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.
Effective strategies for disease control are crucial for sustaining world food production and ensuring food security for the population. Wheat blast, a disease caused by the pathogen Magnaporthe oryzae pathotype Triticum , has been a concern for cereal producers and researchers due to its aggressiveness and rapid expansion. To solve this problem, the development of resistant varieties with durable resistance is an effective, economical and sustainable way to control the disease. Conventional breeding can be aided by several molecular tools to facilitate the mining of many sources of resistance, such as R genes and QTLs. The identification of new sources of resistance, whether in the wheat crop or in other cereals are an opportunity for efficient wheat breeding through the application of different techniques. Since this disease is still poorly studied in wheat, knowledge of the rice Magnaporthe pathotype may be adapted to control wheat blast. Thus, genetic mapping, molecular markers, transgenic approaches, and genomic editing are valuable technologies to fight wheat blast. This review aimed to compile the biotechnological alternatives available to accelerate the development of improved cultivars for resistance to wheat blast.
Rice is one of the most consumed cereals worldwide and feeds about 3 billion people. However, the occurrence of climate changes has influenced abiotic and biotic stresses and consequently affected the production and quality of rice grains. The development of new, higher yielding cultivars is necessary to ensure global food security. Although great progress has already been achieved by conventional breeding, biotechnological tools, such as transgenics and genome editing, can aid in meeting future demands. Gene editing is characterized by cutting and modifying target genes. Among the genome editing techniques, CRISPR/Cas (clustered regularly interspaced short palindromic repeats/Cas), has been proposed because of its ease of manipulation. Variants such as multiple Cas proteins, base editing and prime editing, which aim to increase editing efficiency have also been proposed. Edited plants are more accepted because they are transgene-free. Thus, the objective of this review is to describe the different gene editing techniques and their respective applications in rice breeding. It was observed that the CRISPR/Cas tool was efficient in gene editing in studies related to yield, tolerance to biotic and abiotic stresses, and rice grain quality. However, the impact of this approach in breeding programs depends on the cultivation of edited plants on a large scale in the field. Based on the progress made so far, it is believed that rice breeders can bet on CRISPR/Cas and its variants to help face the current and future challenges of climate change and high food demand.
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