Modern Breeding Strategies and Tools for Durable Late Blight Resistance in Potato.
Ioana Virginia BerindeanAbdelmoumen TaoutaouSoumeya RidaAndreea Daniela OnaMaria Floriana StefanAlexandru CostinIonut RaczLeon MunteanPublished in: Plants (Basel, Switzerland) (2024)
Cultivated potato ( Solanum tuberosum ) is a major crop worldwide. It occupies the second place after cereals (corn, rice, and wheat). This important crop is threatened by the Oomycete Phytophthora infestans , the agent of late blight disease. This pathogen was first encountered during the Irish famine during the 1840s and is a reemerging threat to potatoes. It is mainly controlled chemically by using fungicides, but due to health and environmental concerns, the best alternative is resistance. When there is no disease, no treatment is required. In this study, we present a summary of the ongoing efforts concerning resistance breeding of potato against this devastating pathogen, P. infestans . This work begins with the search for and selection of resistance genes, whether they are from within or from outside the species. The genetic methods developed to date for gene mining, such as effectoromics and GWAS, provide researchers with the ability to identify genes of interest more efficiently. Once identified, these genes are cloned using molecular markers (MAS or QRL) and can then be introduced into different cultivars using somatic hybridization or recombinant DNA technology. More innovative technologies have been developed lately, such as gene editing using the CRISPR system or gene silencing, by exploiting iRNA strategies that have emerged as promising tools for managing Phytophthora infestans , which can be employed. Also, gene pyramiding or gene stacking, which involves the accumulation of two or more R genes on the same individual plant, is an innovative method that has yielded many promising results. All these advances related to the development of molecular techniques for obtaining new potato cultivars resistant to P. infestans can contribute not only to reducing losses in agriculture but especially to ensuring food security and safety.
Keyphrases
- genome wide
- genome wide identification
- copy number
- dna methylation
- climate change
- genome wide analysis
- single molecule
- transcription factor
- bioinformatics analysis
- healthcare
- candida albicans
- gene expression
- primary care
- mental health
- social media
- crispr cas
- risk assessment
- health information
- combination therapy
- cell wall
- genome editing
- nucleic acid