A general overview of the T. solium ESTs generated here is presented in Table 1. More detailed analysis of the parasite transcriptome, such as codon usage and G+C content, can be obtained online at the STINGRAY system http://stingray.biowebdb.org/index.cgi?project=TS.

A total of 2,857 clones were sequenced and, after removal of poor quality (Phred<15 and/or less than 100 bp) and less informative sequences (typically rRNA and mtRNA), the remaining 1,520 ORESTES were used for sequence assembly following detailed analysis by the STINGRAY. After assembling, sequences were arranged into distinct sets named 'Cysticerci' and 'Cysticerci PIGS', which are available at STINGRAY.

The 'Cysticerci' project http://stingray.biowebdb.org/index.cgi?project=TS corresponds to the parasite-derived transcriptome and contains a total of 1,180 ESTs clustered in 812 non-redundant sequences (185 clusters + 627 singlets), with an average size of 355 nt, totaling 288,496 nt.

The 'Cysticerci PIGS' dataset http://stingray.biowebdb.org/index.cgi?project=TP was determined on the basis of blast similarity analysis with high scores against genomic sequences of S. scrofa. It is composed of 340 non-redundant singlets with an average size of 390 nt and about 132,000 nt in total. The stringency criterion used here warrants that most of this subset is certainly composed of the host transcripts, which may include transcripts relevant for the host-parasite interaction.

Among the parasite's 812 non-redundant sequences (627 singlets + 185 clusters), 462 yielded significant hits with at least one of the databases used for comparative analysis http://stingray.biowebdb.org/index.cgi?project=TS. From these sequences with significant hits, 204 showed similarity with sequences of parasitic metazoan species, including sequences from the T. solium Genome Project (84), from other Taenia species such as T. saginata (2), T. crassiceps (2), T. asiatica (1), as well from other parasitic cestodes as E. granulosus (7) and E. multilocularis (4). Hits were also found against sequences from platyhelminths such as S. mansoni (88), S. japonicum (11), Clonorchis sinensis (1) and Fasciola hepatica (6). The remaining 263 sequences showed similarity with other metazoan species (see Additional file 2). For 350 sequences no hits were obtained on Blast, InterProScan or HMMER analyses.

After automated and manual annotation of all 812 non-redundant sequences, 191 were validated as coding sequences (CDS) (Table 1), of which 60 were considered hypothetical proteins or hypothetical conserved proteins. The number of ORESTES sequences according to their annotation identifiers is given in Additional file 3. As expected, this dataset enriched for coding sequences and showed a higher G+C content (53%) as compared to the total dataset (49%) (Table 1).

Analysis of the 191 annotated sequences using Gene Ontology (GO) allowed the categorization of 96 sequences, among which 84 were classified according to molecular function, 65 to biological processes and 48 to cellular component, several with multiple categories (Fig. 1). From the 65 sequences with biological processes annotation, the most frequent GO sub-categories were proteins related to cellular processes (40), followed by metabolic processes (10), biological regulation (4) and adhesion (4) (Fig. 2A). Among the GO molecular function sub-categories, binding (34), catalytic activity (24), structural molecule activity (14) and motor activity (7) were the most frequent (Fig. 2B). It is noteworthy that a relevant fraction of the transcripts revealed here appear to be related to structural aspects (such as adhesion, binding or structural molecule activity) that might be involved with the solid constitution of the cysts and their establishment on host tissues (see Additional file 4). A detailed description of each GO sub-category can be found on the annotated database available at the STINGRAY system http://stingray.biowebdb.org/index.cgi?project=TS.

The search for predictive sub-cellular localization of the products related to each annotated CDS was performed using the Wolf-PSORT software 19 and returned 113 hits. Among the 13 sequences with predictions of having extracellular localization with high scores (>25), only seven have a putative function assigned by GO. Among these, three are probably not extracellular ('40S Ribosomal protein S19' [GenBank:EX150987], 'Deoxyribonuclease I' [GenBank:EX151091], and 'Sec61-like protein' [GenBank:EX150487]), two may have extracellular localization ('WD40 repeat' – [GenBank:EX150998] and 'Heat-shock protein' [GenBank:EX151058]), while the 'TolA protein' [GenBank:EX150587] and the 'Cadherin family member (cdh-4)' [GenBank: EX150991] are probably extracellular (see Additional file 5). Considering the Wolf-PSORT limitations in predicting cellular localization based on short sequences such as ESTs and the fact that none of the 113 proteins predicted as extracellular were annotated as antigens, even though most Taenia sp. proteins already reported in the literature have precisely that description, further analysis using full length sequences are necessary to confirm these results.

The search for protein motifs among the parasite sequences was performed by similarity searches using InterProScan and RPSBlast using all databases available on the STINGRAY system and pointed out 64 distinct motifs distributed in 79 non-redundant sequences (see Additional files 6, 7 and 8). Among these, the 'pistil-specific extensin-like protein motif' [GenBank:IPR003882] was observed in 16 sequences, the 'vinculin/alpha-catenin' [GenBank:IPR006077] in 12, the 'glutelin' [GenBank:IPR000480] in six, 'fibronectin type III-like fold' [GenBank:IPR008957] in five and several others with four or less hits. Detailed categorization of the T. solium sequences according to the Eukaryotic Orthologous Groups (KOG) categories is shown on the Additional file 9.

A sensitive search for protein family recognition using multiple alignments was carried out with HMMER software and revealed 92 sequences of our parasite dataset generating at least one hit with the Pfam HMM profiles library. A domain with a still unknown function (DUF1787) was found in 12 sequences, the 'PT-PT repeat' in another nine sequences, the 'Hsp20/alpha crystallin family' (HSP20) and the 'I-set-immunoglobulin' (I-set domains) in four, the 'spectrin repeat' (SPECTRIN) and 'EGF-EGF-like domains' in another three sequences.

Only 117 of the 812 T. solium cysticerci clustered sequences described in the present study revealed similarity with the T. solium Genome Project ESTs available at GenBank. Among these 117 sequences, 107 showed similarity on tblastx and 100 on blastn analysis with ESTs of the T. solium Genome Project, 39 with exclusive hits to the larval stage sequence, 11 with the adult stage and 67 with genes expressed in both life-cycle stages (see Additional file 10).

Except for nine sequences from Taenia sp. or Echinococcus sp., the remaining cestode-related sequences presenting high score (>90) on blast against the T. solium sequences described in this study, were from Mesocestoides corti (heat shock 70 kDa protein) and from Diphyllobothrium dendriticum (actin). Further 36 low-score (<90) hits with the 28S ribosomal RNA from distinct cestode species were observed.

Comparative analysis against E. granulosus sequences from GenBank mainly revealed constitutive genes such as actin, paramyosin and others metabolic enzymes. However, two clusters [GenBank:EX151048, GenBank:EX151014] showed high similarity with genes coding for ERM family proteins (ezrin, radixin, moesin), exclusively with EST from larval stage of T. solium (see Additional files 6 and 8). Some of these proteins were characterized in Echinococcus species and received distinct names such as EM10, EG10, EM4 and antigen II/3, despite their high nucleotide similarity. In E. granulosus and E. multilocularis these antigens are basically found in the germinal layer of brood capsules and in the tegument of protoscolices, associated with larval stage. Gonzales et al. 2007 20, showed that the TEG-Tsag gene of T. saginata is homologous to EM10 and EG10 genes of Echinococcus spp. and 97% identical to its T. solium homologue. However, alignment of this T. solium gene with the two clusters sequences described in the present study [GenBank:EX151048, GenBank:EX151014] clearly showed high sequence variability, despite the conserved blocks. The TEG molecules are characterized by an N-terminal FERM domain and a C-terminal ERM domain which are found in a number of cytoskeletal-associated proteins located at the interface between the plasma membrane and the cytoskeleton and in proteins interacting with lipid membranes. Thus TEG protein may play a role in tegument function and interaction with the host.

A number of transcripts identified here could be of interest for further study (see Additional file 11). At least 30 genes coding for proteins potentially involved in parasite development, including transcriptional factors, component of chromatin remodelling complexes, cell adhesion-related molecules, receptors and other transducing components of signalling pathways have been identified. Moreover, putative orthologues of two proteins possibly associated to invertebrate immunity were identified for the first time in T. solium cysticerci: a 'heat shock 90 kDa protein' [GenBank:EX150676] and an 'anaphylatoxin-like domain protein' [GenBank:EX150322, GenBank:EX150873].

Fifty-one T. solium ORESTES revealed similarity with known antigens, including five previously characterized helminth antigens with potential for development of immunodiagnostic and/or vaccines. These are 'paramyosin' [GenBank:EL745866, GenBank:EL750686, GenBank:EL762552], 'major egg antigen' [GenBank:EL740635, GenBank:EL758824, GenBank:EL760346], 'cathepsin L-like cysteine proteinase' [GenBank:EL742569], 'heat shock 70 kDa protein' [GenBank:EL740975, GenBank:EL740984, GenBank:EL741400, GenBank:EL744008, GenBank:EL744338, GenBank:EL745376, GenBank:EL747548, GenBank:EL747588] and the 'H17g' or 'TEG-Tsol surface antigen' [GenBank:AJ581299], which is highly conserved among T. solium and T. saginata.

Taenia solium cysticerci were collected from a naturally infected, landrace, bred pig (Sus scrofa). The animal was humanely sacrificed and cysticerci, spontaneously detached from abdominal and thoracic muscles were recovered and carefully micro-dissected to remove any tissue fragments that remained attached. Cysts were extensively washed with phosphate-buffered saline and immediately stored at -80°C. The study was previously approved by the Ethics Committee on Animal Research of the Faculty of Animal Science and Food Engineering (FZEA) of Universidade de São Paulo (USP), and was carried out following the institution's guidelines for animal husbandry.

Total RNA was obtained from cysticerci using the Trizol^® (Invitrogen, Carlsbad). Messenger RNA (mRNA) was purified using the μMACs mRNA isolation kit (Miltenyi Biotec, Bergisch Gladbach), following manufacturer's directions, as described 52. mRNA concentration was evaluated by spectrophotometry (U-3010 Hitachi, Tokyo, Japan) and 25 ng mRNA aliquots were frozen for the posterior generation of ORESTES amplification profiles as described 12. Briefly, cDNA was synthesized and amplified with some of the oligonucleotide primers previously used in the S. mansoni transcriptome project 12. Twenty cDNA mini-libraries were constructed using ORESTES and a set of different oligonucleotide primers (see Additional file 12). The amplification profiles were evaluated in ethidium bromide-stained agarose gels, cloned in pGEM-T-Easy plasmids (Promega Corporation, Madison, USA) and used for Escherichia coli (strain DH10β) transformation. Recombinant clones were obtained by selective growth (X-Gal, IPTG and ampicillin), screened by PCR amplification of the insert using primers pGEM-F (5'-ACG CCA AGC TAT TTA GGT GAC ACT ATA-3') and EXCEL-R (5'-GTT GTA AAA CGA CGG CCA GTG AAT-3') and stored as glycerol stocks at -80°C. For sequencing, the bacterial clones were grown in LB medium for 20 hours at 37°C, followed by plasmid DNA extraction by alkaline lysis according to standard protocols 53.

ORESTES sequencing was carried out by two laboratories located at UFSC and USP using the DYEnamic^® ET Dye Terminator kit (GE Healthcare, Fairfield) or ThermoSequenase II dye terminator cycle sequencing kit (Amersham-Pharmacia Biotech) in a MegaBace 1000^® DNA Analysis System (GE Healthcare) and on a ABI PRISM^® 3100 Genetic Analyzer (Applied Biosystems, Foster City), respectively. Briefly, each sequencing reaction used 5 pmol of pGEM-F or EXCEL-R oligonucleotides, and PCR products 54 or plasmid DNA as templates. The labeling conditions were: 95°C/25 sec., 35 cycles of 95°C/15 sec., 50°C/20 sec. and 60°C/90 sec. The products were then precipitated (70% isopropanol), injected at 2 KV for 100 sec. and electrophoresed for 140 min. at 7 KV.

Sequence analysis was performed using the STINGRAY system (System for Integrated Genomic Resources and Analysis), an improved version of the formerly published GARSA system (Genomic Analysis Resources for Sequence Annotation) 55. Briefly, the system workflow initially performs evaluation of the quality of the obtained chromatograms (cut-off Phred ≥ 15) following removal of vector sequences through Phred and Cross-match 5657 and then clustering the sequences using CAP3 58. Following similarity searches performed by Blast (Basic Local Alignment Tool), Psi-Blast (Position-Specific Integrated Blast), RPSBlast (Reverse Position-specific Blast) 59, InterProScan 60 and HMMER (Hidden Markov Models for sequence profile analysis) 61 packages against local pre-formatted databases, blast analysis was also performed using all EST sequences from the T. solium Genome Project and the Sus scrofa genome available at GenBank. After removal of ribosomal RNA (rRNA) sequences, blast analysis against the Sus scrofa genome was used to separate parasite sequences from host sequences, creating two datasets that were evaluated separately. Functional annotation was performed using the Gene Ontology (GO) vocabulary as described by Jones et al. 62 and putative sub-cellular localization of each coding sequence was performed through the Wolf-PSORT program 63. The G+C content of singlets and clusters was estimated by the GeeCee program (EMBOSS – European Molecular Biology Open Software Suite – package) and the tRNA sequences were predicted by tRNAscan-SE 64.

The results were then individually and manually checked during annotation, when sequences were validated as CDS when presenting i) high similarity values (e-value < = e^-15 and similarity>75%) with protein databases (uniprot_swissprot, uniprot_trembl, uniref90, refseq_protein) or with protein sequences from phylogenetically related organisms (Cestoda and/or Trematoda) available on GenBank, ii) the presence of conserved domains as revealed by RPS-Blast against CDD (see Additional file 6), COG (see Additional file 7) and KOG databases (see Additional file 8); iii) the presence of protein domains as revealed by InterProScan and HMMER and iv) annotations on Gene Ontology analysis, when available. T. solium sequences having no protein domain and showing exclusive hits with high similarity values (e-value < = e^-15 and similarity>75%) with 'hypothetical proteins' or 'hypothetical conserved proteins' from GenBank were annotated accordingly.

The T. solium cysticerci annotated transcripts, the host-parasite transcribed sequences, all databases used for comparative analysis as well as the additional material to this work are available online at the STINGRAY system http://stingray.biowebdb.org/index.cgi?project=TS.