY, Shabanimofrad M, Miah G, Sahebi M, Azizi P, Tanweer FA, Akhtar MS and Nasehi A (2015) Molecular breeding strategy and challenges towards improvement of blast disease resistance in rice crop. Frontiers in Plant Science 6: 886.).
Some successful examples of MAS for blast resistance in rice cultivars were summarized by Tanweer et al. (2015Tanweer FA, Rafii MY, Sijam K, Rahim HA, Ahmed F and Latif MA (2015) Current advance methods for the identification of blast resistance genes in rice. Comptes Rendus Biologies 338: 321-334.). In addition, MAS selection for rice blast resistance was used to screen for resistance genes Pi-b, Pi-k, Pi-i, Pi-z and Pi-ta, as well as for the pyramiding of genes using Pi-ta, aiming for broad spectrum resistance (Biswal et al. 2017Biswal AK, Shamim MD, Cruzado K, Soriano G, Ghatak A, Toleco M and Vikram P (2017) Role of biotechnology in rice production. In Chauhan B, Jabran K and Mahajan G (Eds) Rice production worldwide. Springer, Cham, p. 487-547.). Recently, a study using the quantitative resistance gene pi21 was introduced in strains of rice indica and japonica with the aid of marker-assisted backcrossing. All lines showed resistance to 11 blast isolates in leaves, both at field and greenhouse conditions (Angeles-Shim et al. 2020Angeles-Shim RB, Reyes VP, Del Valle MM, Lapis RS, Shim J, Sunohara H, Jena KK, Ashikari M and Doi K (2020) Marker-assisted introgression of quantitative resistance gene pi21 confers broad spectrum resistance to rice blast. Rice Science 27: 113-123.).
In addition to the R genes, another promising strategy in the search for durable resistance is the introduction of quantitative resistance controlled by QTLs with the aid of MAS. For that, markers that flank up to three QTLs are used, which should explain a large proportion of the phenotypic variation (Ashkani et al. 2015Ashkani S, Rafii MY, Shabanimofrad M, Miah G, Sahebi M, Azizi P, Tanweer FA, Akhtar MS and Nasehi A (2015) Molecular breeding strategy and challenges towards improvement of blast disease resistance in rice crop. Frontiers in Plant Science 6: 886.). The application of R and QTLs genes in rice breeding programs is considered a strategic way to control blast, due to its effectiveness, economy and low environmental risk (Biswal et al. 2017Biswal AK, Shamim MD, Cruzado K, Soriano G, Ghatak A, Toleco M and Vikram P (2017) Role of biotechnology in rice production. In Chauhan B, Jabran K and Mahajan G (Eds) Rice production worldwide. Springer, Cham, p. 487-547.). Increasingly, breeders are seeking the help of MAS for the development of new commercial rice cultivars to complement conventional breeding (Prabhu and Filippi 2006Prabhu AS and Filippi MD (2006) Brusone em arroz: controle genético, progresso e perspectivas. Embrapa Arroz e Feijão, Santo Antônio de Goiás, 387p.).
GENETIC MAPPING
Linkage mapping
Procedures using biotechnological tools, such as the mapping of genes of economic importance, based on genetic maps, have been shown to be important complements in breeding programs for a wide range of plant species (Ashkani et al. 2015Ashkani S, Rafii MY, Shabanimofrad M, Miah G, Sahebi M, Azizi P, Tanweer FA, Akhtar MS and Nasehi A (2015) Molecular breeding strategy and challenges towards improvement of blast disease resistance in rice crop. Frontiers in Plant Science 6: 886.). Among the most important applications of genetic maps is the location of genes that control complex inheritance traits, such as disease resistance. In genetic mapping, an analysis is performed that determines the number of molecular markers linked to genetic loci that control quantitative traits (QTLs), as well as to loci that control qualitative traits (Nordborg and Weigel 2008Nordborg M and Weigel D (2008) Next-generation genetics in plants. Nature 456: 720-723., Raboin et al. 2016Raboin LM, Ballini E, Tharreau D, Ramanantsoanirina A, Frouin J, Courtois B and Ahmadi N (2016) Association mapping of resistance to rice blast in upland field conditions. Rice 9: 1-12., Korinsak et al. 2019Korinsak S, Tangphatsornruang S, Pootakham W, Wanchana S, Plabpla A, Jantasuriyarat C, Patarapuwadol S, Vanavichit A and Toojinda T (2019) Genome-wide association mapping of virulence gene in rice blast fungus Magnaporthe oryzae using a genotyping by sequencing approach. Genomics 111: 661-668.).
Techniques based on the use of molecular markers allow the study of regions that influence the expression of traits of interest, as well as their respective loci, facilitating the selection of superior genotypes (Desta and Ortiz 2014Desta ZA and Ortiz R (2014) Genomic selection: genome-wide prediction in plant improvement. Trends in Plant Science 19: 592-601.). One of the strategies is linkage mapping, using populations properly constructed for mapping, which allows identifying the position of the QTL through linkage maps, in addition to estimating its effects (Desta and Ortiz 2014, Xu et al. 2017Xu Y, Li P, Yang Z and Xu C (2017) Genetic mapping of quantitative trait loci in crops. The Crop Journal 5: 175-184.). For the formation of a population, it is required to select contrasting parents, which show clear differences for one or more traits (Bered et al. 1997Bered F, Barbosa Neto JF and Carvalho FIFD (1997) Marcadores moleculares e sua aplicação no melhoramento genético de plantas. Ciência Rural 27: 513-520.).
When it comes to blast, knowing the chromosomal locations of resistance genes in a genetic map is essential for manipulating these genes in rice breeding programs. Information like this is useful when selecting contrasting parents for the construction of populations, often composed of NILs. These NILs can be used to evaluate the individual performance of resistance genes and the characterization of the pathogen population and also for mapping clones and pyramiding of genes (Nunes et al. 2007Nunes CD, Carvalho FI, Pierobom CR and Oliveira AC (2007) Genética da resistência de cultivares de arroz à raça IA-1 de Pyricularia grisea. Fitopatologia Brasileira 32: 64-69.). Even though this method proves to be effective, there are some limitations that must be considered, such as the restricted number of alleles, and thus, low genetic variability (populations from the crossing of only two parents), the low resolution of the map and the high demand for time and resources for obtaining populations (Desta and Ortiz 2014Desta ZA and Ortiz R (2014) Genomic selection: genome-wide prediction in plant improvement. Trends in Plant Science 19: 592-601., Xu et al. 2017Xu Y, Li P, Yang Z and Xu C (2017) Genetic mapping of quantitative trait loci in crops. The Crop Journal 5: 175-184.). However, through the previously mentioned approach, linkage maps have made it possible to identify numerous QTLs and their positions in the genome of the studied individuals (as described in section 3.1), as well as to estimate their genetic effects, showing themselves as a viable alternative for the genetic improvement of blast resistance.
Association mapping
Association or linkage desequilibrium mapping, also known as genome-wide association studies (GWAS) is a model that aims to detect the statistical association between genotypic and phenotypic values (Raboin et al. 2016Raboin LM, Ballini E, Tharreau D, Ramanantsoanirina A, Frouin J, Courtois B and Ahmadi N (2016) Association mapping of resistance to rice blast in upland field conditions. Rice 9: 1-12., Xu et al. 2017Xu Y, Li P, Yang Z and Xu C (2017) Genetic mapping of quantitative trait loci in crops. The Crop Journal 5: 175-184., Korinsak 2019Korinsak S, Tangphatsornruang S, Pootakham W, Wanchana S, Plabpla A, Jantasuriyarat C, Patarapuwadol S, Vanavichit A and Toojinda T (2019) Genome-wide association mapping of virulence gene in rice blast fungus Magnaporthe oryzae using a genotyping by sequencing approach. Genomics 111: 661-668.). These studies have made it possible to evaluate the germplasm available in order to explore the genetic variability in a plant population of a crop for use in breeding programs (Korinsak 2019Korinsak S, Tangphatsornruang S, Pootakham W, Wanchana S, Plabpla A, Jantasuriyarat C, Patarapuwadol S, Vanavichit A and Toojinda T (2019) Genome-wide association mapping of virulence gene in rice blast fungus Magnaporthe oryzae using a genotyping by sequencing approach. Genomics 111: 661-668.). The technique is based on the concept of linkage desequilibrium (DL), which refers to the non-random association of alleles between different loci (Oraguzie and Wilcox 2007Oraguzie NC and Wilcox PL (2007) An Overview of Association Mapping. In: Oraguzie NC, Rikkerink EHA, Gardiner SE, De Silva HN (eds) Association Mapping in Plants. Springer, New York , p. 1-9., Xu et al. 2017Xu Y, Li P, Yang Z and Xu C (2017) Genetic mapping of quantitative trait loci in crops. The Crop Journal 5: 175-184.). Analyzes performed with a large number of markers spread throughout the genome increase the probability that regions associated with traits of interest are in strong linkage imbalance with the markers (Oraguzie and Wilcox 2007Oraguzie NC and Wilcox PL (2007) An Overview of Association Mapping. In: Oraguzie NC, Rikkerink EHA, Gardiner SE, De Silva HN (eds) Association Mapping in Plants. Springer, New York , p. 1-9.). GWAS becomes more efficient in species that have been sequenced, such as rice, because in this way it is possible to analyze an unlimited number of traits in genetically identical material and different environments (Oraguzie and Wilcox 2007Oraguzie NC and Wilcox PL (2007) An Overview of Association Mapping. In: Oraguzie NC, Rikkerink EHA, Gardiner SE, De Silva HN (eds) Association Mapping in Plants. Springer, New York , p. 1-9., Raboin et al. 2016Raboin LM, Ballini E, Tharreau D, Ramanantsoanirina A, Frouin J, Courtois B and Ahmadi N (2016) Association mapping of resistance to rice blast in upland field conditions. Rice 9: 1-12.). In recent years, many loci have been identified in several studies with the aid of GWAS (Toledo et al. 2008Toledo ER, Leandro RA, de Souza Junior CL and de Souza AP (2008) Mapeamento de QTLs: uma abordagem bayesiana. Revista Brasileira Biometria 26:107-114.). In a study of GWAS with indica rice, 366 varieties were selected to compose the population that was inoculated with 16 isolates of Pyricularia oryzae, which resulted in the identification of 30 loci associated with resistance to the disease (Wang et al. 2014Wang C, Yang Y, Yuan X, Xu Q, Feng Y, Yu H and Wang Y (2014) Genome-wide association study of blast resistance in indica rice. BMC Plant Biology 14: 1-11. ). Another study with GWAS used a population of 1,495 hybrid rice varieties to assess resistance to blast and 38 other agronomic traits and identified four loci associated with resistance (Huang et al. 2015Huang X, Yang S, Gong J, Zhao Y, Fen Q, Gong H, Li W, Zhan Q, Cheng B, Xia J and Chen N (2015) Genomic analysis of hybrid rice varieties reveals numerous superior alleles that contribute to heterosis. Nature Communications 6: 1-9.). Other GWAS for blast resistance in rice were performed (Lin et al. 2018Lin HA, Chen SY, Chang FY, Tung CW, Chen YC, Shen WC, Chen RS, Wu CW and Chung CL (2018) Genome-wide association study of rice genes and loci conferring resistance to Magnaporthe oryzae isolates from Taiwan. Botanical Studies 59: 1-14., Li et al. 2019Li C, Wang D, Peng S, Chen Y, Su P, Chen J, Zheng L, Tan X, Liu J, Xiao Y and Kang H (2019) Genome-wide association mapping of resistance against rice blast strains in South China and identification of a new Pik allele. Rice 12: 1-9., Lu et al. 2019Lu Q, Wang C, Niu X, Zhang M, Xu Q, Feng Y, Yang Y, Wang S, Yuan X, Yu H and Wang Y (2019) Detecting novel loci underlying rice blast resistance by integrating a genome-wide association study and RNA sequencing. Molecular Breeding 39: 1-10., Volante et al. 2020Volante A, Tondelli A, Desiderio F, Abbruscato P, Menin B, Biselli C, Casella L, Singh N, McCouch SR, Tharreau D and Zampieri E (2020) Genome wide association studies for japonica rice resistance to blast in field and controlled conditions. Rice 13: 1-17., Frontini et al. 2021Frontini M, Boisnard A, Frouin J, Ouikene M, Morel JB and Ballini E (2021) Genome-wide association of rice response to blast fungus identifies loci for robust resistance under high nitrogen. BMC Plant Biology 21:1-12.).
Genome editing
Variability is essential for the breeding process. When the genetic variability is absent from the germplasm or hard to transfer, mutation-inducing approaches can be used (Zhu et al. 2017Zhu C, Bortesi L, Baysal C, Twyman RM, Fischer R, Capell T, Schillberg S and Christou P (2017) Characteristics of genome editing mutations in cereal crops. Trends in Plant Science 22: 38-52, Viana et al. 2019Viana VE, Pegoraro C, Busanello C and Costa de Oliveira A (2019) Mutagenesis in rice: the basis for breeding a new super plant. Frontiers in Plant Science 10: 1326.). These methods are being aided by editing technologies, which make it possible to precisely manipulate specific sequences in the genome, that is, it allows the insertion, deletion or substitution of nucleotides in specific genes or sequences (Viana et al. 2019Viana VE, Pegoraro C, Busanello C and Costa de Oliveira A (2019) Mutagenesis in rice: the basis for breeding a new super plant. Frontiers in Plant Science 10: 1326., Ijaz and Ul Haq 2020Ijaz S and Ul Haq I (2020) Genome editing technologies for resistance against phytopathogens: principles, applications and future prospects. In Ul Haq I and Ijaz S (eds) Plant disease management strategies for sustainable agriculture through traditional and modern approaches. Sustainability in plant and crop protection. Springer, Cham , p. 237-245. ). Editing strategies use Sequence-specific nucleases (SSNs), which promote the induction of double-strand DNA breaks (DSBs) in specific locations within the genome in a mediated way. These breaks are solved with the help of cell repair mechanisms (homologous recombination - HR and non-homologous end joining - NHEJ) (Zhu et al. 2017Zhu C, Bortesi L, Baysal C, Twyman RM, Fischer R, Capell T, Schillberg S and Christou P (2017) Characteristics of genome editing mutations in cereal crops. Trends in Plant Science 22: 38-52, Viana et al. 2019Viana VE, Pegoraro C, Busanello C and Costa de Oliveira A (2019) Mutagenesis in rice: the basis for breeding a new super plant. Frontiers in Plant Science 10: 1326.). Among the first techniques involving nucleases there were the Meganucleases (MNs) and Zinc finger nucleases (ZFNs) (Zhu et al. 2017Zhu C, Bortesi L, Baysal C, Twyman RM, Fischer R, Capell T, Schillberg S and Christou P (2017) Characteristics of genome editing mutations in cereal crops. Trends in Plant Science 22: 38-52). Soon after, Transcription activator-like effector nucleases (TALENs) were developed. More recently, a new genomic editing technology, called Clustered regularly interspaced short palindromic repeat/CRISPR-associated protein (CRISPR/Cas9) has been developed (Viana et al. 2019Viana VE, Pegoraro C, Busanello C and Costa de Oliveira A (2019) Mutagenesis in rice: the basis for breeding a new super plant. Frontiers in Plant Science 10: 1326.).
Genomic editing technologies can accelerate the process of plant breeding, allowing the creation of cultivars that are resistant to pathogens by modifying loci involved in the plant's defense system (Yin and Qiu 2019Yin K and Qiu JL (2019) Genome editing for plant disease resistance: applications and perspectives. Philosophical Transactions of the Royal Society B 374: 20180322.). In particular, the CRISPR/Cas9 technique has so far shown the greatest promise to address emerging challenges in agriculture (Haque et al. 2018Haque E, Taniguchi H, Hassan M, Bhowmik P, Karim MR, Śmiech M, Zhao K, Rahman M and Islam T (2018) Application of CRISPR/Cas9 genome editing technology for the improvement of crops cultivated in tropical climates: recent progress, prospects, and challenges. Frontiers in Plant Science 9: 617.). Compared to other genome editing tools, CRISPR/Cas9 is easier, more economical, accurate and highly efficient because it allows the expression of several genes (multiplex) to be modulated (Molinari et al. 2020Molinari HBC, Vieira LR, Volpi e Silva N, Prado GS and Lopes Filho JH (eds) (2020) CRISP na edição genômica de plantas. Biotecnologia aplicada à agricultura .. Embrapa, Brasília, 210p.).
MNs
Meganucleases (MNs) are highly specific enzymes that recognize and cleave specific sequences, from 11 to 40 bp, inducing homologous recombination in different types of cells (Daboussi et al. 2015Daboussi F, Stoddard TJ and Zhang F (2015) Engineering meganuclease for precise plant genome modification. In Advances in new technology for targeted modification of plant genomes. Springer, New York, p. 21-38, Viana et al. 2019Viana VE, Pegoraro C, Busanello C and Costa de Oliveira A (2019) Mutagenesis in rice: the basis for breeding a new super plant. Frontiers in Plant Science 10: 1326.). Recombination induced by MNs generates DSBs in specific target DNA sequences, which will be repaired by HR using the donor DNA or by NHEJ (Daboussi et al. 2015). The understanding and use of this tool came after many studies involving the LAGLIDADG family of proteins (Arnould et al. 2011Arnould S, Delenda C, Grizot S, Desseaux C, Paques F, Silva GH and Smith J (2011) The I-CreI meganuclease and its engineered derivatives: applications from cell modification to gene therapy. Protein Engineering, Design & Selection 24: 27-31.). Among the functionalities of LAGLIDADG proteins are their role as RNA maturases, involved in the splicing of their own intron, and as highly specific endonucleases, which are able to recognize and cleave the exon-exon junction sequence in which their intron resides. The understanding of MNs from the LAGLIDADG family and their interaction with DNA allowed the exploration of a wide range of biotechnological applications, including the modification of MNs for use in gene editing (Arnould et al. 2011Arnould S, Delenda C, Grizot S, Desseaux C, Paques F, Silva GH and Smith J (2011) The I-CreI meganuclease and its engineered derivatives: applications from cell modification to gene therapy. Protein Engineering, Design & Selection 24: 27-31.). However, this is an underused tool due to its limitations, such as recognizing few DNA sequences and the possibility of errors occurring due to insertions or deletions at the cleavage site (Daboussi et al. 2015Daboussi F, Stoddard TJ and Zhang F (2015) Engineering meganuclease for precise plant genome modification. In Advances in new technology for targeted modification of plant genomes. Springer, New York, p. 21-38, Majid et al. al. 2017Majid A, Parray GA, Wani SH, Kordostami M, Sofi NR, Waza SA, Shikari AB and Gulzar S (2017) Genome editing and its necessity in agriculture. International Journal of Current Microbiology and Applied Sciences 6: 5435-5443., Yadav et al. 2019Yadav L, Kapoor P and Kumar A (2019) Genome editing: methods and application in plant pathology. International Journal of Current Microbiology and Applied Sciences 8: 1301-1319., Yin and Qiu 2019Yin K and Qiu JL (2019) Genome editing for plant disease resistance: applications and perspectives. Philosophical Transactions of the Royal Society B 374: 20180322.).
This tool has been successfully used in many species, such as Arabidopsis, cotton and corn (Daboussi et al. 2015Daboussi F, Stoddard TJ and Zhang F (2015) Engineering meganuclease for precise plant genome modification. In Advances in new technology for targeted modification of plant genomes. Springer, New York, p. 21-38, Zhu et al. 2017Zhu C, Bortesi L, Baysal C, Twyman RM, Fischer R, Capell T, Schillberg S and Christou P (2017) Characteristics of genome editing mutations in cereal crops. Trends in Plant Science 22: 38-52, Viana et al. 2019Viana VE, Pegoraro C, Busanello C and Costa de Oliveira A (2019) Mutagenesis in rice: the basis for breeding a new super plant. Frontiers in Plant Science 10: 1326.). In a study in transgenic cotton, MNs developed for the cleavage of a specific target DNA sequence adjacent to a locus responsible for insect resistance were used. MNs induced DBS in embryogenic callus cells, in the presence of exogenous DNA containing resistance to two herbicides. It was possible to observe that approximately 2% of the events were shown to contain the correct insertion and to transfer the characteristics of both insect and herbicide resistance to subsequent generations (D'Halluin et al. 2013D'Halluin K, Vanderstraeten C, Van Hulle J, Rosolowska J, Van Den Brande I, Pennewaert A, D'Hont K, Bossut M, Jantz D, Ruiter R and Broadhvest J (2013) Targeted molecular trait stacking in cotton through targeted double‐strand break induction. Plant Biotechnology Journal 11: 933-941.). However, even though there are no reports of the application of MN in rice crops, this may be an available alternative (Daboussi et al. 2015Daboussi F, Stoddard TJ and Zhang F (2015) Engineering meganuclease for precise plant genome modification. In Advances in new technology for targeted modification of plant genomes. Springer, New York, p. 21-38, Zhu et al. 2017Zhu C, Bortesi L, Baysal C, Twyman RM, Fischer R, Capell T, Schillberg S and Christou P (2017) Characteristics of genome editing mutations in cereal crops. Trends in Plant Science 22: 38-52, Viana et al. 2019Viana VE, Pegoraro C, Busanello C and Costa de Oliveira A (2019) Mutagenesis in rice: the basis for breeding a new super plant. Frontiers in Plant Science 10: 1326.).
ZFNs
Zinc finger nucleases (ZFNs) are composed of the modified restriction enzyme Fok I (Flavobacterium okeanokoites) associated with zinc finger amino acid sequences (Osakabe and Osakabe 2015Osakabe Y and Osakabe K (2015) Genome editing with engineered nucleases in plants. Plant and Cell Physiology 56: 389-400., Zhu et al. 2017Zhu C, Bortesi L, Baysal C, Twyman RM, Fischer R, Capell T, Schillberg S and Christou P (2017) Characteristics of genome editing mutations in cereal crops. Trends in Plant Science 22: 38-52, Ijaz and Ul Haq 2020Ijaz S and Ul Haq I (2020) Genome editing technologies for resistance against phytopathogens: principles, applications and future prospects. In Ul Haq I and Ijaz S (eds) Plant disease management strategies for sustainable agriculture through traditional and modern approaches. Sustainability in plant and crop protection. Springer, Cham , p. 237-245. ). Fok I has two domains, an N-terminal DNA-binding domain and a C-terminal domain with non-specific DNA cleavage activity. Zinc-finger amino acid sequences are capable of recognizing specific sequences of 3 or 4 nucleotides (Kim et al. 1996Kim YG, Cha J and Chandrasegaran S (1996) Hybrid restriction enzymes: zinc finger fusions to Fok I cleavage domain. Proceedings of the National Academy of Sciences 93: 1156-1160., Qi 2015Qi Y (2015) High efficient genome modification by designed zinc finger nuclease. In Zhang F, Puchta H and Thomson J (eds) Advances in new technology for targeted modification of plant genomes. Springer, New York , p. 39-53, Zhu et al. 2017Zhu C, Bortesi L, Baysal C, Twyman RM, Fischer R, Capell T, Schillberg S and Christou P (2017) Characteristics of genome editing mutations in cereal crops. Trends in Plant Science 22: 38-52). Fusion of zinc finger motifs with the Fok I cleavage domain forms ZFNs, which are used for genome editing by introducing DSBs into specific genomic DNA sites (Qi 2015Qi Y (2015) High efficient genome modification by designed zinc finger nuclease. In Zhang F, Puchta H and Thomson J (eds) Advances in new technology for targeted modification of plant genomes. Springer, New York , p. 39-53, Zhu et al. 2017Zhu C, Bortesi L, Baysal C, Twyman RM, Fischer R, Capell T, Schillberg S and Christou P (2017) Characteristics of genome editing mutations in cereal crops. Trends in Plant Science 22: 38-52). Thus, using repair mechanisms, target genes can be disrupted by NHEJ-induced mutations, or edited via HR if a homologous/donor DNA is provided (Qi 2015Qi Y (2015) High efficient genome modification by designed zinc finger nuclease. In Zhang F, Puchta H and Thomson J (eds) Advances in new technology for targeted modification of plant genomes. Springer, New York , p. 39-53, Zhu et al. 2017Zhu C, Bortesi L, Baysal C, Twyman RM, Fischer R, Capell T, Schillberg S and Christou P (2017) Characteristics of genome editing mutations in cereal crops. Trends in Plant Science 22: 38-52, Ijaz and Ul Haq 2020Ijaz S and Ul Haq I (2020) Genome editing technologies for resistance against phytopathogens: principles, applications and future prospects. In Ul Haq I and Ijaz S (eds) Plant disease management strategies for sustainable agriculture through traditional and modern approaches. Sustainability in plant and crop protection. Springer, Cham , p. 237-245. ).
The ZFNs genome editing tool has been successfully employed in species such as rice, maize and Arabidopsis (Cantos et al. 2014Cantos C, Francisco P, Trijatmiko KR, Slamet-Loedin I and Chadha-Mohanty PK (2014) Identification of “safe harbor” loci in indica rice genome by harnessing the property of zinc-finger nucleases to induce DNA damage and repair. Frontiers in Plant Science 5: 302., Yin et al. 2019Yin K and Qiu JL (2019) Genome editing for plant disease resistance: applications and perspectives. Philosophical Transactions of the Royal Society B 374: 20180322., Ijaz and Ul Haq 2020Ijaz S and Ul Haq I (2020) Genome editing technologies for resistance against phytopathogens: principles, applications and future prospects. In Ul Haq I and Ijaz S (eds) Plant disease management strategies for sustainable agriculture through traditional and modern approaches. Sustainability in plant and crop protection. Springer, Cham , p. 237-245. ). In rice, ZFNs were used to induce DBS in the sequence containing the SSIVa gene in order to understand its involvement in starch synthesis and its other functionalities (Jung et al. 2018Jung YJ, Nogoy FM, Lee SK, Cho YG and Kang KK (2018) Application of ZFN for site directed mutagenesis of rice SSIVa gene. Biotechnology and Bioprocess Engineering 23: 108-115.). This study demonstrated that disruption of the SSIVa gene had no effect on other genes related to starch synthesis. Thus, ZFNs proved to be efficient in cleaving and stimulating mutations in the SSIVa locus and this can be used for other characters of interest, such as disease resistance (Jung et al. 2018Jung YJ, Nogoy FM, Lee SK, Cho YG and Kang KK (2018) Application of ZFN for site directed mutagenesis of rice SSIVa gene. Biotechnology and Bioprocess Engineering 23: 108-115.).
TALEN
Transcription activator-type artificial effector nuclease (TALEN) has emerged as a plant genome editing tool that offers an alternative to Zinc-finger nucleases (ZFNs) (Christian et al. 2010Christian M, Cermak T, Doyle EL, Schmidt C, Zhang F, Hummel A, Bogdanove AJ and Voytas DF (2010) Targeting DNA double-strand breaks with TAL effector nucleases. Genetics 186: 757-761., Daboussi et al. 2015Daboussi F, Stoddard TJ and Zhang F (2015) Engineering meganuclease for precise plant genome modification. In Advances in new technology for targeted modification of plant genomes. Springer, New York, p. 21-38, Hilscher et al. 2017Hilscher J, Bürstmayr H and Stoger E (2017) Targeted modification of plant genomes for precision crop breeding. Biotechnology Journal 12: 1600173.). TALE are proteins, or transcription factors, that occur naturally in bacteria of the Xanthomonas genus. When the bacterium infects the plant, it secretes proteins into the cytoplasm of the host's cells, which bind to DNA and activate the expression of target genes, in this case, genes that are favorable to infection by the bacterium (Hilscher et al. 2017Hilscher J, Bürstmayr H and Stoger E (2017) Targeted modification of plant genomes for precision crop breeding. Biotechnology Journal 12: 1600173.). These transcription factors recognize specific sequences as they are composed of blocks of repeated 34 amino acids, with each block recognizing a base pair (Christian et al. 2010Christian M, Cermak T, Doyle EL, Schmidt C, Zhang F, Hummel A, Bogdanove AJ and Voytas DF (2010) Targeting DNA double-strand breaks with TAL effector nucleases. Genetics 186: 757-761., Hilscher et al. 2017Hilscher J, Bürstmayr H and Stoger E (2017) Targeted modification of plant genomes for precision crop breeding. Biotechnology Journal 12: 1600173.). The specificity of TALE is determined by two hypervariable amino acids (VDRs), located at position 12 and 13 of the block (Hilscher et al. 2017Hilscher J, Bürstmayr H and Stoger E (2017) Targeted modification of plant genomes for precision crop breeding. Biotechnology Journal 12: 1600173.). VDRs can be manipulated to generate proteins that are programmed to bind to DNA and perform targeted editing at specific points in the genome. The nuclease-independent sequence Fok I acts as a site-specific nuclease and, through fusion with the DNA recognition domain of TALE, creates TALEN that recognize and cleave target DNA sequences (Ma and Liu 2015Ma D and Liu F (2015) Genome editing and its applications in model organisms. Genomics, Proteomics & Bioinformatics 13: 336-344., Viana et al. 2019Viana VE, Pegoraro C, Busanello C and Costa de Oliveira A (2019) Mutagenesis in rice: the basis for breeding a new super plant. Frontiers in Plant Science 10: 1326.). Similar to what happens in ZFNs, TALEN promotes DSBs for genome editing (Chen et al. 2014Chen K, Shan Q and Gao C (2014) An efficient TALEN mutagenesis system in rice. Methods 69: 2-8., Hilscher et al. 2017). DSBs induce activation by NHEJ, which result in insertions or deletions, and can also be repaired by HR when a homologous DNA is introduced, generating specific alterations (Christian et al. 2010Christian M, Cermak T, Doyle EL, Schmidt C, Zhang F, Hummel A, Bogdanove AJ and Voytas DF (2010) Targeting DNA double-strand breaks with TAL effector nucleases. Genetics 186: 757-761., Chen et al. 2014Chen K, Shan Q and Gao C (2014) An efficient TALEN mutagenesis system in rice. Methods 69: 2-8., Daboussi et al. 2015Daboussi F, Stoddard TJ and Zhang F (2015) Engineering meganuclease for precise plant genome modification. In Advances in new technology for targeted modification of plant genomes. Springer, New York, p. 21-38, Zhu et al. 2017Zhu C, Bortesi L, Baysal C, Twyman RM, Fischer R, Capell T, Schillberg S and Christou P (2017) Characteristics of genome editing mutations in cereal crops. Trends in Plant Science 22: 38-52).
This technique has been successfully used in several crops such as maize, barley, wheat and rice (Ijaz and Ul Haq 2020Ijaz S and Ul Haq I (2020) Genome editing technologies for resistance against phytopathogens: principles, applications and future prospects. In Ul Haq I and Ijaz S (eds) Plant disease management strategies for sustainable agriculture through traditional and modern approaches. Sustainability in plant and crop protection. Springer, Cham , p. 237-245. ). In rice, the TALEN technique was successfully applied to generate plants resistant to bacterial spot caused by Xanthomonas oryzae pv. oryzae. The plants were edited in the promoter region of a gene that encodes a sucrose efflux transporter (OsSWEET14), which acts on the survival and virulence of the pathogen in the plant. The gene was silenced to generate resistance to the pathogen (Li et al. 2012Li T, Liu B, Spalding MH, Weeks DP and Yang B (2012) High-efficiency TALEN-based gene editing produces disease-resistant rice. Nature Biotechnology 30: 390.). It was also shown that a modification in the TALEN technique can improve up to 100% the efficiency of replacement of specific genes for resistance to the fungus Pyricularia oryzae. The technique using modified TALENs, which was called Platinum-Fungal TALENs (PtFg TALENs), showed great potential for applications in filamentous fungi, such as the one causing blast (Arazoe et al. 2015Arazoe T, Ogawa T, Miyoshi K, Yamato T, Ohsato S, Sakuma T, Yamamoto T, Arie T and Kuwata S (2015) Tailor‐made TALEN system for highly efficient targeted gene replacement in the rice blast fungus. Biotechnology and Bioengineering 112: 1335-1342.).
CRISPR/Cas9
The application of CRISPR/Cas9 as a genomic editing tool emerged from fundamental discoveries about the immune system in bacteria against invasion of foreign DNA (Wiedenheft et al. 2012Wiedenheft B, Sternberg SH and Doudna JA (2012) RNA-guided genetic silencing systems in bacteria and archaea. Nature: 331-338.). Two simple components are needed to use the CRISPR/Cas9 technique. The first component is sgRNA, in which crRNA is associated with tracrRNA to make a hybrid sequence called single guided RNA (sgRNA), which stimulates/guides the second component, the enzyme Cas9, to a specific sequence in the genome. This enzyme cleaves the sequence in the genome whose correspondence is present in the sgRNA (Langner et al. 2018Langner T, Kamoun S and Belhaj K (2018) CRISPR crops: plant genome editing toward disease resistance. Annual Review of Phytopathology 56: 479-512., Viana et al. 2019Viana VE, Pegoraro C, Busanello C and Costa de Oliveira A (2019) Mutagenesis in rice: the basis for breeding a new super plant. Frontiers in Plant Science 10: 1326.). This break will be repaired by HR (if a donor/homologous DNA is provided) or by NHEJ (if no homologous DNA is provided).
The development of the CRISPR/Cas9 technique has opened up a wide range of applications and should also be explored in improving plant resistance to pathogens (Langner et al. 2018Langner T, Kamoun S and Belhaj K (2018) CRISPR crops: plant genome editing toward disease resistance. Annual Review of Phytopathology 56: 479-512., Viana et al. 2019Viana VE, Pegoraro C, Busanello C and Costa de Oliveira A (2019) Mutagenesis in rice: the basis for breeding a new super plant. Frontiers in Plant Science 10: 1326.). In rice, a specific mutation in the OsERF922 gene using the CRISPR / Cas9 technique was effective in increasing blast resistance. This is due to the fact that, in culture, plants that express the OsERF922 gene involved in the ethylene route, show a reduction in the expression of defense-related genes and increased susceptibility to Pyricularia oryzae (Wang et al. 2016Wang F, Wang C, Liu P, Lei C, Hao W, Gao Y, Liu YG and Zhao K (2016) Enhanced rice blast resistance by CRISPR/Cas9-targeted mutagenesis of the ERF transcription factor gene OsERF922. PloS one 11: 0154027.).
Transgenics
Using this technology, breeders can precisely manipulate the gene that encodes a trait of interest by inserting genes from unrelated species or by silencing specific genes (Miah et al. 2013Miah G, Rafii MY, Ismail MR, Puteh AB, Rahim HA, Asfaliza R and Latif MA (2013) Blast resistance in rice: a review of conventional breeding to molecular approaches. Molecular Biology Reports 40: 2369-2388.). For the control of pathogens, it is possible to transfer R genes involved in the recognition of the pathogen and transfer genes from the pathogen that, when expressed, activate the plant's defense system (Miah et al. 2013Miah G, Rafii MY, Ismail MR, Puteh AB, Rahim HA, Asfaliza R and Latif MA (2013) Blast resistance in rice: a review of conventional breeding to molecular approaches. Molecular Biology Reports 40: 2369-2388., Biswal et al. 2017Biswal AK, Shamim MD, Cruzado K, Soriano G, Ghatak A, Toleco M and Vikram P (2017) Role of biotechnology in rice production. In Chauhan B, Jabran K and Mahajan G (Eds) Rice production worldwide. Springer, Cham, p. 487-547.). Transgenics involving R genes from sexually incompatible plants have been seen as alternatives for obtaining durable resistance to pathogens (Toenniessen et al. 2003Toenniessen GH, O’Toole JC and DeVries J (2003) Advances in plant biotechnology and its adoption in developing countries. Current Opinion in Plant Biology 6: 191-198., Maciel and Danelli 2018Maciel JLN and Danelli ALD (2018) Resistência genética de plantas a fungos. In Dallagnol LJ (Org) Resistência genética de plantas a patógenos. UFPel, Pelotas, p. 359- 393.). In rice, some transgenic strategies for breeding aimed at blast resistance have been developed. Homozygous transgenic rice lines that harbor the Pi-d2 gene showed high resistance to neck blast incidence (Chen et al. 2010Chen DX, Chen XW, Lei CL, Wang YP and Li SG (2010) Rice blast resistance of transgenic rice plants with Pi-d2 gene. Rice Science 17: 179-184.). In another study, transgenic rice plants were developed using two elicitor genes (MoHrip1 and MoHrip2) from Pyricularia oryzae, and these plants showed high resistance against blast and higher tolerance to water stress (Wang et al. 2017Wang Z, Han Q, Zi Q, Lv S, Qiu D and Zeng H (2017) Enhanced disease resistance and drought tolerance in transgenic rice plants overexpressing protein elicitors from Magnaporthe oryzae. PLoS One 12: 0175734.). Similarly, rice overexpressing the effector gene MoSDT1 showed improved blast resistance (Wang et al. 2019Wang C, Li C, Duan G, Wang Y, Zhang Y and Yang J (2019) Overexpression of Magnaporthe oryzae systemic defense trigger 1 (MoSDT1) confers improved rice blast resistance in rice. International Journal of Molecular Sciences 20: 4762.). In addition, the overexpression of calcium-dependent protein kinase (OsCPK4), involved in calcium influx upon pathogen recognition in plant, confer more resistance to blast (Bundó and Coca 2015Bundó M and Coca M (2016) Enhancing blast disease resistance by overexpression of the calcium‐dependent protein kinase OsCPK4 in rice. Plant Biotechnology Journal 14: 1357-1367.). In another study Chandran et al. (2019Chandran V, Wang H, Gao F, Cao XL, Chen YP, Li GB, Zhu Y, Yang XM, Zhang LL, Zhao ZX and Zhao JH (2019) miR396-OsGRFs module balances growth and rice blast disease-resistance. Frontiers in Plant Science 9: 1999.) verified that transgenic rice overexpressing Growth Regulating Factor genes (OsGRF6, OsGRF7, OsGRF8, and OsGRF9) exhibited enhanced resistance to blast, but showed different alteration of growth. In another study, the association between blast resistance and overexpression of the transcription factor WRKY45 was explored by Shimono et al. (2007Shimono M, Sugano S, Nakayama A, Jiang CJ, Ono K, Toki S and Takatsuji H (2007) Rice WRKY45 plays a crucial role in benzothiadiazole-inducible blast resistance. The Plant Cell 19: 2064-2076.).
FINAL CONSIDERATIONS
Rice blast, caused by the fungus Pyricularia oryzae, is an example of the destructive potential of plant pathogens, and has the ability to affect world food security. Improvement aimed at resistance to diseases has been one of the main objectives in plant breeding programs and, in rice, the work on developing blast resistant cultivars has been going on for several years. There are several plant breeding methods available for the development of resistant cultivars and it is up to breeders to find the best ways to deal with this problem.
Conventional breeding is difficult to keep up with the evolutionary potential of the pathogen and, consequently, there is a constant deficit in commercial blast resistant rice. Molecular biology techniques, such as genetic mapping and marker-assisted selection, have been used for some years to improve germplasm and develop new cultivars. More recent techniques, such as transgenics and genomic editing, can be applied to carry out specific genetic modifications and have great potential for the development of plants resistant to the disease.
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Publication Dates
-
Publication in this collection
30 July 2021 -
Date of issue
2021
History
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Received
22 June 2021 -
Accepted
27 June 2021 -
Preprint posted on
05 July 2021