Genetic Diversity Revealed by Single Nucleotide  Polymorphism Markers in a Worldwide Germplasm  Collection of Durum Wheat

Ren, Jing; Sun, Daokun; Chen, Liang; You, Frank M.; Wang, Jirui; Peng, Yunliang; Nevo, Eviatar; Sun, Dongfa; Luo, Ming‐Cheng; Peng, Junhua

doi:10.3390/ijms14047061

Cited by 92 publications

(101 citation statements)

References 69 publications

(87 reference statements)

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“…Similarly, cotton and other plants high-resolution genetic linkage map and gene tagging have used SNP in their evaluation (Cho et al 2011;Mammadov et al 2012;Li et al 2014). Massive availabilities of SNP markers open the possibility of tagging genes controlling important agronomic characters and supporting breeding programs (Ren et al 2013). The frequency of SNP occurrences in the plant genome is as many as one SNP for every 31 base pair (bp) up to every 124 bp of plant genome (Eulgem et al 2000;Ching et al 2002;Zhang and Wang 2005;Fang et al 2014).…”

Section: Introductionmentioning

confidence: 99%

Development of SNAP markers based on nucleotide variability of WRKY genes in coconut and their validation using multiplex PCR

et al. 2017

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Abstract. Pesik A, Efendi D, Novarianto H, Dinarti D, Sudarsono S. 2017. Development of SNAP markers based on nucleotide variability of WRKY genes in coconut and their validation using multiplex . Development of molecular markers benefits coconut breeding program. The availability of DNA sequences for coconuts opens the new possibility of developing molecular markers such as single nucleotide amplified polymorphism (SNAP). The study aimed to evaluate nucleotide sequence diversities of WRKY gene in the GenBank database, design gene specific primers for generating WRKY gene specific SNAP markers, optimize multiplex PCR technique and validate SNAP marker effectiveness for evaluating Kopyor coconut germplasm. Based on 35 sequences data of coconut WRKY genes that are available in the GenBank database, we have identified eight informative SNPs and used them to generate SNP-specific primers. We have designed sixteen primer pairs and validated them using singleplex PCR. Subsequently, we optimized the Ta and primer concentrations either for duplex or triplex PCR. Duplex PCR using two sets of primer pairs was more reliable for genotyping Kopyor coconut germplasm than triplex PCR. We have successfully demonstrated the duplex PCR for genotyping Banten Tall, Jember Tall, Kalianda Tall, Pati Dwarf and Sumenep Tall Kopyor coconuts. Therefore, one may use the developed SNAP markers as a simple alternative of co-dominant markers for genetic analysis of coconuts. One may use the developed SNAP markers to investigate the possible association between markers and Kopyor endosperm and other relevant phenotypes in coconuts.

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Section: Introductionmentioning

confidence: 99%

Development of SNAP markers based on nucleotide variability of WRKY genes in coconut and their validation using multiplex PCR

et al. 2017

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“…(4) SSRs are more easily scorable than most morphological features, (5) SSR detection is highly reproducible and can reveal intraspecific homology. (6) The abundance of SSRs enhances the likelihood of linkage to specific agronomic traits; for instance, SSR results revealed large genetic distances between certain landraces of rice, thus evaluation of genetic diversity and genetic structure in crops has important implications for plant breeding programs and the conservation of genetic resources (Ren et al, 2013). The result of cluster analysis revealed that there was to significant correlation between the aromatic feature and genetic similarity.…”

Section: Discussionmentioning

confidence: 82%

“…Newly developed single nucleotide polymorphism (SNP) markers are effective in detecting genetic diversity (Ren et al, 2013). SSR and single nucleotide polymorphic (SNP), the two most robust markers for identifying rice varieties were compared for assessment of genetic diversity and population structure (Singh et al, 2013).…”

Section: Author(s) Agree That This Article Remain Permanently Open Acmentioning

confidence: 99%

Genetic diversity of rice from Iran region assessed by simple sequence repeat (SSR) markers

Vazirzanjani¹,

Kawai²,

Korrani³

et al. 2017

Afr. J. Agric. Res.

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Simple sequence repeat (SSR) markers (36 microsatellite pairs) were used to assess genetic diversity among sixteen rice (Oriza sativa L.) cultivars from Iran, four from Uzbekistan, and one from Afghanistan, and to compare this diversity with that of three control cultivars including Nipponbare, Jasmine 85 and Basmati 370. Among the 36 microsatellite pairs, 31 produced polymorphisms ranging from 1 to 7 alleles (average = 3.72 per microsatellite). There were 134 alleles detected using all the SSR primers, 103 of which (76.9%) showed polymorphisms, while 31 did not. The genetic similarity coefficient among the 24 rice cultivars was 0.601. The genetic diversity revealed by this survey will be useful to designate the most appropriate parental cv. to initiate a breeding program aimed at developing new rice varieties with traits adapted for Middle Eastern agriculture.

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“…Newly developed single nucleotide polymorphism (SNP) markers are effective in detecting genetic diversity (Ren et al 2013), but in some cases larger number of markers need to be used due to large genome of wheat. If no pedigree information is available the breeder may use the molecular marker data for selecting the parents/lines for crossing.…”

Section: Discussionmentioning

confidence: 99%

“…To date, a variety of molecular techniques have been in usage in wheat such as restriction fragment length polymorphisms (RFLP), random polymorphic amplified DNA (RAPD) and amplified frag-ment length polymorphisms (AFLP), which have been used successfully for genetic mapping, phylogenetic relationships, comparative genomic studies, and genetic diversity evaluation. However, none of them have been used extensively in breeding programs because they do not meet the requirements for efficient application in marker assisted selection (MAS) (Ren et al 2013).…”

Section: Introductionmentioning

confidence: 99%

Assessing genetic diversity of wheat genotypes from different origins by SNP markers

Španić¹,

Korzun²,

Ebmeyer³

2016

Cereal Research Communications

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Genetic diversity was investigated in a set of eleven hexaploid wheat genotypes originated from CIMMYT, Turkey in comparison with some modern European mostly originated from KWS wheat breeding program using 24 wheat SNP markers. The lowest and highest genetic dissimilarities were observed between genotypes Opus and LDO 330/06, KWS Salix and LDO 330/06, respectively. Based on cluster analysis, 38 wheat genotypes were grouped in two main clusters. Although the grouping pattern is very origin heterogeneous in each group, the grouping pattern of some genotypes appeared to be associated, to some extent. Principal coordinate analysis (PCoA) was used as an alternative way of visualizing the genotypic data. The first, second and third principal components explained 17.79%, 14.39% and 12.24% of the variation, respectively. This study can also be an indicator for breeders to evolve genotypes with diverse genetic background to achieve sustainability in wheat production, to get favorable heterotic combinations in a wheat improvement program.

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Genetic Diversity Revealed by Single Nucleotide Polymorphism Markers in a Worldwide Germplasm Collection of Durum Wheat

Cited by 92 publications

References 69 publications

Development of SNAP markers based on nucleotide variability of WRKY genes in coconut and their validation using multiplex PCR

Development of SNAP markers based on nucleotide variability of WRKY genes in coconut and their validation using multiplex PCR

Genetic diversity of rice from Iran region assessed by simple sequence repeat (SSR) markers

Assessing genetic diversity of wheat genotypes from different origins by SNP markers

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