Precise Timing of Expression of a Plasmodium falciparum-derived Transgene in Plasmodium berghei Is a Critical Determinant of Subsequent Subcellular Localization*

Clemens H. M. Kocken, Anne Marie van der Wel, Martin A. Dubbeld, David L. Narum, Franciscus M. van de RijkeDagger , Geert-Jan van Gemert§, Xander van der Linde, Lawrie H. Bannisterparallel , Chris Janse**, Andrew P. Waters**, and Alan W. ThomasDagger Dagger

From the Department of Parasitology, Biomedical Primate Research Centre, Lange Kleiweg 157, 2280 GJ Rijswijk, The Netherlands, the Dagger  Leiden University Medical Center, Department of Molecular Cell Biology, Laboratory of Cytochemistry and Cytometry, Wassenaarseweg 72, 2333 AL Leiden, The Netherlands, the § Department of Medical Microbiology, University of Nijmegen, Geert Groote Plein 24, 6500 HB Nijmegen, The Netherlands, the  Department of Anatomy, The Medical School, Guy's Hospital, London SE1 9RT, Great Britain, and the ** Department of Parasitology, Leiden University, Wassenaarseweg 62, 2300 RC Leiden, The Netherlands

    ABSTRACT
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Abstract
Introduction
Materials & Methods
Results
Discussion
References

The development of transfection technology for malaria parasites holds significant promise for a more detailed characterization of molecules targeted by vaccines or drugs. One asexual blood stage vaccine candidate, apical membrane antigen-1 (AMA-1) of merozoite rhoptries has been shown to be the target of inhibitory, protective antibodies in both in vitro and in vivo studies. We have investigated heterologous (trans-species) expression of the human malaria Plasmodium falciparum AMA-1 (PF83/AMA-1) in the rodent parasite Plasmodium berghei. Transfected P. berghei expressed correctly folded and processed PF83/AMA-1 under control of both pb66/ama-1 and dhfr-ts promoters. Timing of expression was highly promoter-dependent and was critical for subsequent subcellular localization. Under control of pb66/ama-1, PF83/AMA-1 expression and localization in P. berghei was limited to the rhoptries of mature schizonts, similar to that observed for PF83/AMA-1 in P. falciparum. In contrast the dhfr-ts promoter permitted PF83/AMA-1 expression throughout schizogony as well as in gametocytes and gametes. Localization was aberrant and included direct expression at the merozoite and gamete surface. Processing from the full-length 83-kDa protein to a 66-kDa protein was observed not only in schizonts but also in gametocytes, indicating that processing could be mediated outside of rhoptries by a common protease. Trans-species expressed PF83/AMA-1 was highly immunogenic in mice, resulting in a response against a functionally critical domain of the molecule.

    INTRODUCTION
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Abstract
Introduction
Materials & Methods
Results
Discussion
References

The protozoan parasite Plasmodium falciparum is a causative agent of malaria, one of the major human infectious diseases. In the search for new methods to combat the disease, the advent of transfection technology for Plasmodium species is critical, because it offers the opportunity to relate genotype to phenotype, and this will permit a more rational design of vaccines and drugs. To date, stable episomal maintenance of plasmid DNA introduced into Plasmodium has been reported (1-3) as well as site-directed integration of DNA into the parasite genome (4-8). This technology also offers the possibility to dissect the thus far poorly characterized Plasmodium promoter function (9-11) and study the relation between the tightly controlled timing of expression and the subcellular trafficking and localization of stage-specific proteins. Trans-species expression of malarial antigens will allow targeted development of attenuated parasite vaccines and opens possibilities for complementation of otherwise detrimental integration into essential genes. Apical membrane antigen-1 (AMA-1)1 is an attractive candidate for such studies, because it appears to be intimately involved in red cell invasion (12). Expression and post-translational N-terminal proteolytic cleavage of AMA-1 are restricted to the final stages of schizogony (13), during which the protein is localized within the neck of the rhoptry, an apical secretory organelle of the merozoite involved in red cell invasion (14). AMA-1 is a major candidate for inclusion in a malaria blood stage vaccine following in vivo experiments in nonhuman primates and rodents showing that AMA-1 can induce protective immune responses (15-17).

Here we report for the first time in a malaria parasite the development of drug-selectable trans-species expression of a second gene (in addition to the selectable marker) and its use to investigate the role of the promoter on subcellular localization of the trans-species expressed protein. P. falciparum AMA-1 (PF83/AMA-1) expression in the rodent malaria Plasmodium berghei was driven by the stage-specific P. berghei AMA-1 promoter (pb66/ama-1) or the more constitutive P. berghei dihydrofolate reductase-thymidylate synthase (dhfr-ts) promoter. The type of promoter control determined the timing and subsequent subcellular localization of PF83/AMA-1, which markedly differed between the two promoters. In addition, the trans-species expressed protein proved to be highly immunogenic in mice, resulting in antibodies to a critical functional determinant of PF83/AMA-1.

    MATERIALS AND METHODS
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Abstract
Introduction
Materials & Methods
Results
Discussion
References

DNA Constructs

The selection cassette controlling Toxoplasma gondii DHFR-TS expression and the pUC19 backbone (element pDB.DTm.DB., nomenclature following Ref. 18) were common to all constructs used for transfection and were as described previously for transfection of Plasmodium knowlesi (3) except that Tg dhfr-ts (GenBankTM accession number L08489) was conservatively mutagenized (pAlter kit, Promega, Madison, WI) to remove EcoRI and KpnI sites by use of oligonucleotides ToxM1 CCATGAAGAGTTCCAGTAC (base pairs 3722-3741) and ToxM2 CAACGGGGTTCCCTACGAC (base pairs 3064-3083), the altered residue being underlined. Through a series of cloning steps plasmids pDB.DTm.DB./DB.AF.DB. and pDB.DTm.DB./AB.AF.DB. and two plasmids that were identical but for reversed orientation of pf83/ama-1 open reading frame (ORF) (pDB.DTm.DB./DB.alpha AF.DB. and pDB.DTm.DB./AB.alpha AF.DB.) were derived (see Fig. 1). Pf83/ama-1 was base pairs 1-1869 (complete ORF) of P. falciparum 7G8 strain (19). 5' pb66 was a 1.5-kb polymerase chain reaction fragment lying immediately 5' to the pb66/ama-1 ORF that had been amplified using sequence derived from a lambda ZAP P. berghei ANKA genomic library probed with pf83/ama-1. Recombinant DNA manipulations and analyses were performed according to standard procedures (20).

Derivation and Maintenance of Transfected Parasites

P. berghei ANKA clone 15cy1 schizonts derived from infected Wistar rats were electroporated with constructs pDB.DTm.DB./DB.AF.DB., pDB.DTm.DB./AB.AF.DB., or a mixture of pDB.DTm.DB./DB.alpha AF.DB. and pDB.DTm.DB./AB.alpha AF.DB. as previously reported (1) except that cytomix was used (2). Electroporated parasites (2 × 108) were injected intravenously into phenylhydrazine-treated naive Wistar rats, and pyrimethamine treatment was begun (1). 9-10 days later when parasitemias had reached >= 0.5%, 100 µl of blood was transferred intraperitoneally to six Swiss mice, and pyrimethamine pressure maintained was. 4-6 days after infection, when parasitemias had reached 5%, mice were bled by cardiac puncture to provide parasites for DNA analysis and cryopreserved stocks. Parasites for analyses detailed below were derived from Swiss mice that had been infected with cryopreserved parasites and maintained under pyrimethamine pressure.

Analysis of Transfected Parasites

Leukocytes were removed from infected blood (Plasmodipur, Eurodiagnostica, Apeldoorn, The Netherlands) that was then either used directly or cultured for a further 12-24 h in an atmosphere of 5% O2, 5% CO2, 90% N2 (21). Parasite DNA and RNA was isolated (Gentra Systems Inc., Minneapolis, MN) according to the manufacturer's instructions. Western blots following reduced SDS-polyacrylamide gel electrophoresis (Phast-system, 10-15% gradient gel, Amersham Pharmacia Biotech, Uppsala, Sweden) used parasite stages that had been enriched by Nycodenz centrifugation (21) and stored at -80 °C.

For purification of gametocytes, rats were infected with 108 in vitro matured, Nycodenz-purified schizont-infected red cells isolated from an infected rat at 1% parasitemia. 27 h after infection rats were bled, and gametocytes were Nycodenz purified (21).

Rat mAb Development and in Vitro Inhibition of Invasion Assay

The pan-specific AMA-1 rat mAb 28G2dc1 recognizes a linear determinant at the highly conserved C terminus and immunoprecipitates both the full-length 83-kDa and processed 66-kDa forms of PF83/AMA-1; rat mAb 58F8dc1 recognizes a linear determinant in the N-terminal region and only immunoprecipitates the 83-kDa form (13). Additional mAbs were developed from rats that had been immunized with recombinant PF83/AMA-1 (22) essentially as described (13).

For in vitro inhibition of invasion assays, purified IgG was incubated in triplicate with schizont-infected red blood cells at a parasitemia of 0.04% to 0.1% in 96-well flat-bottomed plates (Costar, Cambridge, MA) in a total volume of 100 µl (1.0-1.5% hematocrit) (T0h). After two cycles of invasion (T65h), 25 µl of RPMI 1640 containing 10% human serum, and [3H]hypoxanthine (Amersham International, 's-Hertogenbosch, The Netherlands) was added to each well to yield a final concentration of 20 µCi ml-1. Parasites were harvested (T87h) onto glass fiber filters using a Skatron cell harvester (Suffolk, UK), and [3H]hypoxanthine incorporation was determined by liquid scintillation spectrometry. Parasite growth inhibition, reported as a percentage, was determined as follows: ((mean cpmcontrol - mean cpmexperimental)/mean cpmcontrol) × 100. The cpm for red blood cells alone was subtracted from all averages prior to determining the percentage of inhibition. All analyses of statistical significance were performed by Student's t test.

IFA and Immunoelectron Microscopy

Methanol-fixed thin films were prepared and used for IFA as described previously (13), and in some experiments mAbs that had been directly succinamide-conjugated with fluorophores (Molecular Probes, Leiden, The Netherlands) were used according to the manufacturer's instructions. Slides were mounted in anti-fade (5% (w/v) 1,4-diazobicyclo[2.2.2 octane], 10 mM Tris-HCl, pH 8, 90% glycerol) to which 4,6-diamidino-2-phenylindole (23) at a final concentration of 1.9 µM was added. Photographs were taken with a Photometrics CH250 cooled CCD camera mounted on a Leica DMRXA microscope. Digital images that were generated were all treated identically. IFA on fresh unfixed gametes was performed with a mixture of 28G2dc1, 58F8dc1, and 4G2dc1 mAb culture supernatants on homogenized mid-guts of Anopheles stephensi at various times after they had fed on infected Swiss mice (24). Immunoelectron microscopy was performed on gametocytes and schizonts transfected with PF83/AMA-1 expressed under the P. berghei dhfr-ts promoter. Cells harvested as for IFA were fixed (20 min on ice in 0.1% (v/v) double-distilled glutaraldehyde in RPMI), washed four times in fresh ice-cold RPMI, then dehydrated in a series of ethanols cooled progressively from 0 to -20 °C, infiltrated with LR White Resin overnight, and polymerized at room temperature under indirect ultraviolet light for 48 h (25). Sectioned material was stained using mAb 58F8dc1 at 25 µg ml-1 and secondary goat anti-rat antibodies labeled with 10-nm gold. Grids were post-stained for 2 min in 2% aqueous uranyl acetate. Controls were parasites transfected with pf83/ama-1 ORF in the reverse orientation.

ELISA

Total IgG-- ELISA plates (Greiner, Labortechnik, Solingen, Germany) were coated overnight at +4 °C with 100 ng ml-1 PF83-7G8-1 (22) in phosphate-buffered saline/0.02% NaN3, pH 7.4, and blocked with 3% bovine serum albumin/phosphate-buffered saline. Dilutions of mouse sera in antibody buffer (0.5% bovine serum albumin/phosphate-buffered saline, pH 8.0) were tested in triplicate, and bound IgG was detected by goat anti-mouse IgG coupled to alkaline phosphatase as described previously (26).

Competition ELISA-- ELISA plates were prepared as above. Rat mAb 4G2dc1 was coupled to alkaline phosphatase (Sigma-Aldrich N.V./S.A., Bornem, Belgium) (27). Duplicate mouse sera (diluted 1:100) and mAb 4G2dc1 (30 µg ml-1) in an optimized concentration of alkaline phosphatase coupled 4G2dc1 in antibody buffer were incubated in wells coated with PF83-7G8-1 (90 min, 37 °C). The plates were washed, substrate was added (2 h), and the A405 was determined. Inhibition of 4G2dc1 binding was calculated using the average OD reading for each group of mice relative to the average OD reading for a pool of normal Swiss mouse serum.

Immunization of Mice with Transfected P. berghei

To assess specific antibody production in animals infected with transfected parasites, infected mice received regular pyrimethamine treatment to maintain plasmids in the parasite population. Parasitemia was controlled when it reached 1% by sulfadiazine treatment (10 mg/liter drinking water) for 2-4 days (28) until parasites were barely detectable by Giemsa thin film. Mice were chloroquine-treated after 5 weeks to kill all remaining parasites and allow recovery and were reinfected with the same transfected parasites 3 weeks later (2 × 107 schizonts/mouse intraperitoneally). To counteract bone marrow suppression induced by pyrimethamine, these mice received folinic acid intraperitoneally once per week (400 µg/kg).

    RESULTS
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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Transfected P. berghei Parasites Express PF83/AMA-1-- The rodent malaria P. berghei was transfected with constructs that were designed to express PF83/AMA-1 controlled by two different promoters. The selection cassette was based on the ability to confer resistance to pyrimethamine, and for this an engineered T. gondii dhfr-ts gene was chosen because of its high resistance levels and the reduced likelihood of unwanted homologous integration (3). To allow easier manipulation of the selection cassette T. gondii dhfr-ts was mutagenized to remove EcoRI and KpnI sites. This mutant T. gondii dhfr-ts was flanked by P. berghei dhfr-ts control regions. In addition to the selectable marker cassette, vectors pDB.DTm.DB./AB.AF.DB. (Fig. 1A) and pDB.DTm.DB./DB.AF.DB. (Fig. 1B) respectively employed the pb66/ama-1 promoter or the P. berghei dhfr-ts promoter to control PF83/AMA-1 expression. Transfection of P. berghei schizont-infected red blood cells with these constructs yielded pyrimethamine-resistant parasites. Southern blot, polymerase chain reaction, and plasmid rescue analyses showed that these parasites contained the T. gondii dhfr-ts gene, indicating that the T. gondii DHFR-TS is active in P. berghei and that the mutagenesis of T. gondii dhfr-ts had no detrimental effects on DHFR-TS expression (data not shown).


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Fig. 1.   Plasmid constructs used for the trans-species expression of PF83/AMA-1 in P. berghei. Plasmids contained Tg dhfr-ts controlled by P. berghei dhfr-ts 5' and 3' regions to enable selection of transfected parasites on the basis of pyrimethamine resistance. PF83/AMA-1 expression was under control of a 1.5-kb 5' region of pb66/ama-1 (pDB.DTm.DB./AB.AF.DB.) (A) or a 2.2-kb 5' region of P. berghei dhfr-ts (pDB.DTm.DB./DB.AF.DB.) (B) and 3' P. berghei dhfr-ts regions. Constructs pDB.DTm.DB./AB.alpha AF.DB. and pDB.DTm.DB./DB.alpha AF.DB. are identical except that the pf83/ama-1 ORF is in reversed orientation.

Pyrimethamine-resistant transgenic P. berghei parasite populations obtained from mice were matured in vitro and analyzed for the presence of the AMA-1 protein of the human malaria P. falciparum. IFA with mAb 58F8dc1 specific for the N-terminal region of PF83/AMA-1 reacted strongly with recombinant P. berghei but not with control P. berghei parasites, indicating that PF83/AMA-1 was expressed.

Developmental Stage-specific Trans-species Expression of PF83/AMA-1 Is Promoter-mediated-- Northern blots of total RNA isolated from 1 × 107 rings, schizonts, or gametocytes and probed with pf83/ama-1 showed high levels of a 2.3-kb mRNA in schizonts and gametocytes of parasites transfected with the construct containing the P. berghei dhfr-ts promoter, whereas under control of the pb66/ama-1 promoter, transcription was only observed in schizonts (Fig. 2A, lanes 2, 3, and 5). The weak hybridization signal in lane 9 (gametocytes transfected with the pb66 promoter construct) can be accounted for by slight contamination of this preparation with mature schizonts (verified in Giemsa-stained thin films). No transcripts were detected in ring stage parasites nor in parasites transfected with pf83/ama-1 in the reverse orientation. Hybridization of these Northerns with a T. gondii dhfr-ts probe showed transcription of the selectable marker gene in all schizont and gametocyte lanes but not in the lanes from ring stage parasites.


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Fig. 2.   Northern blot (A) and Western blot (B) analyses of transfected P. berghei parasites. Parasites were transfected with vector pDB.DTm.DB./DB.AF.DB. (lanes 1-3), vector pDB.DTm.DB./AB.AF.DB. (lanes 4-6), or a mixture of vectors pDB.DTm.DB./AB.alpha AF.DB. and pDB.DTm.DB./DB.alpha AF.DB. (lanes 7-9). Parasites were purified at ring stage (lanes 1, 4, and 7), schizont stage (lanes 2, 5, and 8), and gametocyte stage of development (lanes 3, 6, and 9). A, total RNA was isolated from purified parasite populations and fractionated on a 1% agarose-formaldehyde gel (RNA from 107 parasites/lane), blotted onto a nylon membrane, and probed with a 32P-labeled pf83/ama-1 ectodomain probe under stringent conditions. The 2.3-kb mRNA (lanes 2, 3, and 5) mirrors PF83/AMA-1 protein expression. B, extracts were fractionated by SDS-polyacrylamide gel electrophoresis under reducing conditions (5 × 105 parasite equivalents/lane) and blotted onto a nitrocellulose membrane. The blot was reacted with the panspecific mAb 28G2dc1. 83- and 66-kDa forms of PF83/AMA-1 are evident in transfected schizonts (lanes 2 and 5) and in gametocytes when under dhfr-ts-promoter control (lane 3). Control transfected schizonts only express the 66-kDa Pb66/AMA-1 (lane 8).

Western blot analysis using a pan-specific mAb (28G2dc1) that reacts with a linear determinant present in all Plasmodium AMA-1 molecules identified to date revealed expression of PF83/AMA-1 as a full-length 83-kDa protein in mature schizonts. No expression was detected in ring stage parasites, irrespective of the promoter used to drive expression (Fig. 2B, lanes 2 and 5). In addition, expression controlled by the dhfr-ts promoter was detected in gametocytes (Fig. 2B, lane 3). Analogous to the situation in P. falciparum (13), N-terminal proteolytic processing to a form of approximately 66 kDa was observed (Fig. 2B, lanes 2 and 5). This processed form migrated as the slightly larger molecule in a 66-kDa doublet, the other component of which was authentic P. berghei AMA-1, which was also reactive with mAb 28G2dc1 (Fig. 2B, lanes 2, 5, and 8). As expected authentic P. berghei AMA-1 expression was restricted to schizonts. Confirmation of this expression profile for full-length PF83/AMA-1 expression was obtained through reactivity of the 83-kDa AMA-1 with the N-terminal mAb 58F8dc1, which does not react with P. berghei AMA-1 (data not shown). Interestingly, P. berghei gametocytes that express PF83/AMA-1 under control of P. berghei dhfr-ts also showed processing to the 66-kDa form (Fig. 2B, lane 3). No PF83/AMA-1 expression was evident when P. berghei was transfected with constructs containing pf83/ama-1 in the reverse orientation (Fig. 2B, lanes 7, 8, and 9). The weak 66-kDa signal in the gametocyte lanes 6 and 9 can be accounted for by minor contamination of the gametocyte preparations with mature schizonts.

Trans-species Expressed PF83/AMA-1 Attains a Functional Conformation-- AMA-1 contains multiple disulfide links (29) that generate species-specific epitopes that are critical to vaccine efficacy (11, 17) and protein function (30). Rat mAbs capable of blocking P. falciparum AMA-1 function were selected from a panel of mAbs characterized by recognition of reduction-sensitive, native, parasite determinants present on both full-length and processed PF83/AMA-1. Thus all mAbs in this panel immunoprecipitated both full-length (83-kDa) and processed (66-kDa) forms of PF83/AMA-1 from Triton X-100 extracts of metabolically radiolabeled P. falciparum schizonts but were not reactive with Western blots of P. falciparum schizonts. One of these mAbs, 4G2dc1 (IgG2a) consistently inhibited asexual P. falciparum multiplication in vitro (by 60-70% compared with control mAbs of the same isotype). This mAb reacted by IFA with all ten P. falciparum strains of diverse geographical origin analyzed to date. Critically, 4G2dc1 also recognized transfected P. berghei parasites by IFA when PF83/AMA-1 was expressed under both pb66 and pb-dhfr promoter control.

Temporal Regulation of Trans-species PF83/AMA-1 Expression-- A more detailed analysis of PF83/AMA-1 protein expression in transgenic P. berghei was performed by IFA with mAb 4G2dc1. Parasites transfected with pDB.DTm.DB./AB.AF.DB., using the pb66/ama-1 promoter to control PF83/AMA-1 expression, expressed PF83/AMA-1 only in maturing schizonts with six or more nuclei (Fig. 3A). In contrast, in parasites obtained after transfection with pDB.DTm.DB./DB.AF.DB., using the dhfr-ts promoter to control expression, PF83/AMA-1 was initially observed in maturing trophozoites and during onset of schizogony and could be detected throughout schizont development (Fig. 3B). PF83/AMA-1 expression in native conformation was also evident in gametocytes of both sexes when under control of the dhfr-ts promoter (Fig. 3C). IFA analysis of activated gametes in homogenized mosquito mid-gut revealed PF83/AMA-1 expression 1 h after a blood meal but not 24 h after feeding of the mosquitoes (data not shown). Parasites obtained after transfection with the construct containing the pb66/ama-1 promoter consistently failed to show expression of PF83/AMA-1 in gametocytes and gametes (data not shown).


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Fig. 3.   Immunofluorescent and immunoelectron microscopic analyses of transfected P. berghei parasites expressing PF83/AMA-1. For IFA, methanol-fixed thin films were reacted with the PF83/AMA-1-specific mAb 4G2dc1, and parasite nuclei were stained with 4,6-diamidino-2-phenylindole. A, P. berghei schizont-infected red cells at various stages of development (six and twelve nuclei, and segmented schizont) expressing PF83/AMA-1 under control of the pb66/ama-1 promoter. PF83/AMA-1 expression is barely visible at the six-nucleus stage (arrow), but prominent at the twelve-nucleus stage (middle parasite) and in segmented schizonts (top parasite). B, P. berghei mature schizont-infected red cell expressing PF83/AMA-1 under control of the dhfr-ts promoter, showing high level expression. Similar expression was observed in mature trophozoites (not shown). C, P. berghei gametocyte expressing PF83/AMA-1 under control of the dhfr-ts promoter. D and E, free merozoites expressing PF83/AMA-1 under control of the pb66/ama-1 promoter showing apically restricted fluorescence (D) and under control of the dhfr-ts promoter showing predominantly circumferential and cytoplasmic fluorescence (E). F, electron microscopic section through a developing merozoite within a schizont of P. berghei expressing PF83/AMA-1 under control of the dhfr-ts promoter. Note the rhoptry body staining along with adjacent regions of cytoplasm. The section was immunostained with 58F8dc1 (specific for the N terminus of PF83/AMA-1), and secondary antibodies were labeled with 10-nm gold (magnification, ×64,000).

Subcellular Localization of Trans-species Expressed PF83/AMA-1 Is Promoter-dependent-- Quantitation of PF83/AMA-1 expression under control of the pb66/ama-1 promoter by counting fluorescence patterns in 1000 free merozoites yielded PF83/AMA-1 localization entirely to the apex of 95% of the merozoites (Fig. 3D). In contrast, expression under control of the dhfr-ts promoter yielded in 85% of the merozoites a strong circumferential and cytoplasmic staining in addition to occasional weak apical staining (Fig. 3E). This difference in localization is already evident in maturing schizonts (Fig. 3, A and B), where the protein when expressed under ama-1 promoter control is apparently associated with developing organelles, whereas under dhfr promoter control, a much more diffuse localization is evident.

Immunoelectron microscopy analysis of expression under the dhfr-ts promoter shows that PF83/AMA-1 is distributed patchily in the cytoplasm of merozoites, and in some rhoptries, it localizes to the rhoptry body but is not found in micronemes or dense granules (Fig. 3F). In maturing gametocytes the protein is associated with the endoplasmic reticulum network (not shown). IFA analyses of gametes performed on unfixed material 1 h after mosquito feeding revealed PF83/AMA-1 expression at the gamete surface.

Immunization with Transfected P. berghei Parasites Yields High Titer Antibodies to PF83/AMA-1-- To determine whether P. berghei parasites that expressed PF83/AMA-1 could induce an immune response against PF83/AMA-1, two groups of Swiss mice were infected with P. berghei transfected either with mixed pDB.DTm.DB./DB.AF.DB. and pDB.DTm.DB./AB.AF.DB. (forward pf83/ama-1) or with mixed pDB.DTm.DB./DB.alpha AF.DB. and pDB.DTm.DB./AB.alpha AF.DB. (reverse pf83/ama-1). Sulfadiazine modulation of parasite growth was used to permit two sequential peaks of parasitemia of approximately 1% (28). Parasitemia peaks were observed at the end of the first week after infection and at the beginning of the third week after infection. A second infection was given in week 9. Expression of PF83/AMA-1 was monitored by IFA on parasites that were obtained from infected mice and matured (18 h) in vitro and was evident throughout the experiment. Antibodies reactive with PF83/AMA-1 were already detected at week 4 as determined by ELISA on pooled sera (end point titer 1:20,000; data not shown), and by week 11 antibody titers were >1:100,000 (Fig. 4), whereas in the control group titers of approximately 1:10,000 were observed. This control group reactivity can be explained by cross-reactive antibodies induced by P. berghei AMA-1. To unequivocally demonstrate the appearance of PF83/AMA-1 specific reactivity and determine whether the functional epitope defined by mAb 4G2dc1 was recognized, a competition ELISA was performed. Only antibodies of mice immunized with transfected P. berghei parasites that were expressing PF83/AMA-1 effectively competed with mAb 4G2dc1 (Fig. 4), demonstrating that components of the immune response were directed against a critical functional epitope of PF83/AMA-1.


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Fig. 4.   ELISA titration of individual mouse sera 11 weeks after infection with transfected P. berghei. Mice were infected with P. berghei transfected with pf83/ama-1 (thick lines) or with reverse ORF pf83/ama-1 (thin lines), allowed to experience two waves of parasitemia over a 4-week period, and were finally boosted with 2 × 107 schizonts at week 8. Titration was performed using recombinant full-length PF83/AMA-1 as solid phase antigen. The inset shows results of a competition ELISA demonstrating that only IgG from the experimental group of mice competes with mAb 4G2dc1 for binding to PF83/AMA-1 (>45% inhibition of binding). Lines over the bars indicate standard deviations.

    DISCUSSION
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Abstract
Introduction
Materials & Methods
Results
Discussion
References

The development of transgene expression systems for malaria will allow detailed study of parasite cell biology. Mechanisms underlying drug resistance, protein trafficking, and molecular function can be explored in greater depth than previously possible, and manipulation of parasite phenotype for evaluation of attenuated vaccines, for example toward higher immunogenicity and lower pathogenicity, becomes feasible. Here we report on the first studies of trans-species expression of a human malaria vaccine candidate antigen and show (i) that the protein is expressed in a conformationally and functionally relevant form, (ii) that depending on the time of expression it is differentially routed within the developing parasite, and (iii) that it is highly immunogenic within the context of a rodent malaria parasite. These studies employed an asexual blood stage vaccine candidate, AMA-1, a single copy gene that has a well defined, tightly controlled, stage-specific expression pattern (13, 14, 31) and contains targeting signals for the rhoptries, organelles involved in red cell invasion. Vaccine experiments to date have shown that deletion mutants of AMA-1 are not induced under immune pressure (15, 16), indicating it is an essential molecule. As a prelude to AMA-1 knockout experiments, which we expect to be lethal because the parasite genome during asexual phase development is haploid, we have developed trans-species complementation capabilities for this molecule. In this study two promoters controlled PF83/AMA-1 expression, the authentic P. berghei ama-1 promoter, and the P. berghei dhfr-ts promoter. Both promoters induced expression of conformationally intact, full-length PF83/AMA-1. However, the time of appearance and the subcellular distribution of the protein were substantially different. PF83/AMA-1 conformation was assessed by reactivity with a mAb (4G2dc1) that inhibited P. falciparum invasion of erythrocytes in vitro. This mAb is reactive with an invariant, reduction-sensitive conformational and functional epitope and provides a new tool to assess the correct conformation of P. falciparum AMA-1 molecules.

Trans-species PF83/AMA-1 expression under control of the pb66/ama-1 promoter was analogous to authentic PF83/AMA-1 expression in P. falciparum (13), restricted to schizonts with six or more nuclei. This demonstrates that the 1.5 kb of the pb66/ama-1 upstream region present in the expression construct contains sufficient information to drive stage-specific expression of PF83/AMA-1. Under P. berghei dhfr-ts promoter control, PF83/AMA-1 was expressed throughout schizogony as well as in gametocytes, coordinated with DHFR-TS expression from the genomic copy (32) in developmental stages where DNA synthesis is ongoing. Although, because eight male gametes are produced from each microgametocyte, it was not surprising that under dhfr-ts promoter control PF83/AMA-1 was expressed in male gametocytes, approximately 30% of PF83/AMA-1-expressing gametocytes were female. It remains to be determined whether these results indicate that DHFR-TS is also normally synthesized in female gametocytes (perhaps in preparation for post-fertilization DNA synthesis) or whether the dhfr-ts driven expression observed is a consequence of loss of transcriptional control because of incomplete 5' elements or loss of chromosomal positioning. Despite prolonged exposure we found no evidence for dhfr-ts mRNA transcripts in ring stages, in contrast to a previous report (32).

The timing of expression markedly influenced the subcellular localization of PF83/AMA-1. When expressed under the ama-1 promoter, the protein is routed to the rhoptries, as is authentic AMA-1 (13, 14, 33). In contrast, expression controlled by the dhfr-ts promoter during the onset of schizogony, when rhoptries are absent, as well as in gametes that do not contain rhoptries, results in targeting to the parasite surface as well as in a cytoplasmic localization, as is evident from both IFA and immunoelectron microscopy data. When rhoptries are being formed, dhfr-ts-controlled PF83/AMA-1 is also routed to the rhoptries but is notably localized to the rhoptry body (Fig. 3F) rather than authentically localized in the rhoptry neck (14). At this stage cytoplasmic localization is also detected, but the fate of this cytoplasmically localized protein is not yet clear. Additional immunoelectron microscopy studies are currently being performed to more closely define the localization of authentic and trans-species expressed AMA-1 in relation to the promoter used to drive expression. Exchanging putative signal and targeting sequences in future transfection experiments will start to unravel the trafficking of rhoptry and other organellar proteins to their final destination.

Proteolytic processing of PF83/AMA-1 from an 83- to a 66-kDa form occurred both in schizonts and in gametocytes, suggesting that the processing is mediated by a common parasite protease that is not restricted to the rhoptry. This processing event does not occur in P. berghei AMA-1 because it is synthesized de novo as a 66-kDa molecule, as are all other AMA-1 forms reported to date. This extra N-terminal region, present only in P. falciparum, is of unknown function, but its cleavage seems to be associated with capacity for merozoite invasion of red cells (13).

Although there are significant obstacles to the development of vaccines based on the malaria parasite itself, it is possible that effective vaccines may ultimately be based upon attenuated parasites or upon nonpathogenic species that are genetically modified to carry heterologous target proteins. To evaluate the immunogenicity of PF83/AMA-1 expressed in the context of a P. berghei infection, mice were chronically infected with transgenic P. berghei parasites. The observed responses and the fine specificity thereof demonstrate that trans-species expression of the human P. falciparum antigen PF83/AMA-1 in P. berghei can elicit a strong immune response directed against a functionally important region of this molecule. Given the protection induced in primate models after AMA-1 vaccination (15, 16), it will be interesting to evaluate whether trans-species expression can provide protection against a challenge with a heterologous parasite species. This is not possible in the system described here because rodents are not susceptible to infection with P. falciparum. However, as a prelude to such studies in other systems we have recently shown that expression of AMA-1 from other primate malaria species is feasible in P. knowlesi,2 a parasite of relatively broad host specificity.

In summary, we have demonstrated drug-selectable trans-species expression of a second gene (in addition to the selectable marker) in a malaria parasite. P. falciparum AMA-1 expression in P. berghei under control of the stage-specific P. berghei pb66/ama-1 promoter or the more constitutive P. berghei dhfr-ts promoter resulted in a timing and subsequent subcellular localization of PF83/AMA-1, which markedly differed between the two promoters. In addition, antibodies to a critical functional determinant of PF83/AMA-1 were elicited in mice, emphasizing strong immunogenicity of the trans-species expressed protein.

    ACKNOWLEDGEMENTS

We thank Dr. W. Eling for advice on transmission experiments, Dr. A. Kent for immunolabeling for immunoelectron microscopy, Dr. G. Barker and Dr. M. Ponzi for help in cloning the P. berghei AMA-1 promoter region, and K. de Brouwer and M. van Bokhoven for excellent technical assistance.

    FOOTNOTES

* This work was supported by European Commission, DG XII (International Cooperation-Developing Countries) contracts CT95-0022 and CT94-0275 and by the Life Sciences Foundation (805-33.332P) of the Netherlands Organisation for Scientific Research.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

parallel Supported by Wellcome Trust Grant 048244.

Dagger Dagger To whom correspondence should be addressed. Tel.: 31-15-284-2538; Fax: 31-15-284-3986; E-mail: thomas{at}bprc.nl.

1 The abbreviations used are: AMA-1, apical membrane antigen-1; DHFR-TS, dihydrofolate reductase-thymidylate synthase; IFA, immunofluorescent assay; ORF, open reading frame; kb, kilobase pair(s); mAb, monoclonal antibody; ELISA, enzyme-linked immunosorbent assay.

2 C. H. M. Kocken, A. M. van der Wel, and A. W. Thomas, unpublished observation.

    REFERENCES
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
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