Development of EST-SSR markers for genetic diversity analysis in coconut (Cocos nucifera L.).

Genetic improvement in coconut relies on exploiting the vast existing diversity among coconut accessions. Robust molecular markers are a pre-requisite for efficient characterization of genetic diversity. Microsatellites or simple sequence repeats (SSRs), mined from expressed sequence tags (ESTs), constitute an important resource for analysis of genetic diversity as they are abundant, polymorphic and represent function regions of the genome. We have identified a total of 318,528 putative EST-SSRs from 130,942 unigenes utilizing a leaf transcriptome dataset of coconut. Among the EST-SSRs, dinucleotide repeats were abundant (219,912; 69.04%) followed by trinucleotide (70,722; 22.2%) and tetra-nucleotide repeats (6281; 1.9%). Among the dinucleotide repeat motifs, the dominant repeat was AG/CT (35.87%), followed by AT/AT (18.59%), while the dominant trinucleotide repeat was AAG/CTT (4.59%). One hundred and twenty EST-SSR primer pairs were designed and utilized to amplify six DNA samples of coconut accessions. Fifty primers (41.7%) produced reproducible polymorphic fragments of expected sizes, from which a total of 10 primers were selected for the diversity assessment in 186 palms of 50 coconut accessions, comprising of 25 each of tall and dwarf accessions. A total of 137 alleles were detected with an average of 13.7 alleles per SSR locus. The number of alleles observed at each locus in the data set ranged from 7 to 22. All the loci showed 100% polymorphism with respect to the samples screened. The average observed heterozygosity was 0.46. The PIC values ranged from 0.79 (CnKGDEST129 and CnKGDEST100) to 0.91 (CnKGDEST117 and CnKGDEST122) with a mean value of 0.85, indicating the capacity of the EST-SSR markers to detect high levels of polymorphism. The cluster analysis revealed that accessions were generally clustered based on their relative similarity and irrespective of their geographic origins. The present study demonstrates the usefulness of transcriptome sequencing as a rapid and cost-effective methodology for the development of molecular markers. The EST-SSR markers generated through this study constitute useful and reliable tools for assessment of genetic diversity and marker-assisted selection in coconut.

Dataset of transcriptome assembly of date palm embryogenic calli and functional annotation.

Date palm (Phoenix dactylifera L.; 2n = 36; Arecaceae), cultivated in tropical and sub-tropical regions worldwide, is a staple food for people in the Middle East region and has economic value throughout the world. Tissue culture is considered as a feasible technique for the large-scale multiplication of elite date palm varieties. In this article, we report the transcriptome assembly from the embryogenic calli of Khalas variety of date palm. A total of 50,852,331 paired-end (PE) raw reads were acquired using an Illumina sequencing platform. Reference-based assembly, with date palm genome, resulted in 53251 transcripts. A total of 63888 Gene Ontology (GO) terms could be annotated from the assembled transcriptome. Also, transcription factor families and small RNAs were annotated from the assembled transcriptome. Results of the pathway analysis revealed that a total of 2584 transcripts were involved in various metabolic pathways. Transcripts with possible roles in somatic embryogenesis were also identified. The dataset provides insights into the expression pattern of various genes during early somatic embryogenesis in date palm.

De novo assembly and characterization of global transcriptome of coconut palm (Cocos nucifera L.) embryogenic calli using Illumina paired-end sequencing.

Production and supply of quality planting material is significant to coconut cultivation but is one of the major constraints in coconut productivity. Rapid multiplication of coconut through in vitro techniques, therefore, is of paramount importance. Although somatic embryogenesis in coconut is a promising technique that will allow for the mass production of high quality palms, coconut is highly recalcitrant to in vitro culture. In order to overcome the bottlenecks in coconut somatic embryogenesis and to develop a repeatable protocol, it is imperative to understand, identify, and characterize molecular events involved in coconut somatic embryogenesis pathway. Transcriptome analysis (RNA-Seq) of coconut embryogenic calli, derived from plumular explants of West Coast Tall cultivar, was undertaken on an Illumina HiSeq 2000 platform. After de novo transcriptome assembly and functional annotation, we have obtained 40,367 transcripts which showed significant BLASTx matches with similarity greater than 40 % and E value of ≤10(-5). Fourteen genes known to be involved in somatic embryogenesis were identified. Quantitative real-time PCR (qRT-PCR) analyses of these 14 genes were carried in six developmental stages. The result showed that CLV was upregulated in the initial stage of callogenesis. Transcripts GLP, GST, PKL, WUS, and WRKY were expressed more in somatic embryo stage. The expression of SERK, MAPK, AP2, SAUR, ECP, AGP, LEA, and ANT were higher in the embryogenic callus stage compared to initial culture and somatic embryo stages. This study provides the first insights into the gene expression patterns during somatic embryogenesis in coconut.