Allele mining and enhanced genetic recombination for rice breeding.

Hei Leung,Frances Nikki Borja,Casiana Vera Cruz,Kenneth L Mcnally,Rakesh Kumar Singh,Ramil Mauleon,Ricardo Oliva,Chitra Raghavan,Glenn Gregorio,Vanica Lacorte,Victor Jun Ulat,Mona Liza Jubay,Il Ryong Choi,Ruaraidh Sackville Hamilton,Nickolai N Alexandrov,Bo Zhou

doi:10.1186/s12284-015-0069-y

Hei Leung, Frances Nikki Borja + Show 14 more

Open Access

https://doi.org/10.1186/s12284-015-0069-y

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Journal: Rice	Publication Date: Nov 25, 2015
Citations: 74	License type: CC BY 4.0

Affiliation: International Rice Research Institute

Abstract

Traditional rice varieties harbour a large store of genetic diversity with potential to accelerate rice improvement. For a long time, this diversity maintained in the International Rice Genebank has not been fully used because of a lack of genome information. The publication of the first reference genome of Nipponbare by the International Rice Genome Sequencing Project (IRGSP) marked the beginning of a systematic exploration and use of rice diversity for genetic research and breeding. Since then, the Nipponbare genome has served as the reference for the assembly of many additional genomes. The recently completed 3000 Rice Genomes Project together with the public database (SNP-Seek) provides a new genomic and data resource that enables the identification of useful accessions for breeding. Using disease resistance traits as case studies, we demonstrated the power of allele mining in the 3,000 genomes for extracting accessions from the GeneBank for targeted phenotyping. Although potentially useful landraces can now be identified, their use in breeding is often hindered by unfavourable linkages. Efficient breeding designs are much needed to transfer the useful diversity to breeding. Multi-parent Advanced Generation InterCross (MAGIC) is a breeding design to produce highly recombined populations. The MAGIC approach can be used to generate pre-breeding populations with increased genotypic diversity and reduced linkage drag. Allele mining combined with a multi-parent breeding design can help convert useful diversity into breeding-ready genetic resources.

Highlights

Genetic diversity is the foundation for crop improvement
Genes involved in resistance to three rice viruses, Rice stripe virus (RSV) (Wang et al 2014), Rice tungro spherical virus (RTSV) (Lee et al 2010), and Rice yellow mottle virus (RYMV) (Albar et al 2006; Orjuela et al 2013), have been identified and used in developing rice varieties withstanding damages caused by the viruses
The number of the accessions potentially resistant to rice viruses may increase with further identification of genes and single nucleotide polymorphism (SNP) associated with resistance to RSV, RTSV, RYMV, and other rice viruses in the future

Summary

Introduction

Genetic diversity is the foundation for crop improvement. Traditional varieties or landraces of rice harbour a large store of valuable genes that can be used to develop new varieties with improved yield potential, higher nutritional quality, and higher tolerance of the stresses of future climate. The recent completion of re-sequencing of 3,000 genebank accessions (The 3000 Rice Genomes Project, 2014) has revealed the allelic diversity of multiple rice genomes. These new genomes have served genetic research well, they are not adequate for rice breeding that has to take a population genomics approach using genotypes from a large number of rice accessions.

Results

Conclusion