Expressed Sequence Tags of Trichinella spiralis Muscle Stage Larvae

Article information

Korean J Parasito. 2008;46(2):59-63

Publication date (electronic) : 2008 June 20

doi : https://doi.org/10.3347/kjp.2008.46.2.59

Hae Kyung Park ¹^,³, Seong Won Chang ², Se Won Kang ⁴, Min Kyoung Cho ², Sun Hee Choi ², Yeon Chul Hong ⁵, Yong Seok Lee ⁴, Hae Jin Jeong ²^,³, Hak Sun Yu ²^,³

¹Department of Internal Medicine, School of Medicine, Pusan National University, Busan 609-735, Korea.

²Department of Parasitology, School of Medicine, Pusan National University, Busan 609-735, Korea.

³Pusan National University Hospital Medical Research Institute, Busan 602-739, Korea.

⁴Department of Parasitology and Malariology, PICR, College of Medicine and Frontier Inje Research for Science and Technology, Inje University, Busan 614-735, Korea.

⁵Department of Parasitology, School of Medicine, Kyungpook National University, Daegu 700-422, Korea.

Corresponding author (hsyu@pusan.ac.kr)

Received 2008 February 02; Accepted 2008 May 20.

Abstract

In order to obtain greater insight into the relevant genomic expression patterns of Trichinella spiralis, 992 expressed sequence tags (ESTs) were collected from a cDNA library of T. spiralis muscle stage larvae and assembled into 60 clusters and 385 singletons. Of them, 445 (44.7%) ESTs were annotated to their homologous genes, and small fractions were matched to known genes of nematodes. The annotated ESTs were classified into 25 eukaryotic orthologous groups (KOG). Cytochrome C oxidase (34 clones) was found to be most frequent species.

Keywords: Trichinella spiralis; Expressed sequence tags; muscle stage larva; eukaryotic orthologous groups (KOG)

INTRODUCTION

Genus Trichinella, which consists of several species, is found to infect mammals, birds, and reptiles. These nematodes alternate enteric and skeletal muscle stages during their life cycle. T. spiralis is a relatively small nematode, adult female being 1.4-4.0 mm, adult male 1.4-1.8 mm, and muscle stage larvae approximately 1 mm long [1,2]. The life cycle of this nematode begins with the enteral phase of infection, when a person or an animal eats contaminated meat containing first-stage muscle larvae. Digestive juices from the stomach (pepsin and hydrochloric acid) dissolve the capsule-like cyst and release the larvae, penetrating into epithelial cells of the small intestine [3]. Shortly thereafter, the larvae molt 4 times (10 through 28 hr post-oral ingestion [POI]), and mature into adults that mate (30-34 hr POI). Female worms can produce 500-1,500 newborn larvae (immature L1) during a lifespan, prior to expulsion by the host immune system. The migratory phase of infection begins when these newborn larvae are passed into tissues, enter the lymphatic system, and then enter the general circulation at the thoracic duct. These larvae are distributed widely throughout tissues by circulation, and eventually make their way through blood capillaries into muscle fibers, so initiating the muscle phase of infection. Once in muscle fibers, they encyst, undergo development, become infective within 15 days, and remain for months to years.

Trichinella spiralis evidences several biological differences that include host specificity, phenotypic characteristics induced in infected host cells, and interactions with the host immune system. Additionally, each of these parasites must migrate extracellularly through the tissues of the host in order to infect the various host cells they inhabit [4]. The mechanisms involved in this migration remain to be elucidated. Furthermore, the role of the parasite in regulating changes in these host cells remains unknown. A number of technical obstacles exist which impede progress in many of these issues, including a paucity of information regarding the genes that comprise Trichinella spp [5,6].

Reverse-genetic and/or post-genomic approaches predicated on nucleotide sequence information are vital for such investigations [7,8]. However, the availability of sequence information required for such approaches remains insufficient. Expressed sequence tags (ESTs) analysis enables the collection of nucleotide sequence information regarding protein-coding regions in a rapid and efficient manner, and should be helpful in detecting and identifying genes in genomes. It also provides gene expression information for a particular type of cultivation or for a particular growth phase. For these reasons, EST analysis is conducted as a component of many genome projects [9-11]. In addition to the genes that are candidates for pathogenic factors, many novel genes for stage-specific or cell cycle regulation, in addition to a great many cell signaling-associated genes, have been identified in these parasites via EST analysis [12-14].

ESTs analysis and the single-pass sequencing of randomly selected cDNA clones have been used to characterize the transcribed genes of a variety of organisms, including parasitic nematodes, such as Brugia malayi [15], Toxocara canis [12], Strongyloides ratti [16], and Anisakis simplex [17]. Recently, some ESTs were analyzed using a new database, referred to as eukaryotic Orthologous Groups (KOG) [18,19]. In order to gain greater insight into the relevant genomic expression patterns, we generated the ESTs of T. spiralis third-stage larva and investigated their functions using KOG database analysis. The characterization of the EST data is expected to provide valuable insights into both the metabolism and the pathogenicity of this parasite.

MATERIALS AND METHODS

Trichinella spiralis strain maintenance and isolation

Trichinella spiralis was kindly provided from Dr. Lee of Korea University, and maintained and recovered as described previously [20]. Albino rats (SD strain) were infected with 5,000 larvae and sacrificed 2 mo after infection.

Preparation of total RNA

Approximately 50,000 muscle stage larvae of T. spiralis were homogenized using a tissue homogenizer. Total RNA was extracted from homogenized tissue solution using Trizol reagent, according to the manufacturer's protocols (Invitrogen Life Technologies Inc., Carlsbad, California, USA). After lysing the larvae with 10 ml of Trizol reagent, 1/5 volume of chloroform was added and the sample was vigorously mixed. Aqueous layer was collected by centrifugation at 12,000 rpm for 15 min at 4℃. Total RNA was precipitated with an equal volume of isopropanol. The precipitated pellet was washed with ice-cold 75% ethanol and airdried. The pellet was dissolved in DEPC-treated water and incubated for 10 min at 55℃. The quantity and quality of the RNA was assessed by measuring absorbance at 260 nm and 280 nm with a spectrophotometer. To assess prepared RNA quality, 3 µg of total RNA was run in 1% denaturing formaldehyde agarose gel.

Construction of cDNA library

With 5 µg mRNA purified with mRNA isolation kit (QIAGEN, Hilden, Germany) from the 1 mg total RNA, a cDNA library was constructed in Uni-ZAP™ XR expression vector according to the manufacturer's instructions (Stratagene, La Jolla, California, USA).

Sequencing and analysis of ESTs

The chromatogram files obtained from the sequencer were initially submitted to Phred [21,22] for base calling and quality assignment. The trace files were trimmed with trim-alt 0.05 (Phred score ≥ 20). Each vector sequence was identified and trimmed off using cross-match software (http://www.phrap.org). EST sequences shorter than 100 bp were discarded. The EST sequences were assembled and clustered using TGI Clustering Tools (TGICL) [23] package and cap3 software. Finally, the clusters and singletons were analyzed for annotation using a homology search engine, local BLAST [24,25] against Parablast database (http://blast.inje.ac.kr/parablast) (not released) and National center for biotechnology information (NCBI) nr database, NLM, USA. The significant matches were determined when expectation value was less than 1 × e^-5 with previously report genes. Function of ESTs was predicted through KOG analysis.

RESULTS

Summary of T. spiralis muscle stage larva ESTs

A total of 1,010 reads were collected from the T. spiralis muscle stage larva cDNA library. The length of the ESTs ranged from 78 to 801 bp with an average of 652 bp. Among the 992 ESTs submitted for BLASTx searches, 448 (45.2%) ESTs matched significantly with formerly identified gene transcripts, but 544 (55.8 %) ESTs were not. These ESTs were assembled into 60 clusters and 385singletons (Table 1).

Table 1.

Statistics of ESTs of T. spiralis

Among the ESTs matched, 445 ESTs (44.7%) appeared homologous significantly with formerly identified gene transcripts and, therefore, annotated respective gene transcripts. Of the annotated ESTs, 58 ESTs (5.9%) were homologous with Trichinella gene transcripts and 34 ESTs (3.4%) matched with C. elegans genes. The annotated ESTs were classified into 25 KOG categories: translation, ribosomal structure, and biogenesis (14.4%); RNA processing and modification (3.0%); transcription (0.6%); replication, recombination, and repair (1.2%); chromatin structure and dynamics (3.3%); energy production and conversion (16.8%); carbohydrate transport and metabolism (4.2%); amino acid transport and metabolism (1.5%); nucleotide transport and metabolism (0.9%); coenzyme transport and metabolism (0.6%); lipid transport and metabolism (1.5%); inorganic ion transport and metabolism (0.9%); secondary metabolite biosynthesis, transport, and metabolism (0.3%); cell cycle control, cell division, and chromosome partitioning (0.9%); nuclear structure (0.6%); defense mechanisms (0.9%); signal transduction mechanisms (10.5%); cell wall/membrane/envelope biogenesis (0.0%); cell motility (0.9%); cytoskeleton (1.8%); extracellular structures (2.1%); intracellular trafficking, secretion, and vesicular transport (3.0%); posttranslational modification, protein turnover, and chaperones (12.6%); general function prediction only (9.6%); and function unknown (7.5%). Clusters associated with cell respiration were very frequently detected in this study. In particular, cytochrome c oxidase (34 ESTs) was identified the most frequently (Table 2).

Table 2.

Frequently identified ESTs in T. spiralis muscle stage larva ESTs

DISCUSSION

Trichinella spp. is intracellular parasites of vertebrates, in which the entire life cycle is confined to the host. These parasites alternate between enteric and muscle phases of infection, and several species have been shown to induce mortality and morbidity in humans. The parasites establish remarkable intracellular interactions with different host cell types when adapting to these diverse habitats (intestinal mucosal epithelial cells and striated skeletal muscle cells) [26,27]. A wide range of changes are induced in host cells as the result of infection with Trichinella spp., but these have been poorly characterized with regard to the relevant mechanisms and their significance to parasite survival. Furthermore, the role of the parasite in regulating these host cell changes remains largely unknown.

The KOG system classifies genes on the basis of orthologous relationships between genes [28]. The KOG classification of ESTs from the Trichinella cDNA library was utilized in this study. The largest group of ESTs was genes belonging to the group C associated with energy production and conversion. The cytochrome-associated proteins, particularly cytochrome c oxidase, were most frequently identified in this study. Eukaryotic cytochrome c oxidase is the terminal multicomponent enzyme of the energy-transducing mitochondrial electron transport chain [29]. It is a member of the superfamily of hemecopper-containing terminal oxidases, characterized by the presence of histidine ligands to 2 heme groups and to a CuB copper ion [30]. Although currently it is not clear why this gene is highly transcribed once the infectious larval stage is reached, we believe that the infectious larva might require much more energy than in the muscle stage; therefore it is necessary for the genes associated with energy metabolism, including cytochromes, to be abundantly transcribed.

The translation, ribosomal structure, and biogenesis group (14.4%) was expressed at the second highest level. This means that many proteins were newly generated at the infectious larva stage. The group with the third-highest expression level was also associated with protein synthesis (posttranslational modification, protein turnover, chaperones group). Genes associated with carbohydrate transport and metabolisms were identified more frequently (4.2%) than were genes associated with amino acids, lipids, nucleic acid transport, and metabolism (1.5%, 1.5 %, and 0.9%, respectively).

Serine proteinase has been reported to perform functions in host tissue invasion or molting. This serine proteinase may be attributable to infection into host muscle cells. Previously, several studies have been conducted concerning Trichinella serine protease. In a comparison of two trypsin-like domains, Trap et al. [31] previously suggested that serine protease was detected at both the larval and adult stages. Immune- localization analysis also indicated that the protease was located on the inner layer of the cuticle and esophagus of the parasite, thereby suggesting a potential role in its molting and/or digestive functions [31]. The protease of Trichinella was well characterized by Moczon and Wranicz [32]. Under in vitro conditions, the muscle larvae of T. spiralis secreted minute amounts of a cysteine proteinase into the outer environment from the stichosome. Although multiple proteinase activities were histochemically detected in the somatic muscles, stichosome, midgut, and genital primordium of the muscle larvae, none of these enzymes appeared to be the one that was secreted. Several histochemically demonstrable proteinases were also detected in the cells of 48- to 72-hr-old juvenile worms. One was localized within the esophageal lumen and at or around the anterior esophagus of the larvae, where the developing stichocytes are believed to occur.

Three elongation factor genes were identified in this study. This gene was found to be important in tRNA studies. EF-Tu delivers aminoacyl-tRNAs to ribosomes in the translation system. However, unusual truncations detected in some animal mitochondrial tRNAs appear to prevent recognition via a canonical EF-Tu [33]. Also, it was previously demonstrated that the chromadorean nematode harbors two distinct EF-Tus, one of which (EF-Tu1) binds only to T-armless aminoacyl-tRNAs, whereas the other (EF-Tu2) binds to D-armless Ser-tRNAs [33,34]. Neither of the EF-Tus can bind to canonical cloverleaf tRNAs. It has been recently reported that Trichinella spiralis mitochondria DNA harbors genes that encode for three distinct types of tRNAs: T-armless tRNAs, D-armless tRNAs, and cloverleaf tRNAs with a short T arm [35]. The translation system of Trichinella species may be an intermediate evolutionary state between the canonical system which utilizes uses only cloverleaf tRNAs and the unusual chromadorean system which utilizes only tRNAs that lack the T or D arm. Mitochondrial EF-Tu species, EF-Tu1 and EF-Tu2, were reported from Trichinella britovi. T. britovi EF-Tu2 was shown to bind only to D-armless Ser-tRNA, as does Caenorhabditis elegans EF-Tu2 [33]. In contrast to the case of C. elegans EF-Tu1, however, T. britovi EF-Tu1 bound to all 3 types of tRNA present in the mitochondria of Trichinella. These results indicate that the Trichinella mitochondrial translation system, and in particular the tRNA-binding specificity of EF-Tu1, could represent an intermediate state between the canonical system and the chromadorean nematode mitochondrial system [33].

In the present study, we verified that the T. spiralis mitochondria translation system does include at least one cloverleaf tRNA. We cloned 2 EF-Tu species from T. britovi, a close relative of T. spiralis, and assessed their aminoacyl-tRNA specificity.

According to this study, 45% of the T. spiralis EST clusters evidenced homology with proteins from other species, whereas 55% were located in the category of unknown proteins. Among these, 3 highly transcribed genes (8-11 transcripts of 992 ESTs) were identified. Although we could not determine their functions, these genes might be centrally involved in larval infection or larval life maintenance. More information regarding these genes is required for Trichinella studies.

ACKNOWLEDGEMENTS

This study was supported by a Pusan National University Medical Research Institute grant (2006-50).

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ST category	No. of clones (%)
Total clones sequenced	1,010
ESTs submitted for BLAST search	992
No. of EST clusters	60
Singletons	385
Annotated ESTs	445 (44.7)
ESTs with homology to Trichinella spiralis	58 (5.9)
ESTs with homology to Caenorhabditis elegans	34 (3.4)

Cluster ID	Length	E-value	Annotation	No. of ESTs
TS0799-T3.ab1	748	1.00e^-123	Cytochrome c oxidase	34
TS1030-T3.ab1	490	6.00e^-44	Ts-abundant larval transcript-1	11
TS0416-T3.ab1	782	2.00e^-17	Ts-abundant larval transcript-2	11
TS0920-T3.ab1	504	5.00e^-55	Ts-abundant larval transcript-3	8
TS0813-T3.ab1	541	2.00e^-48	NADH dehydrogenase	8
TS0753-T3.ab1	646	2.00e^-69	Histone H3.3	8
TS0126-T3.ab1	772	5.00e^-17	Cytochrome b protein	6
TS0971-T3.ab1	765	6.00e^-93	Small heat shock protein	5
TS0153-T3.ab1	777	4.00e^-51	MLP/CRP family	5