11 research outputs found
A Novel Root-Knot Nematode Resistance QTL on Chromosome Vu01 in Cowpea.
The root-knot nematode (RKN) species Meloidogyne incognita and M. javanica cause substantial root system damage and suppress yield of susceptible cowpea cultivars. The narrow-based genetic resistance conferred by the Rk gene, present in some commercial cultivars, is not effective against Rk-virulent populations found in several cowpea production areas. The dynamics of virulence within RKN populations require a broadening of the genetic base of resistance in elite cowpea cultivars. As part of this goal, F1 and F2 populations from the cross CB46-Null (susceptible) x FN-2-9-04 (resistant) were phenotyped for M. javanica induced root-galling (RG) and egg-mass production (EM) in controlled growth chamber and greenhouse infection assays. In addition, F[Formula: see text] families of the same cross were phenotyped for RG on field sites infested with Rk-avirulent M. incognita and M. javanica The response of F1 to RG and EM indicated that resistance to RKN in FN-2-9-04 is partially dominant, as supported by the degree of dominance in the F2 and F[Formula: see text] populations. Two QTL associated with both RG and EM resistance were detected on chromosomes Vu01 and Vu04. The QTL on Vu01 was most effective against aggressive M. javanica, whereas both QTL were effective against avirulent M. incognita Allelism tests with CB46 x FN-2-9-04 progeny indicated that these parents share the same RKN resistance locus on Vu04, but the strong, broad-based resistance in FN-2-9-04 is conferred by the additive effect of the novel resistance QTL on Vu01. This novel resistance in FN-2-9-04 is an important resource for broadening RKN resistance in elite cowpea cultivars
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The USDA Barley Core Collection: Genetic Diversity, Population Structure, and Potential for Genome-Wide Association Studies
New sources of genetic diversity must be incorporated into plant breeding programs if they are to continue increasing grain
yield and quality, and tolerance to abiotic and biotic stresses. Germplasm collections provide a source of genetic and
phenotypic diversity, but characterization of these resources is required to increase their utility for breeding programs. We
used a barley SNP iSelect platform with 7,842 SNPs to genotype 2,417 barley accessions sampled from the USDA National
Small Grains Collection of 33,176 accessions. Most of the accessions in this core collection are categorized as landraces or
cultivars/breeding lines and were obtained from more than 100 countries. Both STRUCTURE and principal component
analysis identified five major subpopulations within the core collection, mainly differentiated by geographical origin and
spike row number (an inflorescence architecture trait). Different patterns of linkage disequilibrium (LD) were found across
the barley genome and many regions of high LD contained traits involved in domestication and breeding selection. The
genotype data were used to define ‘mini-core’ sets of accessions capturing the majority of the allelic diversity present in the
core collection. These ‘mini-core’ sets can be used for evaluating traits that are difficult or expensive to score. Genome-wide
association studies (GWAS) of ‘hull cover’, ‘spike row number’, and ‘heading date’ demonstrate the utility of the core
collection for locating genetic factors determining important phenotypes. The GWAS results were referenced to a new
barley consensus map containing 5,665 SNPs. Our results demonstrate that GWAS and high-density SNP genotyping are
effective tools for plant breeders interested in accessing genetic diversity in large germplasm collections
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Sequencing of 15 622 gene-bearing BACs clarifies the gene-dense regions of the barley genome
Barley (Hordeum vulgare L.) possesses a large and highly repetitive genome of 5.1 Gb that has hindered the development of a complete sequence. In 2012, the International Barley Sequencing Consortium released a resource integrating whole-genome shotgun sequences with a physical and genetic framework. However, because only 6278 bacterial artificial chromosome (BACs) in the physical map were sequenced, fine structure was limited. To gain access to the gene-containing portion of the barley genome at high resolution, we identified and sequenced 15 622 BACs representing the minimal tiling path of 72 052 physical-mapped gene-bearing BACs. This generated ~1.7 Gb of genomic sequence containing an estimated 2/3 of all Morex barley genes. Exploration of these sequenced BACs revealed that although distal ends of chromosomes contain most of the gene-enriched BACs and are characterized by high recombination rates, there are also gene-dense regions with suppressed recombination. We made use of published map-anchored sequence data from Aegilops tauschii to develop a synteny viewer between barley and the ancestor of the wheat D-genome. Except for some notable inversions, there is a high level of collinearity between the two species. The software HarvEST: Barley provides facile access to BAC sequences and their annotations, along with the barley– Ae. tauschii synteny viewer. These BAC sequences constitute a resource to improve the efficiency of marker development, map-based cloning, and comparative genomics in barley and related crops. Additional knowledge about regions of the barley genome that are gene-dense but low recombination is particularly relevant.Keywords: Aegilops tauschii,
Barley,
centromere BACs,
HarvEST:Barley,
gene distribution,
synteny,
recombination frequency,
Hordeum vulgare L.,
BAC sequencingThis is the publisher’s final pdf. The published article is copyrighted by the author(s) and published by John Wiley & Sons Ltd. on behalf of the Society for Experimental Biology. The published article can be found at: http://onlinelibrary.wiley.com/journal/10.1111/%28ISSN%291365-313X. Supporting information is available online at: http://onlinelibrary.wiley.com/doi/10.1111/tpj.12959/abstrac
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Cuesta-MarcosAlfonsoCropSoilScienceUSDABarleyCore.pdf
New sources of genetic diversity must be incorporated into plant breeding programs if they are to continue increasing grain
yield and quality, and tolerance to abiotic and biotic stresses. Germplasm collections provide a source of genetic and
phenotypic diversity, but characterization of these resources is required to increase their utility for breeding programs. We
used a barley SNP iSelect platform with 7,842 SNPs to genotype 2,417 barley accessions sampled from the USDA National
Small Grains Collection of 33,176 accessions. Most of the accessions in this core collection are categorized as landraces or
cultivars/breeding lines and were obtained from more than 100 countries. Both STRUCTURE and principal component
analysis identified five major subpopulations within the core collection, mainly differentiated by geographical origin and
spike row number (an inflorescence architecture trait). Different patterns of linkage disequilibrium (LD) were found across
the barley genome and many regions of high LD contained traits involved in domestication and breeding selection. The
genotype data were used to define ‘mini-core’ sets of accessions capturing the majority of the allelic diversity present in the
core collection. These ‘mini-core’ sets can be used for evaluating traits that are difficult or expensive to score. Genome-wide
association studies (GWAS) of ‘hull cover’, ‘spike row number’, and ‘heading date’ demonstrate the utility of the core
collection for locating genetic factors determining important phenotypes. The GWAS results were referenced to a new
barley consensus map containing 5,665 SNPs. Our results demonstrate that GWAS and high-density SNP genotyping are
effective tools for plant breeders interested in accessing genetic diversity in large germplasm collections
Recommended from our members
Cuesta-MarcosAlfonsoCropSoilScienceUSDABarleyCore_SupportingInformation.zip
New sources of genetic diversity must be incorporated into plant breeding programs if they are to continue increasing grain
yield and quality, and tolerance to abiotic and biotic stresses. Germplasm collections provide a source of genetic and
phenotypic diversity, but characterization of these resources is required to increase their utility for breeding programs. We
used a barley SNP iSelect platform with 7,842 SNPs to genotype 2,417 barley accessions sampled from the USDA National
Small Grains Collection of 33,176 accessions. Most of the accessions in this core collection are categorized as landraces or
cultivars/breeding lines and were obtained from more than 100 countries. Both STRUCTURE and principal component
analysis identified five major subpopulations within the core collection, mainly differentiated by geographical origin and
spike row number (an inflorescence architecture trait). Different patterns of linkage disequilibrium (LD) were found across
the barley genome and many regions of high LD contained traits involved in domestication and breeding selection. The
genotype data were used to define ‘mini-core’ sets of accessions capturing the majority of the allelic diversity present in the
core collection. These ‘mini-core’ sets can be used for evaluating traits that are difficult or expensive to score. Genome-wide
association studies (GWAS) of ‘hull cover’, ‘spike row number’, and ‘heading date’ demonstrate the utility of the core
collection for locating genetic factors determining important phenotypes. The GWAS results were referenced to a new
barley consensus map containing 5,665 SNPs. Our results demonstrate that GWAS and high-density SNP genotyping are
effective tools for plant breeders interested in accessing genetic diversity in large germplasm collections
Recommended from our members
A receptor-like protein mediates plant immune responses to herbivore-associated molecular patterns
Herbivory is fundamental to the regulation of both global food webs and the extent of agricultural crop losses. Induced plant responses to herbivores promote resistance and often involve the perception of specific herbivore-associated molecular patterns (HAMPs); however, precisely defined receptors and elicitors associated with herbivore recognition remain elusive. Here, we show that a receptor confers signaling and defense outputs in response to a defined HAMP common in caterpillar oral secretions (OS). Staple food crops, including cowpea (Vigna unguiculata) and common bean (Phaseolus vulgaris), specifically respond to OS via recognition of proteolytic fragments of chloroplastic ATP synthase, termed inceptins. Using forward-genetic mapping of inceptin-induced plant responses, we identified a corresponding leucine-rich repeat receptor, termed INR, specific to select legume species and sufficient to confer inceptin-induced responses and enhanced defense against armyworms (Spodoptera exigua) in tobacco. Our results support the role of plant immune receptors in the perception of chewing herbivores and defense
Recommended from our members
A receptor-like protein mediates plant immune responses to herbivore-associated molecular patterns
Herbivory is fundamental to the regulation of both global food webs and the extent of agricultural crop losses. Induced plant responses to herbivores promote resistance and often involve the perception of specific herbivore-associated molecular patterns (HAMPs); however, precisely defined receptors and elicitors associated with herbivore recognition remain elusive. Here, we show that a receptor confers signaling and defense outputs in response to a defined HAMP common in caterpillar oral secretions (OS). Staple food crops, including cowpea (Vigna unguiculata) and common bean (Phaseolus vulgaris), specifically respond to OS via recognition of proteolytic fragments of chloroplastic ATP synthase, termed inceptins. Using forward-genetic mapping of inceptin-induced plant responses, we identified a corresponding leucine-rich repeat receptor, termed INR, specific to select legume species and sufficient to confer inceptin-induced responses and enhanced defense against armyworms (Spodoptera exigua) in tobacco. Our results support the role of plant immune receptors in the perception of chewing herbivores and defense
A receptor-like protein mediates plant immune responses to herbivore-associated molecular patterns
Herbivory is fundamental to the regulation of both global food webs and the extent of agricultural crop losses. Induced plant responses to herbivores promote resistance and often involve the perception of specific herbivore-associated molecular patterns (HAMPs); however, precisely defined receptors and elicitors associated with herbivore recognition remain elusive. Here, we show that a receptor confers signaling and defense outputs in response to a defined HAMP common in caterpillar oral secretions (OS). Staple food crops, including cowpea (Vigna unguiculata) and common bean (Phaseolus vulgaris), specifically respond to OS via recognition of proteolytic fragments of chloroplastic ATP synthase, termed inceptins. Using forward-genetic mapping of inceptin-induced plant responses, we identified a corresponding leucine-rich repeat receptor, termed INR, specific to select legume species and sufficient to confer inceptin-induced responses and enhanced defense against armyworms (Spodoptera exigua) in tobacco. Our results support the role of plant immune receptors in the perception of chewing herbivores and defense