Informative genomic microsatellite markers for efficient genotyping applications in sugarcane

Parida, Swarup K.; Kalia, Sanjay; Kaul, Sunita; Dalal, Vivek; Hemaprabha, G.; Selvi, A.; Pandit, Awadhesh; Singh, Archana; Gaikwad, Kishor; Sharma, Tilak Raj; Srivastava, Prem S.; Singh, Nagendra; Mohapatra, Trilochan

doi:10.1007/s00122-008-0902-4

Cited by 136 publications

(102 citation statements)

References 31 publications

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“…Microsatellite or SSR markers are particularly suitable for detecting somaclonal variations in micropropagated plants as repeated DNA sequences are known to show increased levels of instability in tissue culture (Parida et al, 2009) [19]. The thirteen primers used in the present study were all informative and generated amplicons for the detection of the genetic fidelity of the progeny.…”

Section: Resultsmentioning

confidence: 99%

Genetic Fidelity Testing Using SSR Marker Assay Confirms Trueness to Type of Micropropagated Coconut (Cocos nucifera L.) Plantlets Derived from Unfertilized Ovaries

Bandupriya¹,

Iroshini²,

Perera³

et al. 2017

TOPSJ

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Section: Resultsmentioning

confidence: 99%

Genetic Fidelity Testing Using SSR Marker Assay Confirms Trueness to Type of Micropropagated Coconut (Cocos nucifera L.) Plantlets Derived from Unfertilized Ovaries

Bandupriya¹,

Iroshini²,

Perera³

et al. 2017

TOPSJ

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“…Genotyping was carried out using a set of 174 polymorphic SSR primers (Table S3) comprising of 43 genomic SSRs (Govindaraj et al 2005;Parida et al 2009), and 131 EST-SSRs (Pinto et al 2004;Oliveira et al 2009;Singh et al 2013). DNA amplification was carried out in a 15 lL reaction volume consisting of 1 9 PCR assay buffer, 200 mM of each dNTPs (Fermentas, USA), 12 ng (1.8 pmol) each of forward and reverse primers (Operon Biotechnologies, GmbH, Germany), 0.5 units of Taq DNA polymerase (Fermentas, USA) and 25 ng genomic DNA using a thermal cycler (MyCycler, Biorad, USA).…”

Section: Genotyping Using Ssr Markersmentioning

confidence: 99%

Identification of marker-trait associations for morphological descriptors and yield component traits in sugarcane

Siraree

Banerjee

Khan

et al. 2016

Physiol Mol Biol Plants

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Ninety two sugarcane varieties from sub-tropical India were subjected to molecular profiling with 174 simple sequence repeat markers and characterized for 23 qualitative (morphological descriptors) and nine quantitative traits that directly or indirectly contribute to yield and juice quality. Using STRUCTURE-based population stratification study and a mixed linear model for marker-trait association (MTA) analysis, a total of 60 MTAs were identified for 22 qualitative traits that were able to explain a significantly higher (up to 40%) proportion of the phenotypic variations compared to all the previous reports of MTA studies in sugarcane. In addition, 21 MTAs stable over the three years of study were also identified for nine quantitative traits that explained 16-37% of the total trait variation. It could be concluded that the qualitative traits that are governed mostly by one or a few genes are more responsive to MTA studies and hence have a better potential to be adopted in marker-assisted breeding programmes in sugarcane. The MTAs identified in this study could also find significant applications in upcoming more stringent IP regime, which may necessitate tracking of specific alleles integrated in breeding programmes.

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“…The characteristics of microsatellite sequences have made them the molecular marker of choice for many types of studies because of their high polymorphism and ability to identify both alleles in diploid organisms and given that they are co-dominant. They are very useful in identifying individuals propagated sexually or vegetatively since it is very improbable that two randomly selected individuals will have exactly the same alleles if several markers are used (Parida et al, 2009;Kalia et al, 2011). These markers have been widely used for the molecular characterization of scion cultivars of Prunus species (Cantini et al, 2001;Dirlewanger et al, 2002;Aranzana et al, 2003a;Struss et al, 2003;Pedersen, 2006;Rojas et al, 2008;Akpinar et al, 2010;Maghuly and Laimer, 2011) and rootstock cultivars (Serrano et al, 2002;Struss et al, 2002;Liu et al, 2007;Turkoglu et al, 2010;Arismendi et al, 2012).…”

Section: Molecular Markersmentioning

confidence: 99%

Breeding rootstocks for Prunus species: Advances in genetic and genomics of peach and cherry as a model

Guajardo¹,

Hinrichsen

Muñoz

2015

Chilean J. Agric. Res.

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Prunus rootstock is an important choice in optimizing productivity of grafted cultivars. Nevertheless, many Prunus rootstocks are notoriously intolerant to hypoxia which is caused by waterlogging and/or heavy soils. There is no available information to help select Prunus rootstocks that are tolerant to stress conditions such as root hypoxia caused by excess moisture. Information from genetic maps has demonstrated a high level of synteny among Prunus species, and this suggests that they all share a similar genomic structure. It should be possible to identify the genetic determinants involved in tolerance to hypoxia and other traits in Prunus rootstocks by applying methods to identify regions of the genome involved in the expression of important traits; these have been developed mainly in peach which is the model species for the genus. Molecular markers that are tightly linked to major genes would be useful in marker-assisted selection (MAS) to optimize new rootstock selection. This article provides insight on the advances in the development of molecular markers, genetic maps, and gene identification in Prunus, mainly in peach; the aim is to provide a general approach for identifying the genetic determinants of hypoxia stress in rootstocks.

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Informative genomic microsatellite markers for efficient genotyping applications in sugarcane

Cited by 136 publications

References 31 publications

Genetic Fidelity Testing Using SSR Marker Assay Confirms Trueness to Type of Micropropagated Coconut (Cocos nucifera L.) Plantlets Derived from Unfertilized Ovaries

Genetic Fidelity Testing Using SSR Marker Assay Confirms Trueness to Type of Micropropagated Coconut (Cocos nucifera L.) Plantlets Derived from Unfertilized Ovaries

Identification of marker-trait associations for morphological descriptors and yield component traits in sugarcane

Breeding rootstocks for Prunus species: Advances in genetic and genomics of peach and cherry as a model

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