Population structure, genetic diversity and bakanae disease resistance among rice varieties

Abstract Availability of resistance sources among cultivated varieties helps in easy utilization as donor owing to no deleterious linkage drag. In the present investigation, 121 rice varieties were screened for their resistance against a virulent isolate of Fusarium fujikuroi (Ff-10) and genotyped u...

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Published inPlant genetic resources: characterization and utilization Vol. 20; no. 5; pp. 319 - 327
Main Authors Raghu, S., Baite, M. S., Yadav, M. K., Prabhukarthikeyan, S. R., Keerthana, U., Anil Kumar, C., Jeevan, B., Lenka, S., Subudhi, H. N., Rath, P. C.
Format Journal Article
LanguageEnglish
Published Cambridge Cambridge University Press 01.10.2022
Subjects
Acids
Blight
Chromosomes
Cluster analysis
Crop diseases
Disease resistance
Flowers & plants
Fungicides
Fusarium fujikuroi
Genes
Genetic diversity
Genetic markers
Genotypes
Microsatellites
Pathogens
Pesticides
Phenotypic variations
Population genetics
Population structure
Populations
Rice
Seeds
Structural analysis
Variance analysis
India
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Summary:Abstract Availability of resistance sources among cultivated varieties helps in easy utilization as donor owing to no deleterious linkage drag. In the present investigation, 121 rice varieties were screened for their resistance against a virulent isolate of Fusarium fujikuroi (Ff-10) and genotyped using reported microsatellite markers. Among 121 varieties, only eight varieties, namely Luna Sankhi, Improved Tapaswini, Sarasa, Sadabahar, CR-311, Kshira, Wifa-10 and Binadhan-8, were found to be highly resistant (HR), seven varieties were resistant (R), 31 were moderately resistant (MR), 10 were moderately susceptible (MS), 11 were susceptible (S) and the rest 54 were highly susceptible (HS). The allele diversity of molecular markers classified the population into three clusters. The highly resistant varieties were grouped in major clusters II and III, whereas the remaining genotypes were distributed in all three clusters. Analysis of molecular variance (AMOVA) resulted in 95% of the maximum diversity within the test population and 5% diversity between populations. Population structure analysis grouped the genotypes into two sub-populations based on relatedness, where most of the resistant genotypes were grouped into one sub-population and other genotypes were distributed among sub-populations. Re-examination of reported markers' trait associations with bakanae resistance in the experimental population identified marker RM-3698 as associated with resistance accounting 8.4% explained phenotypic variation. This study shows that simple sequence repeat markers can be used to assess allelic diversity and population structure of bakanae resistance in rice varieties. The highly resistant genotypes, along with resistance markers, could be used as donors in marker-assisted bakanae improvement breeding programmes.
ISSN:1479-2621
1479-263X
DOI:10.1017/S1479262123000199