• We are sorry, but NCBI web applications do not support your browser and may not function properly. More information
Logo of nihpaAbout Author manuscriptsSubmit a manuscriptNIH Public Access; Author Manuscript; Accepted for publication in peer reviewed journal;
Mol Biochem Parasitol. Author manuscript; available in PMC Sep 1, 2010.
Published in final edited form as:
PMCID: PMC2705950
NIHMSID: NIHMS110901

Biomphalaria glabrata peroxiredoxin: effect of Schistosoma mansoni infection on differential gene regulation

Abstract

To identify gene(s) that may be associated with resistance/susceptibility in the intermediate snail host Biomphalaria glabrata to Schistosoma mansoni infection, a snail albumen gland cDNA library was differentially screened and a partial cDNA encoding an antioxidant enzyme thioredoxin peroxidase (Tpx), or peroxiredoxin (Prx), was identified. The 753 bp full-length, single-copy, constitutively expressed gene now referred to as BgPrx4 was later isolated. BgPrx4 is a 2-Cys peroxiredoxin containing the conserved peroxidatic cysteine (CP) in the N-terminus and the resolving cysteine (CR) in the C-terminus. Sequence analysis of BgPrx4 from both resistant and susceptible snails revealed the presence of several (at least 7) Single Nucleotide Polymorphisms (SNPs). Phylogenetic analysis indicated BgPrx4 to resemble a homolog of human peroxiredoxin, PRDX4. Northern analysis of hepatopancreas RNA from both resistant and susceptible snails showed that upon parasite exposure there were qualitative changes in gene expression. Quantitative real-time RT-PCR analysis showed differences in the levels of BgPrx4 transcript induction following infection, with the transcript up-regulated in resistant snails during the early phase (5 h) of infection compared to susceptible snails in which it was down-regulated within the early time period. While there was an increase in transcription in susceptible snails later (48 h) post- infection, this never reached the levels detected in resistant snails. A similar trend - higher, earlier up-regulation in the resistant snails but lower, slower protein expression in susceptible snails - was observed by Western blot analysis. Enzymatic analysis of the purified, recombinant BgPrx4 revealed the snail sequence to function as Prx but with an unusual ability to use both thioredoxin and glutathione as substrates.

Keywords: Snail, Parasite, Resistant, Susceptible, Peroxiredoxin, BgPrx4

1. Introduction

Schistosomiasis remains a disease of major global public health concern and is rated second only to malaria in posing chronic and debilitating illness to populations that endure poor sanitation, inadequate health infrastructure and poverty. Recognized as one of the major neglected tropical diseases, schistosomiasis was recently referred to as a ‘silent pandemic’ [1]. Humans are susceptible to infection by a larval stage shed from intermediate host snails. Until an effective vaccine against the causative parasites (human blood flukes, species within the genus Schistosoma) becomes available, there remains a need for alternative control methods. As a means to reduce the transmission of these parasites, efforts must be sustained to more fully understand the molecular basis of the snail-schistosome relationship. Such knowledge may lead to better tools to detect these parasites or to block transmission at the vector (i.e. snail host) stage of parasite development [2].

The outcome of each snail-parasite encounter is governed by the genetics of both organisms. Exposing snail stocks genetically selected for various susceptibility/ resistance phenotypes to different strains of parasites showed that the genetics of susceptibility in the snail Biomphalaria glabrata to Schistosoma mansoni is complex and variable [3-4]. Snails are categorized as resistant if, upon exposure, as either adults or juveniles, they show an active defense reaction (mediated by hemocytes possibly aided by soluble factors in the hemolymph) against the invading miracidia. Without a similar defense response in susceptible snails, miracidia develop through several larval stages, eventually yielding cercariae that are infective to humans.

To determine the molecular basis of these opposing phenotypes, snails displaying either resistance or susceptibility to infection are being utilized to search for genes that may be involved in parasite destruction. Characterization of anti-parasite genes are important if genetically modified (GM) snails carrying such genes are to be realistically considered as part of an integrated control effort aimed at the cessation of transmission of schistosomiasis.

Using various gene-discovery methods, several genes that may be involved in resistance/susceptibility of the snail host in its relationship to trematodes such as S. mansoni and Echinostoma caproni have been described [5-11]. In addition, a rational, targeted approach to identify genes with deterministic roles in the snail/schistosome interaction has also proven fruitful [12]. An ongoing genome project aimed at deciphering the 931megabase (Mb) sequence of B. glabrata will facilitate further progress in both gene discovery and targeted approaches [13].

Through studies of the innate defense mechanism(s) involved in the snail's ability to destroy incoming parasites, it has been found that the hemocytes of B. glabrata exploit reactive oxygen (ROS) and nitrogen species (RNS) [14-16]. As part of an effort to understand the roles of ROS and RNS in this system, we [17] previously identified cDNA transcripts (Accession number AAK26236) encoding peroxiredoxin, one of several enzymes responsible for maintaining redox balance. Several clones encoding this enzyme were found by differential antibody screening of an albumen gland cDNA expression library. The antibodies were raised against soluble albumen gland proteins prepared from a non-susceptible snail stock (LAC 2). This stock was derived through several generations (by self-fertilization) from a generally susceptible stock (NMRI).

Peroxiredoxins (Prxs), formerly known as thioredoxin peroxidases, are a family of conserved antioxidant enzymes that play protective roles by neutralizing reactive oxygen and nitrogen species that can damage cellular function. If not neutralized, reactive oxygen and nitrogen species cause protein oxidation, lipid peroxidation, DNA base modification and DNA strand breaks [18]. The enzymes catalyze the reaction thioredoxin + H2O2 = thioredoxin disulfide + H2O. Prxs are also involved in cell signaling, protein phosphorylation, transcriptional regulation, and apoptosis [19-20].

Three classes of Prx have been characterized: 1-Cys, typical 2-Cys, and atypical 2-Cys. All three classes catalyze a two-step reaction that is centered on a redox-active cysteine called the peroxidatic cysteine. The first step - the attack of the peroxide substrate by the peroxidatic cysteine and its oxidation to S-hydroxycysteine - is common to all three peroxiredoxins, whereas the second step - the regeneration of cysteine from S-hydroxycysteine - is different in the three classes.

The functions and mechanisms of action of Prxs in protecting against sulfur-containing radicals (but not against oxidation systems lacking thiols) have been recognized [21], but remain poorly understood. However, the involvement of other antioxidant enzymes (e.g. catalase, superoxide dismutase, and glutathione peroxidase) in enabling organisms to adapt and survive otherwise lethal oxidative environments has been well documented.

Schistosome parasites lack catalase and utilize a glutathione-thioredoxin peroxidase to reduce hydrogen peroxide that is known to be lethal for the parasite [14, 22]. Prxs have now been described in a variety of parasitic worms in which they are believed to play a role in the removal of toxic radicals, thus helping to circumvent the host immune response [23].

The pathways that generate superoxide and NO and that catalyze their further conversion to more or less damaging species are highly varied and complex. In particular, potential roles for Prx in snails remain speculative. Possibilities include contributing to the hemocyte's antagonistic attack on parasites, and protection of the host from peroxides of either host or parasite origin.

Here, we report a full-length cDNA encoding a B. glabrata 2- Cys peroxiredoxin gene (BgPrx4), its molecular characterization, and the temporal regulation of its transcript upon exposure of resistant and susceptible snails to parasites. Using Western blot analysis, we compared the protein expression profiles of the 30 kDa BgPrx4 protein in tissues of the resistant and susceptible snails in response to parasite infection. Finally, we report functional enzymatic analysis of the recombinant (rBgPrx4) enzyme, including its capacity to utilize either thioredoxin or glutathione as substrate.

2. Materials and Methods

2.1. Snails

The non-susceptible LAC2 snail stock was developed from the susceptible NMRI stock of B. glabrata by self-fertilization for several generations (F0- F12) as described previously [24]. At each successive generation, progeny snails displayed progressively less (25%) susceptibility to parasite infection. This was determined by taking a sample of each progressive generation of LAC2 and following their infection rates (cercarial shedding) post infection by S. mansoni miracidia. In our laboratory, “non-susceptibility” is defined as the inability of the snail to sustain schistosome infection and on histological examination parasites are seen surrounded by a minimal host reaction consisting primarily of amoebocytes. Lack of parasite development may be due to a weak form of resistance or biochemical unsuitability [24-25]. In contrast, in snails that are classified as “resistant”, the larval stage is engulfed by hemocytes within 3-4 days of parasite infection in a very strong immune mediated reaction. In our laboratory, the B. glabrata BS-90 [26] snails display invariant 100% resistance to S. mansoni infection as both juveniles and adults. The susceptible B. glabrata NMRI snails exhibit both juvenile and adult susceptibility when exposed to the S. mansoni NMRI strain. Likewise, the M-line snails are also highly susceptible to S. mansoni infection [27]. Within this study, snails were either juveniles (up to 4 mm in diameter) or adults (6-10 mm in diameter), and were maintained in aged, dechlorinated tap water at room temperature and fed on Romaine lettuce. 13-16-R1 snails were maintained at Oregon State University (OSU) and are predominantly resistant to S. mansoni [28].

2.2. Copy number analysis

Copy number of the BgPrx4 gene was determined by slot blot analysis by comparing the hybridization signal of BgPrx4 to that of the single copy B. glabrata ferritin gene using the procedure previously described [29]. Briefly, 10-fold serial dilutions of DNA from 10 μg to 1 ng in a total volume of 150 μl TE buffer, pH 8.0 were pipetted into microcentrifuge tubes containing 12 μl of 5M NaOH and 3 μl 0.5M EDTA. Samples were boiled (10 min), snap-chilled on ice, and neutralized with an equal volume of 2M Ammonium Acetate prior to application. Duplicate strips of the membrane were probed with either 32P-labeled ferritin or 32P-labeled BgPrx under standard hybridization conditions. Membranes were washed at moderate stringency (1× SSC, 0.5% SDS at 60°C) before being subjected to autoradiography on X-ray film with intensifying screens at -70°C for 7 days. Densitometric analyses of the autoradiographs were performed using the public domain NIH Image program (available at http://rsb.info.nih.gov/nih-image).

2.3. DNA and RNA isolation

DNA was isolated from individual snails as previously described [5]. For RNA isolation, juvenile snails (15 snails for each stock) of B. glabrata (resistant BS-90, non-susceptible LAC 2, and susceptible NMRI and M-line) were treated overnight with autoclaved water at room temperature containing 100 μg/ml ampicillin to minimize bacterial contamination. To assess possible responses to infection, individuals were exposed to five S. mansoni miracidia. Exposures were for 5 different time periods (0, 5, 10, 24, 48 h). At the end of each time period, total RNA was extracted immediately from individual snails (whole body) using RNA-Bee according to the manufacturer's protocol (Tel-test, Friendswood, TX). RNA was also isolated from snail tissue (albumen gland, hepatopancreas, cerebral ganglia, hemocytes and ovotestis) as previously described [8, 30]. For performing Random Amplification of cDNA Ends (RACE) reactions, RNA was prepared from snail head-foot using an RNeasy® kit from Qiagen (Valencia, CA) as described [28].

2.4. Northern and Southern blot analysis

Northern blots (transfer, hybridization and washes) were performed using total RNA (5μg/lane) with the MOPS/formaldehyde method as described [30]. Southern blots (transfer, hybridization and washes) were done on digested DNA or PCR samples according to a previously described method [31]. DNA probes were either the intact recombinant plasmids [partial cDNA (pBGC2) or full-length cDNA (BgPrx4) ] or PCR amplified products synthesized from the aforementioned recombinant plasmids using B. glabrata Prx4 gene specific primers F: 5-ATGGCATCCTCTCTGCAAACCGGG-3′ and R: 5′-TTAGAGTTCATCGTTAGATTGC-3′. For Southern and Northern hybridizations, radiolabeled probes were prepared using the random primed DNA labeling kit to incorporate the 32P - dCTP according to the manufacturer's instructions (Roche, Indianapolis, IN). Hybridized blots were washed twice at room temperature, for 30 min in 0.2× SSC, and with the same stringency twice for 30 min at 60°C. Washed filters were subjected to autoradiography on Kodak-X-Omat XAR-2 film with intensifying screens at -70°C for between 1 and 4 weeks.

2.5. Reverse Transcriptase Polymerase Chain Reaction (RT-PCR)

Total RNA isolated from albumen glands, hepatopancreases, hemocytes, ovotestes and cerebral ganglia of unexposed snails was treated with RNase-free DNase (RQI, Promega, WI). First strand cDNA was synthesized using the treated RNA in the presence of an oligo (dT) primer and MuLV reverse transcriptase at 42°C according to the manufacturer's instructions (Roche Molecular Systems, Branchburg, NJ). Control reactions (with no reverse transcriptase) were performed to preclude any DNA contamination. Second strand reactions were performed using BgPrx4 gene-specific primers mentioned in section 2.4. The PCR products were analyzed on 1% TBE-agarose gels and the bands were visualized using ethidium bromide. As a reference, the constitutively expressed B. glabrata myoglobin gene [32] was amplified in parallel using the same conditions as described above [7].

2.6. Real time RT- PCR analysis of the B. glabrata BgPrx4 transcript

Real time PCR analysis was performed with BgPrx4 gene-specific primers as described previously using whole, juvenile snail RNA. RT-PCR of the constitutively expressed myoglobin gene (B. glabrata specific myoglobin primers F: 5′-GATGTTCGCCAATGTTCCC-3′; R: 5′-AGCGATCAAGTTTCCCCAG-3′) was used to assess the comparability of samples and confirm that template cDNA was used in equivalent amounts for each amplification reaction. The RT-PCR reactions were performed using an Applied Biosystems 7300 Real Time PCR System (Applied Biosystem, Foster City, CA). The reaction was performed in a one-step format with 80 ng of DNase treated-total RNA. DNase treatment was done with RNase-free DNase (RQI,) according to the manufacturer's (Promega, Madison, WI) suggested protocol. First strand cDNA reactions and PCR amplifications were performed in triplicate with the Full Velocity SYBR Green QRT-PCR Master mix according to the manufacturer's instructions (Stratagene, La Jolla, CA). A validation assay and melting curve using four different input RNA samples with gene-specific primers corresponding to BgPrx4 (with an expected product size of 753 bp) and myoglobin (with an expected product size of 322 bp) was performed at the beginning of the study according the manufacturer's instructions (Applied Biosystems). The amplification showed efficiencies of these primers were equal and a single peak was obtained at the expected temperature indicating target- specific amplification (data not shown). Each 25 μL of the final amplification reaction volume contained 200 nM of BgPrx4 forward and reverse primers. A parallel amplification reaction was performed using the same concentrations of starting RNA but with 50 nM of myoglobin primers. This reaction was performed for adjusting the differences in concentration of the reverse transcribed RNA starting material. All reactions also contained 300 nM of reference dye, 1× of Full Velocity SYBR Green QRT-PCR master mix containing RT-PCR buffer, SYBR green I dye, MgCl2 and nucleotides (G, A, U, C). The amplification protocol included an initial incubation at 48°C, 45 min for cDNA synthesis and a 95°C initial denaturation for 10 min followed by 40 cycles with 95°C denaturation for 10 sec, and annealing/ amplification at 58°C for 1 min. Fold increases of gene expression were calculated by comparative Ct method with the formula indicated below [33]:

Fold change=2ΔΔCt=2[(CtPrx,exposedCtmyglobin,exposed)(CtPrx,unexposedCtmyoglobin,unexposed)]

In order to determine the significance of differences (P < 0.05 or P < 0.01) in gene expression for the different time points the P-value was calculated by comparing delta delta Ct values using the Student's t-test and one-way ANOVA between the exposed and non-exposed snails within each stock.

2.7. RACE reaction and isolation of clones encoding the full-length BgPrx4 cDNA from the 13-16-R1 stock of B. glabrata

The original cDNA insert identified from the recombinant plasmid clone pBGC2 contained only the partial cDNA (666 bp) of the B. glabrata Prx (GenBank Acc. No. AY026258) ortholog [17]. To extend this sequence, the head-foot of an adult 13-16-R1 snail was placed in 200 μL of TRIzol (Invitrogen, Carlsbad, CA) and immediately frozen at -80°C. RNA was extracted by disruption of the tissue, followed by sequential phenol: chloroform, chloroform:isoamyl alcohol extractions, and isopropanol precipitation. To ensure the removal of any contaminating DNA, extracts from head-foot were digested with DNase (Qiagen, Valencia, CA) and eluted using RNeasy ® columns (Qiagen, Valencia, CA). Reverse transcription (1 h) was by MMLV reverse transcriptase (Promega, Madison, WI) in the presence of Prime RNase inhibitor (Eppendorf, Westbury, NY) and Oligo (dT)15 primer (Promega, Madison, WI). The cDNAs were heated at 95°C for 10 min to inactivate reverse transcriptase. After centrifugation, cDNA products were used as templates for PCR. The 5′-ready cDNA was prepared using Ambion's (Austin, TX) FirstChoice® RLM RACE Kit, and the BgPrx4 sequence was amplified using a gene-specific primer and the primers supplied with the kit. The amplicon was sequenced by the Central Services Laboratory of Oregon State University's Center for Genome Research and Biocomputing.

2.8. Full-length sequences for additional snail stocks and sequence analysis

The B. glabrata peroxiredoxin sequence previously submitted to GenBank (Accession No. AY026258, previously named BgTpx) lacked 31 amino acids at the 5′ end of the transcript. Consequently, using the existing sequence data and mRNA from the 13-16-R1 snail stock (see previous section), the 5′end of this gene was deduced by 5′ RACE. Subsequently, gene-specific primers were designed to deduce full-length open reading frames (ORFs) for the BS-90 (resistant), LAC2 (non-susceptible) and the NMRI and M-line (susceptible) snail stocks. The snail BgPrx4 sequences have been submitted to GenBank (Accession No. BgPrx4-BS-90: FJ176938; BgPrx4-LAC2: FJ176940; BgPrx4-M-line: FJ176941; BgPrx4-NMRI: FJ176942; BgPrx4-δNMRI: FJ176939). DNA sequences were analyzed using EMBOSS [34]. The computer program ClustalW (version 2.0.5) was used to generate the multiple sequence alignment [35-36]. Comparisons of the sequences were made with sequences in the protein and nucleic acid public databases using the BLAST algorithm [37]. The deduced amino acid sequence of BgPrx4 was further analyzed using the NCBI conserved domain database [38] to classify and characterize the type of protein domains encoded within it. These data were also used to query the Interpro EMBL-EBI [39], a database of protein families, domains and functional sites in which identifiable features found in known proteins can be applied to unknown protein sequences, and the Sanger MEROPS release 7.80 [40] database. Signal sequence prediction was performed using the Signal P program version 3.0 [41].

To ascertain possible orthology between potential molluscan Prx genes and the more fully characterized mammalian genes, we identified 14 B. glabrata EST sequences from GenBank with annotation that included ‘thioredoxin peroxidase’ or ‘peroxiredoxin’. Using Sequencher (Gene Codes Corporation, Ann Arbor, MI), these were assembled, yielding 4 non-redundant contigs (BxPrx-contig A: AY026258, EE722991, EE723209, EE723214; BgPrx-contig B: FC858724, DW474756; BgPrx-contig C: EX003613, FC857164, FC858504, EX003036, EW996752, ES488429, ES482777; BgPrx-contig D: EW997425) each encoding the peroxiredoxin active site motifs. The assignment of names for members of gene families in non-model species is non-trivial, in part because of erroneous annotation of many sequences in public databases, in part because of gene duplications and/or loss over evolutionary time, and in part because changes are, in some cases, so extensive that ancestry is no longer obvious. Taking a prudent approach, we decided to use the human database, as this is a high quality, thoroughly curated and universally available benchmark for the assignment of names, and because conservation of peroxiredoxin sequences is sufficient for meaningful comparisons. The phylogenetic analyses of various Prxs were performed using MEGA4 program that uses a Maximum Composite Likelihood (MCL) method formerly known as Simultaneous Expression (SE) method based on the maximum likelihood principle [42]. It has been shown that the use of this method substantially improves the accuracy of NJ trees.

2.9. Expression of the snail BgPrx4 in E. coli: purification and preparation of antibody against the recombinant enzyme

Insert DNA (666 bp) from the recombinant plasmid clone pBGC2 containing the partial cDNA of the B. glabrata BgPrx4 ortholog [17] was sub-cloned into the prokaryotic expression vector pRSETB (Invitrogen, Carlsbad, CA) and expressed as a His-tagged fusion protein using the method of Ghosh et al. [43]. Briefly, the Open Reading Frame (ORF) was amplified by PCR using a 5′ primer 5′-CGCGGATCCTTCGGCACGAGC-3′ containing a recognition site for BamH1, and a 3′ primer 5′-CGGAATTCTCAGAAGTTCATCGTTAG-3′ containing a recognition site for EcoR1 and a stop codon. A three step-cycle PCR program of 94° C for 1 min, 65° C for 45 s and 72° C for 1.5 min was employed for 30 cycles. The gel-purified PCR products were digested with BamH l and EcoR1 and ligated into the expression vector pRSET B (Invitrogen, Carlsbad, CA) in frame. Recombinant plasmids were used to transform E. coli (DH10B). In order to produce recombinant protein from the BgPrx4-pRSETB constructs, purified recombinant DNA from the transformants propagated in E. coli DH10B were checked for the correct size and orientation (in-frame) and verified by PCR before transformation into E. coli B strain BL21 (DE3)pLYsS (Invitrogen, Carlsbad, CA). Protein expression in the transformants containing the BgPrx4 insert was induced with 0.4 mM IPTG for 2 hr at 37° C according to manufacturer's instructions (Invitrogen, Carlsbad, CA). The expressed BgPrx4-His-tagged fusion protein was purified using a nickel-NT agarose column. For elution, buffer contained varying concentrations of imidazole (60 mM-500 mM) according to the manufacturer's suggested protocol (Novagen/EMD Biosciences, Madison, WI). The recombinant protein, eluted with 300 mM imidazole, was dialyzed against Tris-Buffered Saline (TBS, pH 8.0), and quantitated by the bicinochoninic protein assay (Pierce, Rockford, IL). Antibodies were produced in six Swiss albino mice (Charles River Laboratories Inc., Wilmington, MA) using purified recombinant BgPrx4 protein. The Biomedical Research Institute's (BRI) animal care program complies with the guidelines adopted by the Office of Laboratory Animal Welfare (OLAW) and maintains an OLAW Assurance. No experimental animals were used unnecessarily and all were well -treated to avoid distress. All animal procedures were conducted by protocols approved by the BRI's animal care and use committee (IACUC). Approximately 50 μl of blood was obtained from each mouse (pre-bleed) by collecting blood from the tail vein by a needle-prick procedure. For primary immunizations, 10 μg of purified BgPrx4 protein was mixed with 40 mg/ml alum (1:1) in a total volume of 300 μl and injected subcutaneously in the right flank. At three-week intervals, two subsequent boosts (300 μl volume) were administered subcutaneously in separate sites, with 5 μg of the purified protein/alum mixture (as above). Following collection of blood as above, antibody titers were determined by Western blotting throughout the course of immunization, prior to each booster immunization, and at 3 weeks after the last boost. Mice were then euthanized by an IACUC-approved CO2 inhalation procedure, and blood was collected by cardiac puncture.

2.10. Western Blotting

Two individual snails from adult resistant (BS-90) and susceptible (NMRI) stocks were either exposed (12-15 miracidia/ snail) for 5 h and 24 h, or left unexposed (0 h). At the end of each exposure, the hepatopancreas and albumen gland tissues were dissected from the snails, snap frozen in liquid nitrogen and kept frozen at -70°C. For soluble protein extractions, fresh and/or frozen adult snail tissue samples were homogenized in sterile PBS, pH 7.5 on ice using a mechanized Kontes pestle (VWR, West Chester, PA). Soluble protein was separated from the membrane-bound insoluble material by centrifugation at 10,000 × g for 20 min at 4°C. Extracts were either analyzed immediately or aliquoted and stored at -70°C until required. Long-term storage (up to 6 months) at -70°C had no effect on enzyme activity. The protein concentration in the supernatant was determined by the BCA method [44]. Soluble extracts (50 μg) were resolved under reducing conditions by 15% Sodium Dodecyl Sulfate-Poly Acrylamide Gel Electrophoresis (SDS-PAGE). Western Blot [45] was performed by transferring resolved protein onto a nitrocellulose membrane using a semi-dry blotter in a buffer containing 0.192 M glycine, 0.025M Tris pH 8.3, 0.0013 M SDS and 10-20% methanol. After transfer for 1 h at 10-15 V/200-300 mA, proteins transferred to the membrane were visualized using 0.4% Ponceau S stain in 2% trichloroacetic acid prior to blocking and antibody addition. The membrane was then blocked using blocking buffer (TBS, 0.1% Tween-20, 0.05% Triton X-100 and 3% Carnation milk powder) for 2 h at room temperature, followed by incubation with mouse anti-BgPrx4 antibodies (1:500 dilution) in blocking buffer overnight at 4°C as described previously [46]. The second antibody was a 1:2000 dilution of goat anti-mouse IgG Fc conjugated with alkaline phosphatase (Jackson Immunoresearch Laboratories Inc., West Grove, PA) in blocking buffer. Following three washes with the wash buffer (TBS, 0.1% Tween-20, 0.05% Triton X-100) the antigen-antibody complexes were visualized using the BCIP/NBT phosphatase substrate system according to the manufacturer's instructions (KPL Protein Research Products, Gaithersburg, MD).

2.11. Functional Analysis of Biomphalaria glabrata Peroxiredoxin 4

The activity of the recombinant B. glabrata peroxiredoxin was determined with the following substrates: H2O2, cumene hydroperoxide, tertiary butyl hydroperoxide, recombinant Escherichia coli thioredoxin and glutathione by monitoring the oxidation of NADPH in reactions coupled to recombinant E. coli thioredoxin reductase (22) or yeast glutathione reductase (Sigma-Aldrich, St. Louis, MO). All assay reactions were performed in 1.0 ml 0.1 M potassium phosphate (pH 7.4), 10 mM EDTA using 100 μM NADPH and 0.15 μM thioredoxin reductase or 0.3 unit/ml yeast glutathione reductase. Kinetic parameters were determined using Lineweaver-Burk plots using KaleidaGraph 4 (Synergy Software, http://www.synergy.com) least squares best fit of data and varying concentrations of one substrate while maintaining the concentration of the other substrate. In thioredoxin-coupled assays, thioredoxin concentrations ranged from 4 to 120 μM and in the glutathione-coupled assays glutathione concentrations ranged from 0.05 to 1 mM at a fixed concentration of 0.5 mM H2O2. To determine kinetic parameters for hydroperoxide substrates, H2O2, cumene hydroperoxide and tertiary butyl hydroperoxide concentrations ranged from 0.01 to 1 mM, with fixed concentrations of either thioredoxin (16 μM) or glutathione (0.7 mM). All assays were done in triplicate and each determination was repeated three times.

3. Results

3.1. Copy number analysis of BgPrx4

The copy number of the gene encoding BgPrx4 was deduced by slot blot analysis. We compared the signal intensities of a known single copy gene, ferritin [47], with that of the BgPrx4 gene, both hybridized to the same blot sequentially. Ten-fold serial dilutions of denatured and neutralized B. glabrata BS-90 genomic DNA from 10 μg-1 ng were spotted and probed with either the labeled ferritin gene (Fig. 1A) or BgPrx4 as probes (Fig. 1B) respectively as described previously [29]. Probes for both ferritin and BgPrx4 detected signals with 10 μg and 100 ng of B. glabrata DNA and not any of the lower dilutions. Since ferritin is present as a single copy in the snail genome, signals of the same intensities indicated that BgPrx4 also probably exists as a single copy gene.

Figure 1
Copy number analysis of BgPrx4 in the diploid genome of B. glabrata (BS-90)

3.2. BgPrx4 is transcribed in all snail stocks examined

Northern blot analysis of BgPrx was performed using total RNA from the snail hepatopancreas since this is the most abundant tissue sample that can be easily isolated from a snail. Total RNA from hepatopancreas was isolated from unexposed (Figs. 2A and B, lanes 2 and 5) and S. mansoni exposed 5 h (Figs. 2A and B, lanes 3 and 6) and 24 h (Figs. 2A and B, lanes 4 and 7) resistant BS-90 and susceptible NMRI snail stocks. This was done in order to determine if transcripts differed in size between the different strains and if exposure to parasites modulates the transcription of the snail-host Prx gene. The ethidium bromide stained gel prior to blotting is shown in Fig. 2A which shows the predominantly staining snail ribosomal RNA (21S) band. Upon hybridization with the radiolabeled BgPrx4 PCR product, transcript sizes of ~1.8 Kb, ~1.2 Kb and 0.7 Kb were detected in both normal BS-90 (Fig. 2B, lane 2) and NMRI (Fig. 2B, lane 5) unexposed snails. The ~1.8 Kb, ~1.2 Kb size transcripts were also detected in these snails following exposure to parasites for 5 h or 24 h. However, after infection, smaller transcripts of 0.6 Kb and 0.3 Kb (indicated by dark arrows) not seen in the unexposed snails appeared in both BS-90 (Fig. 2B, lanes 3 and 4) and NMRI snails (Fig. 2B, lanes 6 and 7). Mouse liver RNA was loaded in lane 8 as marker (note positions of 28S and 18S rRNA in Fig. 2A) to which there appears to be a signal at ~4 Kb that is unrelated to Prx since the expected size of the mouse Prx transcript ranges from approximately 1-2 Kb.

Figure 2
Northern analysis of B. glabrata using BgPrx4 probe

3.3. Tissue specificity of expression of the BgPrx4 transcript

To determine the tissue specificity of the BgPrx4 in normal snails, we performed RT-PCR assays using gene-specific primers designed from the BgPrx4 sequence. The ethidium bromide stained gel of the amplified 753 bp product using cDNA template from various tissues is shown in Fig. 3A. BgPrx4 sequence was amplified from the albumen gland (Lane 2), hepatopancreas (lane 3), ovotestis (lane 5) and cerebral ganglia (lane 6). No signal was discernable in hemocytes (Lane 4) despite several attempts of repeating the assay. Failure to detect the BgPrx4 transcript in hemocytes was not due to the lack of template, as evidenced from RT-PCR performed instead with gene specific primers corresponding to the constitutively expressed housekeeping gene myoglobin (data not shown). Amplicons representing BgPrx have been found in hemocytes from other laboratories (Bayne et al. personal communication). This anomaly may be due to differences in hemocyte tissue processing and RNA extraction methods in the different laboratories. Lane 7 shows the absence of product with the BgPrx4 primers in the absence of cDNA template. Southern blot analyses of the above gel using 32P-labeled BgPrx4 probe showed products from all tissues examined (Fig. 3B, lanes 2, 3, 5 and 6) other than the hemocytes (Fig. 3B, lane 4).

Figure 3
RT-PCR analysis of B. glabrata tissue specific distribution of BgPrx4

3.4. Real-time RT-PCR reveals the temporal modulation of gene expression of BgPrx4 upon S. mansoni infection of B. glabrata snails

To examine quantitative differences in the amounts of BgPrx4 transcript between resistant (BS-90) non-susceptible (LAC2) and susceptible (NMRI and M-line) snails following exposure to S. mansoni, RNA was isolated from juvenile whole snails before and after exposure to miracidia and analyzed by real time RT-PCR. As shown in Fig. 4, a 13-fold increase in expression occurred in resistant (BS-90) snails early (5 h) post-exposure, followed by a decline at 10 h and 24 h and a 16-fold increase at 48 h in these snails. Similarly, LAC2 snails when infected showed a 5-fold and 8-fold change in induction at 5 h and 10 h, respectively. As seen in the BS-90 snails, expression levels in LAC2 snails also decreased at 24 h followed by 8.5-fold increase at 48 h. Thus, in both stocks that are capable of resisting infection, the levels of induction of the BgPrx4 encoding transcript was significantly up-regulated during the early (5-10 h) stages of infection, followed by a decline at 24 h and another peak of expression at 48 h. In contrast, in the same early stages of infection (5-10 h), induction of BgPrx4 in both susceptible snails (NMRI and M-line) remained weak (≤ 2.3 fold Fig. 4); higher levels of induction were evident later (24-28 h) but never reached levels seen in the resistant snails.

Figure 4
Relative abundance of BgPrx4 transcripts in BS-90, LAC2, NMRI and M-line stocks of B. glabrata

3.5. Sequence and phylogenetic analyses of the full-length cDNA encoding B. glabrata peroxiredoxin

From the albumen gland library of the LAC2 snail as mentioned above, a partial cDNA insert (666 bp) with sequence similarity to thioredoxin peroxidase but with an ORF lacking the 5′end of 31 amino acids (Tpx- GenBank Accession No. AY026258) was identified [17]. Subsequently, 5′ RACE reactions yielded the missing 5′ end of the gene and this is denoted by a horizontal arrow below the multiple sequence alignment shown in Fig. 5A. Gene-specific primers designed based on the original, partial ORF and the 5′ RACE product yielded the full-length ORF now referred to as BgPrx4. BgPrx4 was cloned and sequenced from resistant (BS-90), non-susceptible (LAC2), and susceptible snails (NMRI and M-line). Nucleotide sequence analyses confirmed that all strains expressed a thiol-specific antioxidant enzyme, peroxiredoxin (Prx) (also known as thioredoxin peroxidase [TPx ]). Constructs from the four snail stocks were completely sequenced in both directions multiple times (×3). While cDNAs from BS-90, M-line and LAC2 snails each contained a 753 bp sequence that encoded a protein of 250 amino acids (28 kDa), cDNAs derived from NMRI snails were of two forms, the same 753 bp sequence seen in both the resistant and susceptible stocks and a second shorter sequence of 516 bp encoding a smaller peptide of 171 amino acids (19 kDa). In the various constructs, we detected 7 single nucleotide polymorphisms (SNPs), with two resulting in an amino acid change (amino acid 119 was either a lysine or glutamic acid and amino acid 217 was either a valine or methionine). Multiple sequence alignment of the deduced amino acid sequence of the snail enzyme (BgPrx4) to that of the parasites S. mansoni, S. japonicum and the vertebrates human, mouse and rat showed the peroxiredoxins to be highly conserved among snails, humans and schistosomes [17]. The inferred amino acid sequences for the five full-length ORFs (see section 2.8 for GenBank accession numbers) from BS-90, LAC2, M-line and NMRI snail stocks including the second smaller sequence found in the NMRI snail, (δNMRI) and the original partial B. glabrata Tpx are aligned (Fig. 5A), in which the numbering system represents the amino acid position of the first full length sequence in the alignment, i.e. the BS-90 stock of B. glabrata. The variant NMRI BgPrx4 sequence (δNMRI) possesses a large deletion (79 amino acids) resulting in a smaller peptide (171 amino acids) compared to the other BgPrxs sequences (250 amino acids), and lacks the peroxidatic cysteine (CP) in the N-terminus. The longer sequences show this highly conserved peroxidatic cysteine (CP) in the N-terminus in addition to the resolving cysteine (CR) in the C-terminal arm thus indicating that these sequences are “2-Cys peroxiredoxins” [48]. Deprotonation of the catalytic cysteine thiol is facilitated by H-bonding of the threonine or serine hydroxyl group, and the positive charge of the arginine side chain that together form the invariant active site residues which are shown in Fig. 5A (bold uppercase “T” and “R” and highlighted “•”). Like the mosquito and Drosophila 2-cys peroxiredoxins, this BgPrx contains the conserved GG(V/I/L)G-(X)n-YF (Fig. 5A, shaded in gray) sequence that is present in Prxs sensitive to inactivation by hyperoxidation [48]. All sequences also contain a signal peptide and the first 21 amino acids encompass the highly hydrophobic signal sequence that is present in secretory proteins. The arrow between amino acids 20 and 21 denotes the putative cleavage site of the signal peptide. An unrooted, phylogenetic analysis of this BgPrx sequence revealed a closer evolutionary relationship between the vertebrate orthologs and the snail in contrast to the parasite [17].

Figure 5
A) Alignment of the deduced amino acid sequences of peroxiredoxins (BgPrx4) from the snail B. glabrata The amino acid sequences of the BgPrx4 from the individual snail stocks BS-90 (Acc. No. ...

In metazoans Prxs are typically encoded by multiple genes e.g. chicken and Drosophila have 4 and 5 different genes, respectively. To ascertain if B. glabrata is consistent in this regard and to investigate possible orthologs between potential molluscan Prx genes and the more fully characterized mammalian genes, we identified 14 B. glabrata EST sequences from GenBank with annotation that included ‘thioredoxin peroxidase’ or ‘peroxiredoxin’. Using Sequencher (Gene Codes Corporation, Ann Arbor, MI), these were assembled, yielding 4 non-redundant contigs (A, B, C and D) each encoding the peroxiredoxin active site motifs (data not shown). For assignment of contig names for members of gene families in a non-model species such as the snail we decided to use the human database as the benchmark for the assignment of names (for details see section 2.8). Phylogenetic analyses of the various contigs by means of MEGA4 [42] show that the sequences we report in this study are orthologs of human PRDX4 (Figure 5B). Accordingly, the sequence reported in this paper and one of the 4 EST contigs identified from GenBank (data not shown) is named BgPrx4. Another of the B. glabrata contigs is orthologous (99% - 100% certainty after 1000 iterations of bootstrap analyses) to human PRDX6 (not shown), and the two remaining B. glabrata contigs, while they are clearly 2-Cys Prxs, are of uncertain orthologies. When the three unnamed B. glabrata genes represented by the contigs are fully sequenced, definitive names can be assigned on the basis of evolutionary relationships with mammalian genes.

3.6. BgPrx4 protein expression varies between tissues and through time pre- and post exposure to S. mansoni

Since Western blot analyses using protein extracts prepared from whole snail bodies of either resistant or susceptible snails (with and without infection) failed to reveal differential protein expression of BgPrx (data not shown), we therefore chose, based on our earlier results from real-time RT-PCR studies, to look for any changes in the protein expression profiles using, instead, specific tissues (hepatopancreas and albumen glands). Based on several experiments to assess variations in this enzyme between individual resistant (BS-90) and susceptible (NMRI) snails before and after infection, a representative blot is shown in Figure 6 (A and B). Hepatopancreas and albumen gland tissues were dissected from all individual snails pre- (0 h) and post- exposure (5 h and 24 h) to miracidia. Recombinant BgPrx4 protein was included in the analysis as positive control (lane 1, Figs. 6A and B). The molecular size of the recombinant protein was ~ 28 kDa (including the 6-His-tag) while the native protein from the tissues expressed a slightly higher molecular size product of ~ 29-30 kDa, probably due to post-translational modifications. In the hepatopancreases (Fig. 6A) from two individual unexposed resistant BS-90 snails there was a low level of expression (0 h) followed by up-regulation at both 5 h and 24 h post- exposure. In the same tissue (hepatopancreas) of individual, susceptible NMRI snails, we detected some individual variation in basal enzyme levels but unlike in the resistant snail, there was no increase during the early stage of infection (5h). However, an increase was evident in both individual susceptible snails analyzed later (24 h) during infection.

Figure 6
Western blot analysis of B. glabrata protein expression

Western blot analyses of the albumen gland extracts (Fig 6B) indicated a different pattern of protein expression. In the BS-90 snails there appeared to be only a marginal increase in expression compared to levels detected in the hepatopancreas at both early (5h) and late (24 h) time point post-exposure. In the susceptible NMRI snails however there appeared to be a higher basal level of enzyme expression in the albumen gland compared to the constitutive level of expression found in the same gland of resistant snails. Interestingly, this higher basal level of protein expression in the susceptible snails was down -regulated with parasite exposure (5 h and 24 h).

3.7. Functional analysis of the B. glabrata recombinant peroxiredoxin

Steady state kinetic analysis of the recombinant BgPrx protein indicated that the enzyme has a wide substrate range and is active with H2O2 and with model lipid hydroperoxides (cumene hydroperoxide and tertiary butyl hydroperoxide) (Fig. 7 and Table 1). Somewhat unusually, B. glabrata Prx is active with both thioredoxin and glutathione and is indeed slightly more active with glutathione than with thioredoxin. The apparent Kms for the biological substrates thioredoxin and glutathione are in the range for the expected cellular concentrations of these two important thiol reductants of low micromolar and low millimolar, respectively (Table 1). The apparent catalytic rates (kcat/Km) for BgPrx (0.27 – 5.4 × 104 M-1 s-1) are similar to if slightly lower than those seen for Prx from other organisms (~105 M-1 s-1) and, as expected, significantly lower than those of GPx (~108 M-1 s-1) and catalase (~106 M-1 s-1) [49].

Figure 7
Specific activities of recombinant Biomphalaria glabrata peroxiredoxin
Table 1
Apparent saturation kinetic constants for B. glabrata peroxiredoxin

4. Discussion

Peroxiredoxins comprise a family of ubiquitous peroxidases that play important roles as antioxidant enzymes and in cell signaling [49, 50]. They have been described in a variety of organisms [19, 22, 49, 51-53] in which they can protect cells from a variety of oxidative and nitrosative stress challenges. They are also involved in redox balance and signal transduction pathways that use hydrogen peroxide as a second messenger, and can affect phosphorylation, transcriptional regulation and apoptosis (48, 49, 54-56). They are often present in abundant quantities since they have relatively lower catalytic activities compared to catalases and glutathione peroxidases [49]. While both ROS and RNS are produced to defend hosts against pathogens, both can also inflict self-damage within the host [57].

Here, we have identified and characterized the cDNA sequence containing the full-length ORF for BgPrx4 encoding a peroxiredoxin in B. glabrata, a snail host of S. mansoni. Regulation of this important enzyme was also evaluated following parasite infection of resistant and susceptible snails at both RNA and protein levels. As scavengers of H2O2, these enzymes are pivotal in the varied pathways involved in reactive oxygen species (ROS) detoxification. In the hemolymph of another snail host of this parasite, B. alexandrina, the free radical scavengers, catalase and glutathione peroxidase (GPx), were found to be higher in the hemolymph of individual snails that were more resistant to infection, while superoxide dismutase was lower in those snails susceptible to infection [58]. These enzymes varied in expression in both resistant and susceptible B. alexandrina snails after infection. In the present study, the abundance of transcripts in resistant and susceptible B. glabrata whole, juvenile snails (with and without exposure) (Fig. 4), while not identical to the amount of the enzyme in the hepatopancreas (Fig. 6A ), showed the same general trend - infection in the resistant BS-90 snail triggered up-regulation of both RNA and protein expression during the early infection phase (5 h) followed by a decrease at 24 h. In contrast, susceptible NMRI snails infected for the same period showed 2-fold up-regulation of RNA but no discernable change in protein (especially in the hepatopancreas) within the early stages (5-10 h) of infection, followed by further up-regulation at 24 h. However, the protein expression profile in the albumen gland (with infection) within the same period (Fig. 6 B) differed from that seen by real time RT-PCR.

Thus far, while Northern blot analysis (Fig. 2) has revealed the occurrence of four putative transcription isoforms corresponding to B. glabrata Prx, sequence analysis of cDNAs reverse transcribed from mRNA (from the 4 different snail stocks) have shown only two diverse forms of BgPrx4 (Fig. 5A), one of 753 bp (250 amino acids) and the other of 516 bp (171 amino acids). Paradoxically, despite this degree of diversity at the RNA level, multiple-sized protein products were not observed in either the hepatopancreas or albumen gland protein extracts of both NMRI and BS-90 snails, indicating that the multiple transcription isoforms observed in the Northern blot might correspond to alternatively spliced transcripts that are not translated but may be involved in regulation. A similar phenomenon has been reported for the Drosophila peroxiredoxin I (dPrx I) ortholog where there are two alternatively spliced transcripts containing distinct 5′ UTRs (Ia and Ib) that leads to an identical coding sequence for a single protein product (59). In a study of the human neuronal nitric oxide synthetase (nNOS) that is encoded by 5 different transcription isoforms, it has been shown that while they share an identical coding sequence they differ in the 5′ mRNA leader sequence. Elaborate splicing patterns that involve alternatively spliced leader exons and exon skipping have been superimposed on this diversity (60). Likewise, the human peroxiredoxin 5 (PRDX5) also has alternative splice variant transcripts with no corresponding proteins. Although the single coding sequence is in frame with the two ATGs of the alternative splice forms, no evidence of translation was seen in Western blots. In fact, attempts at expressing these shorter proteins resulted in insoluble forms of proteins due to misfolding and are in agreement with the absence of expression of these proteins in vivo. It is thought that the complexity of regulation of the PRDX5 gene and the presence of variable mRNA sequences might be associated with pathological situations. Such splicing variants have also been shown in baboons and African green monkeys, and thus far there is no evidence of translation of these primate mRNA variants. It has been speculated that the splice variants of the PRDX5 could be involved in gene regulation and have been predicted to have stable secondary structures that could induce specific post-transcriptional gene silencing (61). Furthermore, extensive diversification of genes of B. glabrata, for example the Ig superfamily has also been described (63). We plan to express the shorter ORF (516 bp) of BgPrx4, if possible, to ascertain whether or not this smaller version is functional. Typically, as stated above, Prxs have been shown to be multigenic in a variety of organisms but in this study we have shown that BgPrx4 exists as a single copy gene. We have recently further validated the single-copy character of BgPrx4 in this snail by physically mapping a corresponding BAC clone onto metaphase chromosome spreads prepared from the Bge snail embryonic cell line [64].

Schistosomes have been shown to express elevated levels of antioxidant enzymes in the presence of hemocytes from susceptible snails while hemocytes from resistant snails may interfere with this detoxification process by down-regulating the schistosome's antioxidant enzymes, thereby enabling parasite killing [65]. In the snail, the enzyme was expressed in a tissue-specific manner (Fig. 4). Thus, Southern blots of RT-PCR products (Figs. 3A and B) indicated abundant transcripts of BgPrx4 in the albumen gland, hepatopancreas, ovotestis and cerebral ganglia tissue. Its apparently variable expression in hemocytes remains enigmatic; further experiments will be needed to clarify this observation.

Molecular characterization and sequence analysis of the B. glabrata peroxiredoxin described in this work implies that it is a homolog of human PRDX4, and that it is properly classified as a 2-cys peroxiredoxin because of the presence of 2 cysteines, one preceding the first alpha helix and the other on the C-terminal tail.

Prior to obtaining the complete sequence at the 5′ end of the ORF of BgPrx4, we had sequenced a 666 bp insert cDNA from an albumen gland library of the LAC2 stock of snails with sequence similarity to thioredoxin peroxidase (Tpx) [17]. Despite missing the first 31 amino acids at the N-terminus, the inferred protein had all the elements of a functional enzyme (the peroxidatic and resolving cysteines, invariant active site residues threonine and arginine, etc). To resolve the sulfenic acid intermediate formed upon reduction of peroxide substrates typical 2-Cys Prxs function as homodimers and form an intermolecular disulfide bond between the peroxidatic cysteine of one subunit and the resolving cysteine of the other subunit which can then be reduced by thioredoxin. Thus in 2-Cys Prxs, the CP-SOH and CR-SH react and form a disulfide (CP-S-S-CR). 2-Cys Prxs have been further subdivided into either “typical” (the CP-SOH reacts with the CR residue located in the C-terminal arm from the other subunit of a homodimer) or “atypical” (the CR residue resides within the same subunit) types depending on the location of the CR residue [66-68]. Typical 2-Cys Prxs function as homodimers, utilizing a unique intermolecular redox-active disulfide center for the reduction of peroxides. The functional homodimer is formed through beta strands at one edge of the monomer (B-type interface). Typical 2-cys Prx also form stable decamer (pentamer of dimers) structures. Thus, this sequence also shows the conserved regions I (loop-helix active-site motif) and II that together play a role in decamer formation, consistent with its being a typical 2-Cys peroxiredoxin. We therefore used this partial sequence to express a recombinant protein and later obtained the complete ORFs from the various snail stocks (Fig. 5A). The recombinant BgPrx4 (rBgPrx4) protein (~28 kDa) was used both to produce mouse antibodies and to characterize its activity. Kinetic analysis of the rBgPrx4 protein indicated that the enzyme has a wide substrate range for peroxides including H2O2 (Table 1). An unusual attribute of BgPrx4 is its ability to use both thioredoxin and glutathione (Fig. 7 and Table 1). This ability to utilize both thiol reductants is also seen with the schistosome Prx [22]. The preference we observed for glutathione may be the result of using a heterologous (bacterial) thioredoxin in the assay, for which the snail Prx may have a lower affinity; confirmation would depend on conducting the assays with Biomphalaria thioredoxin. The Kms for the biological substrates are in the range for the expected cellular concentrations and the catalytic activities are similar to if slightly lower than those seen for Prx from other organisms [49]. This could be due to improper protein folding due to the missing 31 amino acids at the N-terminus of the rBgPrx4.

In conclusion, while it remains to be seen how peroxiredoxins may influence resistance and susceptibility in B. glabrata to invading S. mansoni, our studies reveal that the structure of the enzyme is similar in resistant and susceptible snails but that the induction of these enzymes is both time- and tissue-specific at both RNA and protein levels, with higher levels of expression in the resistant compared to the susceptible snail. The presence of variant forms of the transcript but a single, expressed protein product resembling that which has previously been observed for drosophila and human peroxiredoxin orthologs indicates that a complex transcriptional/post-transcriptional regulation and splicing mechanism may also exist for BgPrx4 in B. glabrata. Thus, early higher expression of BgPrx4 RNA and its corresponding protein seems to be a hallmark of snails that are resistant to parasite infection while lower and slower levels of expression are observed in susceptible snails.

Acknowledgments

This work was funded by NIH-R01 AI63480-01A1. We wish to thank Drs. Fred Lewis and Peter FitzGerald for their encouragement, support in the experimental design, and for their helpful suggestions with the writing of this manuscript. Randy Bender is thanked for assembly of the contigs and ideas on nomenclature. Dee Denver and Emilie Dicks are thanked for instruction in phylogenetic analysis using MEGA4.

Footnotes

Note: Nucleotide sequence data reported in this paper are available in GenBank under the accession numbers: BgPrx4-BS-90: FJ176938; BgPrx4-LAC2: FJ176940; BgPrx4-M-line: FJ176941; BgPrx4-NMRI: FJ176942; BgPrx4-δNMRI: FJ176939

Publisher's Disclaimer: This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final citable form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.

References

1. King CH, Dickman K, Tisch DJ. Reassessment of the cost of chronic helminthic infection: a meta-analysis of disability-related outcomes in endemic schistosomiasis. Lancet. 2005;365:1561–1569. [PubMed]
2. King CH, Sturrock RF, Kariuki HC, Hamburger J. Transmission control for schistosomiasis - why it matters now. Trends Parasitol. 2006;22:575–582. Epub 2006 Oct 9. [PubMed]
3. Richards CS, Shade PC. The genetic variation of compatibility in Biomphalaria glabrata and Schistosoma mansoni. J Parasitol. 1987;73:1146–1151. [PubMed]
4. Lewis FA, Patterson CN, Grzywacz C. Parasite-susceptibility phenotypes of F1 Biomphalaria glabrata progeny derived from interbreeding Schistosoma mansoni-resistant and -susceptible snails. Parasitol Res. 2003;89:98–101. Epub 2002 Sep 5. [PubMed]
5. Knight M, Miller AN, Geoghagen NSM, Lewis FA, Kerlavage AR. Expressed sequence tags (ESTs) of Biomphalaria glabrata, an intermediate snail host of Schistosoma mansoni: use in the identification of RFLP markers. Malacologia. 1998;29:175–182.
6. Davids BJ, Wu XJ, Yoshino TP. Cloning of a beta integrin subunit cDNA from an embryonic cell line derived from the freshwater mollusc, Biomphalaria glabrata. Gene. 1999;228:213–223. [PubMed]
7. Miller AN, Raghavan N, FitzGerald PC, Lewis FA, Knight M. Differential gene expression in haemocytes of the snail Biomphalaria glabrata: effects of Schistosoma mansoni infection. Int J Parasitol. 2001;31:687–696. [PubMed]
8. Raghavan N, Miller AN, Gardner M, FitzGerald PC, Kerlavage AR, Johnston DA, Lewis FA, Knight M. Comparative gene analysis of Biomphalaria glabrata hemocytes pre- and post-exposure to miracidia of Schistosoma mansoni. Mol Biochem Parasitol. 2003;126:181–191. [PubMed]
9. Vergote D, Bouchut A, Sautiere PE, Roger E, Galinier R, Rognon A, Coustau C, Salzet M, Mitta G. Characterisation of proteins differentially present in the plasma of Biomphalaria glabrata susceptible or resistant to Echinostoma caproni. Int J Parasitol. 2005;35:215–224. [PubMed]
10. Lockyer AE, Spinks J, Noble LR, Rollinson D, Jones CS. Identification of genes involved in interactions between Biomphalaria glabrata and Schistosoma mansoni by suppression subtractive hybridization. Mol Biochem Parasitol. 2007;151:18–27. [PMC free article] [PubMed]
11. Bouchut A, Coustau C, Gourbal B, Mitta G. Compatibility in the Biomphalaria glabrata/Echinostoma caproni model: new candidate genes evidenced by a suppressive subtractive hybridization approach. Parasitol. 2007;134:575–588. [PubMed]
12. Goodall CP, Bender RC, Broderick EJ, Bayne CJ. Constitutive differences in Cu/Zn superoxide dismutase mRNA levels and activity in hemocytes of Biomphalaria glabrata (Mollusca) that are either susceptible or resistant to Schistosoma mansoni (Trematoda) Mol Biochem Parasitol. 2004;137:321–328. [PubMed]
13. Raghavan N, Knight M. The snail (Biomphalaria glabrata) genome project. Trends Parasitol. 2006;22:148–151. [PubMed]
14. Hahn UK, Bender RC, Bayne CJ. Production of reactive oxygen species by hemocytes of Biomphalaria glabrata: carbohydrate-specific stimulation. Dev Comp Immunol. 2000;24:531–541. [PubMed]
15. Hahn UK, Bender RC, Bayne CJ. Killing of Schistosoma mansoni sporocysts by hemocytes from resistant Biomphalaria glabrata: role of reactive oxygen species. J Parasitol. 2001;87:292–299. [PubMed]
16. Bayne CJ, Hahn UK, Bender RC. Mechanisms of molluscan host resistance and of parasite strategies for survival. Parasitol. 2001;123(Suppl):S159–67. [PubMed]
17. Knight M, Raghavan N. Parasite Effects on the Snail Host Transcriptome. In: Maule AD, Marks NJ, editors. Parasitic Flatworms: Molecular Biology, Biochemistry, Immunology and Physiology. CABI; Oxfordshire, UK: 2006. pp. 228–242.
18. Gutteridge JM, Halliwell B. Free radicals and antioxidants in the year 2000. A historical look to the future. Ann N Y Acad Sci. 2000;899:136–147. [PubMed]
19. Rhee SG, Chae HZ, Kim K. Peroxiredoxins: a historical overview and speculative preview of novel mechanisms and emerging concepts in cell signaling. Free Radic Biol Med. 2005;38:1543–1552. Epub 2005 Mar 24. [PubMed]
20. Jacob C, Knight I, Winyard PG. Aspects of the biological redox chemistry of cysteine: from simple redox responses to sophisticated signalling pathways. Biol Chem. 2006;387:1385–1397. [PubMed]
21. Chae HZ, Robison K, Poole LB, Church G, Storz G, Rhee SG. Cloning and sequencing of thiol-specific antioxidant from mammalian brain: alkyl hydroperoxide reductase and thiol-specific antioxidant define a large family of antioxidant enzymes. Proc Natl Acad Sci U S A. 1994;91:7017–7021. [PMC free article] [PubMed]
22. Sayed AA, Williams DL. Biochemical characterization of 2-Cys peroxiredoxins from Schistosoma mansoni. J Biol Chem. 2004;279:26159–26166. Epub 2004 Apr 9. [PubMed]
23. Sayed AA, Cook SK, Williams DL. Redox balance mechanisms in Schistosoma mansoni rely on peroxiredoxins and albumin and implicate peroxiredoxins as novel drug targets. J Biol Chem. 2006;281:17001–17010. Epub 2006 Apr 10. [PubMed]
24. Cooper LA, Richards CS, Lewis FA, Minchella DJ. Schistosoma mansoni: relationship between low fecundity and reduced susceptibility to parasite infection in the snail Biomphalaria glabrata. Exp Parasitol. 1994;79:21–28. [PubMed]
25. Sullivan JT, Richards CS. Schistosoma mansoni, NIH-SM-PR-2 strain, in susceptible and nonsusceptible stocks of Biomphalaria glabrata: comparative histology. J Parasitol. 1981;67:702–708. [PubMed]
26. Paraense WL, Correa LR. Variation in susceptibility of populations of Australorbis glabratus to a strain of Schistosoma mansoni. Rev Inst Med Trop Sao Paulo. 1963;5:15–22. [PubMed]
27. Newton J. The establishment of a strain of Australorbis glabratus which combines albinism and high susceptibility to infection with Schistosoma mansoni. J Parasitol. 1955;41:526–528. [PubMed]
28. Goodall CP, Bender RC, Brooks JK, Bayne CJ. Biomphalaria glabrata cytosolic copper/zinc superoxide dismutase (SOD1) gene: association of SOD1 alleles with resistance/susceptibility to Schistosoma mansoni. Mol Biochem Parasitol. 2006;147:207–210. Epub 2006 Mar 9. [PubMed]
29. Raghavan N, Tettelin H, Miller A, Hostetler J, Tallon L, Knight M. Nimbus (BgI): an active non-LTR retrotransposon of the Schistosoma mansoni snail host Biomphalaria glabrata. Int J Parasitol. 2007;37:1307–1318. Epub 2007 Apr 19. [PMC free article] [PubMed]
30. Miller AN, Ofori K, Lewis F, Knight M. Schistosoma mansoni: use of a subtractive cloning strategy to search for RFLPs in parasite-resistant Biomphalaria glabrata. Exp Parasitol. 1996;84:420–428. [PubMed]
31. Knight M, Miller A, Raghavan N, Richards C, Lewis F. Identification of a repetitive element in the snail Biomphalaria glabrata: relationship to the reverse transcriptase-encoding sequence in LINE-1 transposons. Gene. 1992;118:181–187. [PubMed]
32. Dewilde S, Winnepenninckx B, Arndt MH, Nascimento DG, Santoro MM, Knight M, Miller AN, Kerlavage AR, Geoghagen N, Van Marck E, Liu LX, Weber RE, Moens L. Characterization of the myoglobin and its coding gene of the mollusc Biomphalaria glabrata. J Biol Chem. 1998;29(273):13583–13592. [PubMed]
33. Livak KJ, Schmittgen TD. Analysis of relative gene expression data using real-time quantitative PCR and the 2(-Delta Delta C(T)) Method. Methods. 2001;25:402–8. [PubMed]
34. Rice P, Longden I, Bleasby A. EMBOSS: The European Molecular Biology Open Software Suite. Trends in Genetics. 2000;16:276–277. [PubMed]
35. Wilbur WJ, Lipman DJ. Rapid similarity searches of nucleic acid and protein data banks. Proc Natl Acad Sci USA. 1983;80:726–730. [PMC free article] [PubMed]
36. Myers EW, Miller W. Optimal alignments in linear space. Comput Applic Biosci. 1988;4:11–17. [PubMed]
37. Altschul SF, Gish W, Miller W, Myers EW, Lipman DJ. Basic local alignment search tool. J Mol Biol. 1990;215:403–410. [PubMed]
38. Marchler, Mullokandov M, Shoemaker BA, Simonyan V, Song JS, Thiessen PA, Yamashita RA, Yin JJ, Zhang D, Bryant SH. CDD: a Conserved Domain Database for protein classification. Nucleic Acids Research. 2005;33:D192–6. [PMC free article] [PubMed]
39. Zdobnov EM, Apweiler R. InterProScan--an integration platform for the signature-recognition methods in InterPro. Bioinformatics. 2001;17:847–848. [PubMed]
40. Rawlings ND, Morton FR, Barrett AJ. MEROPS: the peptidase database. Nucl Acids Res. 2006;34:D270–2. [PMC free article] [PubMed]
41. Bendtsen JD, Nielsen H, von Heijne G, Brunak S. Improved prediction of signal peptides: SignalP 3.0. J Mol Biol. 2004;340:783–795. [PubMed]
42. Tamura K, Dudley J, Nei M, Kumar S. MEGA4: Molecular Evolutionary Genetics Analysis (MEGA) software version 4.0. Mol Biol Evol. 2007;24:1596–1599. Epub 2007 May 7. [PubMed]
43. Ghosh I, Eisinger SW, Raghavan N, Scott AL. Thioredoxin peroxidases from Brugia malayi. Mol Biochem Parasitol. 1998;91:207–220. [PubMed]
44. Smith PK, Krohn RI, Hermanson GT, Mallia AK, Gartner FH, Provenzano MD, Fujimoto EK, Goeke NM, Olson BJ, Klenk DC. Measurement of protein using bicinchoninic acid. Anal Biochem. 1985;150:76–85. [PubMed]Anal Biochem. 1987;163:279. Erratum in.
45. Towbin H, Staehelin T, Gordon J. Electrophoretic transfer of proteins from polyacrylamide gels to nitrocellulose sheets: procedure and some applications. Proc Natl Acad Sci USA. 1979;76:4350–4354. [PMC free article] [PubMed]
46. Raghavan N, Freedman DO, Fitzgerald PC, Unnasch TR, Ottesen EA, Nutman TB. Cloning and characterization of a potentially protective chitinase-like recombinant antigen from Wuchereria bancrofti. Infect Immun. 1994;62:1901–1908. [PMC free article] [PubMed]
47. Adema CM, Luo MZ, Hanelt B, Hertel LA, Marshall JJ, Zhang SM, DeJong RJ, Kim HR, Kudrna D, Wing RA, Soderlund C, Knight M, Lewis FA, Caldeira RL, Jannotti-Passos LK, Carvalho Odos S, Loker ES. A bacterial artificial chromosome library for Biomphalaria glabrata, intermediate snail host of Schistosoma mansoni. Mem Inst Oswaldo Cruz. 2006;101 1:167–177. [PubMed]
48. Wood ZA, Poole LB, Karplus PA. Peroxiredoxin evolution and the regulation of hydrogen peroxide signaling. Science. 2003;300:650–653. [PubMed]
49. Hofmann B, Hecht HJ, Flohe L. Peroxiredoxins. Biol Chem. 2002;383:347–364. [PubMed]
50. Bryk R, Lima CD, Erdjument-Bromage H, Tempst P, Nathan C. Metabolic enzymes of mycobacteria linked to antioxidant defense by a thioredoxin-like protein. Science. 2002;295:1073–1077. Epub 2002 Jan 17. [PubMed]
51. Chae HZ, Kim IH, Kim K, Rhee SG. Cloning, sequencing, and mutation of thiol-specific antioxidant gene of Saccharomyces cerevisiae. J Biol Chem. 1993;268:16815–16821. [PubMed]
52. McGonigle S, Dalton JP, James ER. Peroxidoxins: a new antioxidant family. Parasitol Today. 1998;14:139–145. [PubMed]
53. Peterson TM, Luckhart S. A mosquito 2-Cys peroxiredoxin protects against nitrosative and oxidative stresses associated with malaria parasite infection. Free Radic Biol Med. 2006;40:1067–1082. Epub 2005 Nov 22. [PMC free article] [PubMed]
54. Veal EA, Findlay VJ, Day AM, Bozonet SM, Evans JM, Quinn J, Morgan BA. A 2-Cys peroxiredoxin regulates peroxide-induced oxidation and activation of a stress-activated MAP kinase. Mol Cell. 2004;15:129–139. [PubMed]
55. Choi J, Choi S, Choi J, Cha MK, Kim IH, Shin W. Crystal structure of Escherichia coli thiol peroxidase in the oxidized state: insights into intramolecular disulfide formation and substrate binding in atypical 2-Cys peroxiredoxins. J Biol Chem. 2003;278:49478–49486. Epub 2003 Sep 23. [PubMed]
56. Harder S, Bente M, Isermann K, Bruchhaus I. Expression of a mitochondrial peroxiredoxin prevents programmed cell death in Leishmania donovani. Eukaryot Cell. 2006;5:861–870. [PMC free article] [PubMed]
57. Fang FC. Antimicrobial reactive oxygen and nitrogen species: concepts and controversies. Nat Rev Microbiol. 2004;2:820–832. [PubMed]
58. Mahmoud AH, Rizk MZ. Free radical scavengers in susceptible/resistant Biomphalaria alexandrina snails before and after infection. Comp Biochem Physiol C Toxicol Pharmacol. 2004;138:523–530. [PubMed]
59. Chen CW, Lin TY, Chen TC, Juang JL. Distinct translation regulation by two alternative 5′UTRs of a stress-responsive protein-dPrx I. J Biomed Sci. 2005;12:729–739. [PubMed]
60. Wang Y, Newton DC, Miller TL, Teichert AM, Phillips MJ, Davidoff MS, Marsden PA. RNA diversity has profound effects on the translation of neuronal nitric oxide synthase. Proc Natl Acad Sci USA. 1999;96:12150–12155. [PMC free article] [PubMed]
61. Nguyên-Nhu NT, Berck J, Clippe A, Duconseille E, Cherif H, Boone C, Van der Eecken V, Bernard A, Banmeyer I, Knoops B. Human peroxiredoxin 5 gene organization, initial characterization of its promoter and identification of alternative forms of mRNA. Biochim Biophys Acta. 2007;769:472–483. [PubMed]
62. Georgieva T, Dunkov BC, Harizanova N, Ralchev K, Law JH. Iron availability dramatically alters the distribution of ferritin subunit messages in Drosophila melanogaster. Proc Natl Acad Sci U S A. 1999;96:2716–2721. [PMC free article] [PubMed]
63. Zhang SM, Adema CM, Kepler TB, Loker ES. Diversification of Ig superfamily genes in an invertebrate. Science. 2004;305:251–254. [PubMed]
64. Odoemelam E, Raghavan N, Miller A, Bridger JM, Knight M. Revised karyotyping and gene mapping of the Biomphalaria glabrata embryonic (Bge) cell line. Int J Parasitol. 2009;39:675–681. Epub 2008 Dec 24. [PMC free article] [PubMed]
65. Zelck UE, Von Janowsky B. Antioxidant enzymes in intramolluscan Schistosoma mansoni and ROS-induced changes in expression. Parasitology. 2004;128:493–501. [PubMed]
66. Hirotsu S, Abe Y, Okada K, Nagahara N, Hori H, Nishino T, Hakoshima T. Crystal structure of a multifunctional 2-Cys peroxiredoxin heme-binding protein 23 kDa/proliferation-associated gene product. Proc Natl Acad Sci USA. 1999;96:12333–12338. [PMC free article] [PubMed]
67. Seo MS, Kang SW, Kim K, Baines IC, Lee TH, Rhee SG. Identification of a new type of mammalian peroxiredoxin that forms an intramolecular disulfide as a reaction intermediate. J Biol Chem. 2000;275:20346–20354. [PubMed]
68. Wood ZA, Poole LB, Hantgan RR, Karplus PA. Dimers to doughnuts: redox-sensitive oligomerization of 2-cysteine peroxiredoxins. Biochemistry. 2002;41:5493–5504. [PubMed]
PubReader format: click here to try

Formats:

Related citations in PubMed

See reviews...See all...

Cited by other articles in PMC

See all...

Links

Recent Activity

Your browsing activity is empty.

Activity recording is turned off.

Turn recording back on

See more...