Disease-resistance(R)gene cloning in wheat(Triticum aestivum)has been accelerated by the recent surge of genomic resources,facilitated by advances in sequencing technologies and bioinformatics.However,with the challen...Disease-resistance(R)gene cloning in wheat(Triticum aestivum)has been accelerated by the recent surge of genomic resources,facilitated by advances in sequencing technologies and bioinformatics.However,with the challenges of population growth and climate change,it is vital not only to clone and functionally characterize a few handfuls of R genes,but also to do so at a scale that would facilitate the breeding and deployment of crops that can recognize the wide range of pathogen effectors that threaten agroecosystems.Pathogen populations are continually changing,and breeders must have tools and resources available to rapidly respond to those changes if we are to safeguard our daily bread.To meet this challenge,we propose the creation of a wheat R-gene atlas by an international community of researchers and breeders.The atlas would consist of an online directory from which sources of resistance could be identified and deployed to achieve more durable resistance to the major wheat pathogens,such as wheat rusts,blotch diseases,powdery mildew,and wheat blast.We present a costed proposal detailing how the inter-acting molecular components governing disease resistance could be captured from both the host and the pathogen through biparental mapping,mutational genomics,and whole-genome association genetics.We explore options for the configuration and genotyping of diversity panels of hexaploid and tetraploid wheat,as well as their wild relatives and major pathogens,and discuss how the atlas could inform a dynamic,durable approach to R-gene deployment.Set against the current magnitude of wheat yield losses worldwide,recently estimated at 21%,this endeavor presents one route for bringing R genes from the lab to the field at a considerable speed and quantity.展开更多
基金the UK Biotechnology and Biological Sciences Research Council(BBSRC)through the cross-institute strategic program Designing Future Wheat(BB/P016855/1)the 2Blades Foundation,USA+2 种基金a UKRI-BBSRC Norwich Research Park Biosciences Doctoral Training Partnership fellowship to A.N.H.a BBSRC/RAGT Industrial Collaborative Award in Science and Engineering fellowship to D.G.and a Monsanto Beachell-Borlaug International Scholars Program fellowship(06-400258-12580)。
文摘Disease-resistance(R)gene cloning in wheat(Triticum aestivum)has been accelerated by the recent surge of genomic resources,facilitated by advances in sequencing technologies and bioinformatics.However,with the challenges of population growth and climate change,it is vital not only to clone and functionally characterize a few handfuls of R genes,but also to do so at a scale that would facilitate the breeding and deployment of crops that can recognize the wide range of pathogen effectors that threaten agroecosystems.Pathogen populations are continually changing,and breeders must have tools and resources available to rapidly respond to those changes if we are to safeguard our daily bread.To meet this challenge,we propose the creation of a wheat R-gene atlas by an international community of researchers and breeders.The atlas would consist of an online directory from which sources of resistance could be identified and deployed to achieve more durable resistance to the major wheat pathogens,such as wheat rusts,blotch diseases,powdery mildew,and wheat blast.We present a costed proposal detailing how the inter-acting molecular components governing disease resistance could be captured from both the host and the pathogen through biparental mapping,mutational genomics,and whole-genome association genetics.We explore options for the configuration and genotyping of diversity panels of hexaploid and tetraploid wheat,as well as their wild relatives and major pathogens,and discuss how the atlas could inform a dynamic,durable approach to R-gene deployment.Set against the current magnitude of wheat yield losses worldwide,recently estimated at 21%,this endeavor presents one route for bringing R genes from the lab to the field at a considerable speed and quantity.
