- Data Note
- Open Access
SpiroESTdb: a transcriptome database and online tool for sparganum expressed sequences tags
- Dae-Won Kim†1,
- Dong-Wook Kim†2,
- Won Gi Yoo†1,
- Seong-Hyeuk Nam2,
- Myoung-Ro Lee1,
- Hye-Won Yang4,
- Junhyung Park5,
- Kyooyeol Lee5,
- Sanghyun Lee1,
- Shin-Hyeong Cho1,
- Won-Ja Lee1,
- Hong-Seog Park2, 3Email author and
- Jung-Won Ju1Email author
© Park et al; licensee BioMed Central Ltd. 2011
- Received: 1 December 2011
- Accepted: 8 March 2012
- Published: 8 March 2012
Sparganum (plerocercoid of Spirometra erinacei) is a parasite that possesses the remarkable ability to survive by successfully modifying its physiology and morphology to suit various hosts and can be found in various tissues, even the nervous system. However, surprisingly little is known about the molecular function of genes that are expressed during the course of the parasite life cycle. To begin to decipher the molecular processes underlying gene function, we constructed a database of expressed sequence tags (ESTs) generated from sparganum.
SpiroESTdb is a web-based information resource that is built upon the annotation and curation of 5,655 ESTs data. SpiroESTdb provides an integrated platform for expressed sequence data, expression dynamics, functional genes, genetic markers including single nucleotide polymorphisms and tandem repeats, gene ontology and KEGG pathway information. Moreover, SpiroESTdb supports easy access to gene pages, such as (i) curation and query forms, (ii) in silico expression profiling and (iii) BLAST search tools. Comprehensive descriptions of the sparganum content of all sequenced data are available, including summary reports. The contents of SpiroESTdb can be viewed and downloaded from the web (http://pathod.cdc.go.kr/spiroestdb).
This integrative web-based database of sequence data, functional annotations and expression profiling data will serve as a useful tool to help understand and expand the characterization of parasitic infections. It can also be used to identify potential industrial drug targets and vaccine candidate genes.
- Spirometra erinacei
- Expressed sequence tags (ESTs)
Sparganum is the plerocercoid larva of the genus Spirometra erinacei of pseudophyllidean tapeworms. Human sparganosis occurs occasionally through the ingestion of freshwater contaminated with proceroid-infected cyclops or through contact with plerocercoid-infected animal hosts, such as frogs and snakes. Sparganosis is reported in many countries but is most common in eastern Asia . Ingested spargana have the ability to invade various organs, such as the eye, subcutaneous tissues, abdominal wall, brain, spinal cord, lung, breast, and others [2, 3]. Human sparganosis can cause diverse symptoms, such as non-specific irritation, uncertain pain, tissue mass formation, or headache, or it can cause no symptoms that affect the internal organs . Thus, sparganum has become an important parasite for human health, and research into this organism will greatly contribute to the identification and characterization of genes and pathways involved in parasite development and function.
For contemporary functional genomic studies, the significant efforts invested in the creation of integrative transcript databases of expressed sequence tags (ESTs) derived from full-length cDNA libraries have provided opportunities to direct gene discovery and functional analysis. However, in the absence of a fully sequenced genome, parasite transcriptome data have only been analyzed in a limited number of studies [5–8]. Therefore, the motivation for this project was to develop a database and tool that would provide parasite researchers with flexible access to parasite-specific information about sparganum that is relevant for studying the production of parasite proteins and identifying molecules involved in key biological pathways that might serve as targets for diagnostic markers and treatments for the control of sparganum.
Database contents and construction
Summary of sparganum transcriptome
Total sequence reads
Total analyzed reads
Total assembled sequences (average size)
1,787 (725 bp)
910 (787 bp)
877 (661 bp)
Total annotated genes (non-redundant set)*
SpiroESTdb architecture and web interface
General features of SpiroESTdb components and tools
The online database of SpiroESTdb also provides comprehensive information on the ESTs through the "Annotation" section, which consists of 11 categories including Statistics, Annotation Report, BLASTN, BLASTX, TBLASTX, Uniprot, KEGG, InterPro, GO, SNP and TRF. In particular, in the case of the Statistics page, users can see all of the detailed functional annotation information describing how the unigenes were annotated and taxonomically distributed in the system (Figure 2d). Each category using the BLAST algorithm  allows users access to annotation information including unigene IDs and sequence information, annotated unique identifiers, sequence lengths, description, aligned start and end positions, matched similarity, and significant scores that were assigned by the prediction algorithms. SpiroESTdb allows users to view detailed alignment information by clicking on the description of each unigene (Figure 2e). InterProScan  is a predictive model for identifying protein domains, families and functional sites using diverse source databases. The InterPro category provides comprehensive information about the functional domains present in previously unidentified genes via a homology search. The potential assignment ID results are integrated into the GO category. As additional data, we also list single nucleotide polymorphisms in the SNP category and copy number variants in the TRF category.
Specific search function
Existing information can be retrieved for any unigene using full-text matching (against the read id, consensus id, gene name, gene accession number and functional description) in the "Annotation" page. With a gene or protein, users are able to blast a query sequence against raw read data, contigs and singletons, via the "Run BLAST" page, to find and visualize potential homologous matches.
Personalized curation service and "Electronic Northern"
For some genes that have not previously been studied, the best hits identified using a homology search will provide ambiguous annotation descriptions such as "predicted protein" or "hypothetical protein". To increase the quality of the BLAST results and to offer biologically meaningful information, SpiroESTdb supports a user-friendly curation service that allows experts to manually edit functional annotations based on an experimental or heuristic approach. In addition, we programmed the "Electronic Northern" module to detect differential expression between different libraries and/or among unigenes within the same library by comparing accession IDs from BLAST results (Figure 2f).
Practical examples using SpiroESTdb
Further development of the database will involve updating the experimental records for verified sparganum (plerocercoid of Spirometra erinacei) genes with additional functional annotations, such as information about drug targets and vaccine candidates, maps of KEGG pathways and host-pathogen interaction information. Comparative genomes will also be integrated into SpiroESTdb to facilitate the production of large scale synteny maps and their associated genomic information. This database is available on the Web for all users upon registration and provides a large amount of information on potential industrial drug targets and vaccine candidates that can be used in virtual screening initiatives and molecular docking.
SpiroESTdb is open access and freely available. The curation service requires free user registration because each user needs a unique session. All questions, comments and requests should be sent by email to email@example.com.
Project name: SpiroESTdb
Project home page: http://pathod.cdc.go.kr/spiroestdb
Operating system: Linux
Other requirements: None
License: None required
This work was supported by grant 2009-0084206 from the Ministry of Education, Science and Technology, Korea and grant 2006-N54002-00 from the Korean National Institute of Health. The contribution of the staff at the Genome Research Center of KRIBB in Korea is gratefully acknowledged.
The authors thank the pathogen research community at the Korea National Institutes of Health for valuable input on this project and suggestions for building and maintaining this database.
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