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http://dx.doi.org/10.5808/gi.21031

Chromosome-specific polymorphic SSR markers in tropical eucalypt species using low coverage whole genome sequences: systematic characterization and validation  

Patturaj, Maheswari (Institute of Forest Genetics and Tree Breeding)
Munusamy, Aiswarya (Institute of Forest Genetics and Tree Breeding)
Kannan, Nithishkumar (Institute of Forest Genetics and Tree Breeding)
Kandasamy, Ulaganathan (Centre for Plant Molecular Biology, Osmania University)
Ramasamy, Yasodha (Institute of Forest Genetics and Tree Breeding)
Publication Information
Genomics & Informatics / v.19, no.3, 2021 , pp. 33.1-33.10 More about this Journal
Abstract
Eucalyptus is one of the major plantation species with wide variety of industrial uses. Polymorphic and informative simple sequence repeats (SSRs) have broad range of applications in genetic analysis. In this study, two individuals of Eucalyptus tereticornis (ET217 and ET86), one individual each from E. camaldulensis (EC17) and E. grandis (EG9) were subjected to whole genome resequencing. Low coverage (10×) genome sequencing was used to find polymorphic SSRs between the individuals. Average number of SSR loci identified was 95,513 and the density of SSRs per Mb was from 157.39 in EG9 to 155.08 in EC17. Among all the SSRs detected, the most abundant repeat motifs were di-nucleotide (59.6%-62.5%), followed by tri- (23.7%-27.2%), tetra- (5.2%-5.6%), penta- (5.0%-5.3%), and hexa-nucleotide (2.7%-2.9%). The predominant SSR motif units were AG/CT and AAG/TTC. Computational genome analysis predicted the SSR length variations between the individuals and identified the gene functions of SSR containing sequences. Selected subset of polymorphic markers was validated in a full-sib family of eucalypts. Additionally, genome-wide characterization of single nucleotide polymorphisms, InDels and transcriptional regulators were carried out. These variations will find their utility in genome-wide association studies as well as understanding of molecular mechanisms involved in key economic traits. The genomic resources generated in this study would provide an impetus to integrate genomics in marker-trait associations and breeding of tropical eucalypts.
Keywords
Eucalyptus camaldulensis; E. grandis; E. tereticornis; simple sequence repeats; whole genome resequencing;
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