Molecular Breeding for Ascochyta Blight Resistance in Lentil: Current Progress and Future Directions

Rodda, Matthew; Davidson, J. A.; Javid, Muhammad; Sudheesh, Shimna; Blake, Sara N.; Forster, John W.; Kaur, Sukhjiwan

doi:10.3389/fpls.2017.01136

Cited by 23 publications

(13 citation statements)

References 81 publications

(150 reference statements)

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“…Several genetic linkage maps have previously been used to identify QTLs for Ascochyta blight resistance in lentil (reviewed by Rodda et al [89]), with magnitudes varying from 3% to 89% of the phenotypic variance evidenced. Common QTL locations between different studies are difficult to establish because of the differing nomenclature for linkage groups and the lack of common marker loci between the genetic maps.…”

Section: Discussionmentioning

confidence: 99%

“…Common QTL locations between different studies are difficult to establish because of the differing nomenclature for linkage groups and the lack of common marker loci between the genetic maps. In spite of that, the QTL named AB_NF1 on LG6 in the study of Sudheesh et al [67] is comparable in position to QTL5 on LG1 of Rubeena et al [85] and QTL1 on LG1 of Gupta et al [49], based on a common SSR locus location [89]. The AB_NF1 QTL accounted for 7% of the phenotypic variation in an F 6 RIL population from a cross of Indianhead x Northfield, being Northfield (ILL5588) a common parent in the majority of the studies published.…”

Section: Discussionmentioning

confidence: 99%

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Construction of a high-density interspecific (Lens culinaris x L. odemensis) genetic map based on functional markers for mapping morphological and agronomical traits, and QTLs affecting resistance to Ascochyta in lentil

et al. 2019

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Usage of high-throughput sequencing approaches allow for the generation and characterization of reference transcriptome datasets that support gene-based marker discovery, which in turn can be used to build genetic maps among other purposes. We have obtained a transcriptome assembly including 49,453 genes for the lentil ( Lens culinaris Medik.) cultivar Alpo using RNAseq methodology. This transcriptome was used as reference to obtain 6,306 quality polymorphic markers (SNPs and short indels) analyzing genotype data from a RIL population at F 7 generation derived from the interspecific cross between L . culinaris cv. Alpo and L . odemensis accession ILWL235. L . odemensis is a wild species included in the secondary gene pool and can be used as a source for gene introgression in lentil breeding programs. Marker data were used to construct the first genetic interspecific map between these two species. This linkage map has been used to precisely identify regions of the CDC-Redberry lentil draft genome in which the candidate genes for some qualitative traits (seed coat spotting pattern, flower color, and stem pigmentation) could be located. The genome regions corresponding to a significant single quantitative trait locus (QTL) controlling “time to flowering” located in chromosome 6 and three QTLs regulating seed size and positioned in chromosomes 1 and 5 (two QTLs) were also identified. Significant QTLs for Ascochyta blight resistance in lentil were mapped to chromosome 6 in the genome region or close to it where QTLs for Ascochyta blight resistance have previously been reported.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Construction of a high-density interspecific (Lens culinaris x L. odemensis) genetic map based on functional markers for mapping morphological and agronomical traits, and QTLs affecting resistance to Ascochyta in lentil

et al. 2019

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“…For example, both Indianhead and Northfield (syn. ILL5588, Nei's coefficient value 0.69194), known to be resistant to Ascochyta Blight (Rodda et al, 2017), have been crossed to each other to produce improved levels of disease resistance in the breeding germplasm (Rodda et al, 2017). The information generated in the current study provides a database for breeders to select Lens accessions for future crossing strategies in order to introgress novel alleles.…”

Section: Assessment Of Genetic Diversity and Population Structure In mentioning

confidence: 99%

Characterization of Genetic and Allelic Diversity Amongst Cultivated and Wild Lentil Accessions for Germplasm Enhancement

et al. 2020

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Intensive breeding of cultivated lentil has resulted in a relatively narrow genetic base, which limits the options to increase crop productivity through selection. Assessment of genetic diversity in the wild gene pool of lentil, as well as characterization of useful and novel alleles/genes that can be introgressed into elite germplasm, presents new opportunities and pathways for germplasm enhancement, followed by successful crop improvement. In the current study, a lentil collection consisting of 467 wild and cultivated accessions that originated from 10 diverse geographical regions was assessed, to understand genetic relationships among different lentil species/subspecies. A total of 422,101 high-confidence SNP markers were identified against the reference lentil genome (cv. CDC Redberry). Phylogenetic analysis clustered the germplasm collection into four groups, namely, Lens culinaris/Lens orientalis, Lens lamottei/Lens odemensis, Lens ervoides, and Lens nigricans. A weak correlation was observed between geographical origin and genetic relationship, except for some accessions of L. culinaris and L. ervoides. Genetic distance matrices revealed a comparable level of variation within the gene pools of L. culinaris (Nei's coefficient 0.01468-0.71163), L. ervoides (Nei's coefficient 0.01807-0.71877), and L. nigricans (Nei's coefficient 0.02188-1.2219). In order to understand any genic differences at species/subspecies level, allele frequencies were calculated from a subset of 263 lentil accessions. Among all cultivated and wild lentil species, L. nigricans exhibited the greatest allelic differentiation across the genome compared to all other species/subspecies. Major differences were observed on six genomic regions with the largest being on Chromosome 1 (c. 1 Mbp). These results indicate that L. nigricans is the most distantly related to L. culinaris and additional structural variations are likely to be identified from genome sequencing studies. This would provide further insights into evolutionary relationships between cultivated and wild lentil germplasm, for germplasm improvement and introgression.

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“…Using RIL populations, QTLs for stemphylium blight and rust resistance (Saha, Sarker, Chen, Vandemark, & Muehlbauer, 2010a, 2010b) and seedling and pod stage ascochyta blight resistance (each of three QTLs, accounted for 34% and 61% of the total estimated phenotypic variation (Gupta, Taylor, et al, 2012) were identified. Nevertheless, identified flanking markers have potential to be used in MAS especially for disease-resistance genes with single gene inheritance or codominance (Chowdhury, Andrahennadi, Slinkard, & Vandenberg, 2001;Eujayl et al, 1998;Ford, Pang, & Taylor, 1999;Kaur et al, 2014;Rodda et al, 2017;Rubena, Taylor, Ades, & Ford, 2006;Tullu et al, 2003). However, validation of these linked markers would remain important challenge for the success of adoption of such markers in lentil improvement programme.…”

Section: Qtl Mapping and Mas In Breeding Programmesmentioning

confidence: 99%

“…These AB-resistant markers were evaluated on a diverse lentil panel, which had nearly 86% accuracy for phenotypic response to be potentially adopted in lentil breeding programmes. Ascochyta blight-resistant genes have been identified through lentil genomics and integrated genetic linkage map, EST libraries and draft genome sequences have been generated (Rodda et al, 2017). Among few attempts to dissect genes of interest from wild genotypes using mapping and QTL analysis, a linkage map of 94 RILs from a cross between two L. ervoides genotypes has been developed (Bhadauria, Ramsay, Bett, & Banniza, 2017 34 countries with a wide range of variation for zinc (Zn) and iron (Fe) concentration in seeds were used, and two SNP markers tightly linked to Fe and one linked to Zn concentration were identified using marker-trait association analysis (Khazaei et al, 2017).…”

Section: Qtl Mapping and Mas In Breeding Programmesmentioning

confidence: 99%

Widening the genetic base of cultivated gene pool following introgression from wild Lens taxa

et al. 2018

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Wild Lens taxa are a reservoir of useful rare genes/alleles for widening the genetic base and synthesis of a new gene pool of lentil. To maximize and sustain lentil production, new gene sources are needed to be identified and incorporated into cultivated background. This needs a comprehensive approach to accumulate favourable alleles from distantly related germplasm for widening of the cultivated gene pool and would be the most appropriate strategy to solve the various problems associated with stressed crop production and plateaued yields. Furthermore, expansion of deeper understanding of lentil genomics along with extensive research undertaken in other crop species can provide suitable guidelines to cover the distribution of Lens genus and component gene pools for further remarkable progress in lentil genetic improvement. This review aims at the genus Lens distribution and gene pools, crop germplasm conserved in ex‐situ and in‐situ collection, wild species characterization and evaluation for useful traits of interest to solve production‐related problems, highlight useful gene sources present in different gene pools and the progress achieved for widening the genetic base of cultivated varieties of lentil through wide hybridization and exploring lentil genomics.

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Molecular Breeding for Ascochyta Blight Resistance in Lentil: Current Progress and Future Directions

Cited by 23 publications

References 81 publications

Construction of a high-density interspecific (Lens culinaris x L. odemensis) genetic map based on functional markers for mapping morphological and agronomical traits, and QTLs affecting resistance to Ascochyta in lentil

Construction of a high-density interspecific (Lens culinaris x L. odemensis) genetic map based on functional markers for mapping morphological and agronomical traits, and QTLs affecting resistance to Ascochyta in lentil

Characterization of Genetic and Allelic Diversity Amongst Cultivated and Wild Lentil Accessions for Germplasm Enhancement

Widening the genetic base of cultivated gene pool following introgression from wild Lens taxa

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