Mediation of Cryptosporidium parvum Infection In Vitro by Mucin-Like Glycoproteins Defined by a Neutralizing Monoclonal Antibody

doi:10.1128/IAI.68.9.5167-5175.2000

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Infection and Immunity, September 2000, p. 5167-5175, Vol. 68, No. 9
0019-9567/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.

Mediation of Cryptosporidium parvum Infection In Vitro by Mucin-Like Glycoproteins Defined by a Neutralizing Monoclonal Antibody

Ana María Cevallos,¹ Najma Bhat,¹ Renaud Verdon,¹^, Davidson H. Hamer,¹ Barry Stein,² Saul Tzipori,¹^,² Miercio E. A. Pereira,¹ Gerald T. Keusch,¹ and Honorine D. Ward¹^,²^,^*

Division of Geographic Medicine and Infectious Diseases, Tupper Research Institute, New England Medical Center, Tufts University School of Medicine, Boston, Massachusetts 02111,¹ and Division of Infectious Diseases, Tufts University School of Veterinary Medicine, North Grafton, Massachusetts 01536²

Received 22 March 2000/Returned for modification 18 May 2000/Accepted 7 June 2000

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

The protozoan parasite Cryptosporidium parvum is a significant cause of diarrheal disease worldwide. Attachment to and invasionof host intestinal epithelial cells by C. parvum sporozoites arecrucial steps in the pathogenesis of cryptosporidiosis. The molecularbasis of these initial interactions is unknown. In order to identifyputative C. parvum adhesion- and invasion-specific proteins, weraised monoclonal antibodies (MAbs) to sporozoites and evaluatedthem for inhibition of attachment and invasion in vitro. Usingthis approach, we identified two glycoproteins recognized by 4E9,a MAb which neutralized C. parvum infection and inhibited sporozoiteattachment to intestinal epithelial cells in vitro. 4E9 recognizeda 40-kDa glycoprotein named gp40 and a second, >220-kDa proteinwhich was identified as GP900, a previously described mucin-likeglycoprotein. Glycoproteins recognized by 4E9 are localized tothe surface and apical region of invasive stages and are shedin trails from the parasite during gliding motility. The epitoperecognized by 4E9 contains $alpha$ -N-acetylgalactosamine residues, whichare present in a mucin-type O-glycosidic linkage. Lectins specificfor these glycans bind to the surface and apical region of sporozoitesand block attachment to host cells. The surface and apical localizationof these glycoproteins and the neutralizing effect of the MAband $alpha$ -N-acetylgalactosamine-specific lectins strongly implicatethese proteins and their glycotopes as playing a role in C. parvum-hostcellinteractions.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Cryptosporidium parvum, an intestinal Apicomplexan parasite, is a significant cause of diarrheal disease worldwide (15,17). In immunocompetent individuals, the disease is usuallyself-limiting, but it may be chronic and life threatening in immunocompromisedpatients such as those with AIDS. Recently, the parasite has gainednotoriety as the causative agent of numerous outbreaks of waterbornediarrheal disease. There is currently no effective specific therapyapproved for disease caused by thisparasite.

Infection is initiated by ingestion of oocysts, which undergo excystation to release sporozoites. Attachment of sporozoitesto epithelial cells and subsequent invasion of the host cell membraneare crucial primary steps in the pathogenesis of cryptosporidiosis.The ultrastructural aspects of attachment and invasion have beencharacterized in detail (10, 24, 33, 34). Sporozoitesattach to host cells by their anterior pole. Attachment is followedby invagination of the host cell plasma membrane, which extendsalong the surface of the sporozoite and eventually completelysurrounds it, leading to formation of a parasitophorus vacuolewhere the parasite undergoes further development in a unique intracellularbut extracytoplasmiclocation.

Using in vitro models of sporozoite attachment to epithelial cells, we previously showed that attachment was dose and timedependent and was influenced by pH, divalent cations, and thedegree of differentiation of host cells (20, 22). Further,attachment could be inhibited by polyclonal antibodies to C. parvumproteins as well as by glycoconjugates specific for a sporozoitesurface Gal/GalNAc-binding lectin which we had previously described(20-22). A recent study confirmed the role of Gal/GalNAc-specificlectin-carbohydrate interactions in attachment (4). Previousstudies have also reported that C. parvum infection in vitro canbe inhibited by polyclonal or monoclonal antibodies to C. parvumproteins (5, 7, 9, 11, 23). In addition, sporozoitemotility and invasion have been shown to be dependent on parasiteand host cell cytoskeletal elements (4, 12, 13).

Although ultrastructural details and various factors affecting attachment and invasion have been characterized, little isknown about the molecular basis of these initial host-parasiteinteractions or of specific parasite and host molecules whichmediate them (38). Knowledge of such molecules is crucial forunderstanding the pathogenic mechanisms involved in the host-parasiteinteraction and for designing preventive and interventional strategiesto combat cryptosporidiosis. The aim of this study was to identifyand characterize specific parasite proteins that may be involvedin the initial C. parvum-host cell interactions of attachmentand invasion. In order to do this, we raised monoclonal antibodies(MAbs) to sporozoite surface proteins and screened them for inhibitionof attachment and infection in vitro. In this study, we describetwo C. parvum glycoproteins identified by 4E9, a MAb to a carbohydrateepitope present in multiple developmental stages of the parasite,which inhibits attachment and infection invitro.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Parasites. C. parvum oocytes of the GCH1 isolate (36) were treated with 1.75% (vol/vol) sodium hypochlorite for 10 min on ice; washedwith Dulbecco modified Eagle medium (Life Technologies, GrandIsland, N.Y.) containing 25 mM HEPES, 100 U of penicillin perml, and 100 µg of streptomycin per ml, and excysted for 2 h at37°C or for 1 h in the presence of 0.25% trypsin and/or 0.75%taurocholic acid. Sporozoites were purified by isopycnic Percollgradient centrifugation (1) or by filtration through a 2.0-µm-pore-sizeNucleopore polycarbonate filter (Costar Scientific Corporation,Cambridge, Mass.).

Shed proteins (SP) were obtained by excystation of oocysts in Dulbecco modified Eagle medium for 2 h at 37°C, followed bycentrifugation at 5000 × g at 4°C for 10 min. Protease inhibitors(final concentrations of 2 mM phenylmethylsulfonyl fluoride, 20µM leupeptin, 10 µM E64, and 2 mM EDTA) were added to the supernatant,which was concentrated 10-fold by ultrafiltration. The excystationrate using this protocol ranged from 40 to 60% (depending on theage of the oocysts), compared to 60 to 80% when excystation wasperformed in the presence of trypsin and/or taurocholic acid.This method was used to obtain SP in order to avoid inclusionof proteins that may be released from the surface of the parasiteby trypsin and/or taurocholicacid.

Other protozoan parasites were provided by A. Kane, Center for Gastroenterology Research in Absorptive and Secretory Processes,New England Medical Center, Boston, Mass. (Giardia lamblia trophozoitesand Entameba histolytica trophozoites); M. E. A. Pereira, TuftsUniversity School of Medicine, Boston, Mass. (Trypanosoma cruzitrypomastigotes and Leishmania major promastigotes); and K. Kim,Albert Einstein School of Medicine, New York, N.Y. (Toxoplasmagondiitachyzoites).

Cell culture. Caco-2A (human intestinal epithelial) cells were obtained from the cell culture core of the Center for Gastroenterology Researchin Absorptive and Secretory Processes at New England Medical Centerand grown as described previously (22).

MAbs. In order to obtain MAbs to surface epitopes, sporozoites were fixed with 1% glutaraldehyde for 30 min on ice, residual aldehydegroups were blocked with 0.1 M glycine, and sporozoites were washedwith phosphate-buffered saline (PBS). BALB/c mice were immunizedintraperitoneally with fixed sporozoites in complete Freund'sadjuvant, followed by three intraperitoneal boosts with the samepreparation using incomplete Freund's adjuvant. Spleen cells werefused with P3 × 63/Ag mouse myeloma cells and cloned in liquidmedium. Clones were screened for reactivity with the surface and/orapical region of sporozoites by immunofluorescence(IF).

Clone 4E9, which showed the strongest reactivity by IF, was chosen for further study. This clone was further subcloned anddetermined to be of the immunoglobulin M (IgM) (kappa) isotypeusing an enzyme-linked immunosorbent assay (ELISA)-based isotypingkit (Southern Biotechnology Associates, Inc., Birmingham, Ala.).Ascites fluid was obtained following injection of 4E9 hybridomacells into Pristane-primed BALB/c mice. B9A4, an IgM control MAbagainst Brugia malayi phosphorylcholine, was generously providedby C. Carlow, New England Biolabs, Beverly, Mass. 7B3, an IgG1MAb to GP900 (26), was obtained as a kind gift from C. Petersen,University of California, San Francisco. 4E9 and B9A4 IgM werepurified from ascites fluid using an E-Z-SEP purification kit(Pharmacia Biotech Inc., Piscataway, N.J.).

IF and FITC-lectin-binding assays. Purified oocysts were placed on poly-L-lysine (30 µg/ml in water)-coated slides. Purified sporozoites were allowed to glideon poly-L-lysine-coated slides for 30 min at room temperature(RT). For intracellular stages, Caco-2A cells grown to confluencein 16-well chamber slides were infected with oocysts for 24 h(37). Slides with oocysts and sporozoites were fixed with 4%paraformaldehyde for 10 min at RT. Slides with intracellular stageswere fixed and permeabilized with methanol. IF was performed asdescribed previously (20). Controls included culture mediumand the irrelevant IgM MAb B9A4. Binding of the following fluoresceinisothiocyanate (FITC)-conjugated lectins (Sigma, St. Louis, Mo.)(2 µg/ml in PBS) was performed as described earlier (39): Helixpomatia agglutinin (HPA), Maclura pomifera agglutinin (MPA), Artocarpusintegrifolia agglutinin (AIA) (Jacalin), and Sambucus nigra agglutinin(SNA). Specificity of binding was determined by preincubationof the lectin with its cognate sugar inhibitor (as described forlectin blottingbelow).

Immunoelectron microscopy (IEM). Piglets and gamma interferon (IFN- $gamma$ )-knockout mice were infected with C. parvum oocysts as described previously (16, 35).Intestinal tissue, oocysts, and sporozoites were fixed in 0.25%glutaraldehyde-4% paraformaldehyde in 0.1 M sodium phosphate buffer(pH 7.2) (PB), at 4°C overnight. Oocysts and sporozoites werepelleted by centrifugation, and 2% agarose was added and allowedto solidify. Samples were washed with PB, dehydrated, and embeddedin L. R. White Resin (Electron Microscopy Sciences, Fort Washington,Pa.). Silver-gold sections from polymerized blocks were placedon Formvar-coated 300-mesh nickel grids. Grids with sections werefloated on drops of 0.05 M glycine-0.5 M NaCl-1% Tween 20-0.05M Tris (pH 7.5) (TBST) for 30 min, on 1% bovine serum albumin(BSA) in TBST for 10 min, and on 10% normal goat serum (NGS) inTBST for 10 min. Grids were then placed on 4E9 IgM at 4°C for1 h, followed by 1% BSA in TBST for 4 min and lastly on 10-nm-diametercolloidal gold conjugated to goat anti-mouse Ig diluted in 5%BSA-1% NGS in TBST for 30 min. Grids were washed, stained with3% aqueous uranyl acetate, and viewed by transmission electronmicroscopy.

Immunoblotting and lectin blotting. Parasite proteins were separated by gradient sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) (5 to 15%polyacrylamide) and transferred to nitrocellulose for 18 h at395 mA at 4°C. Bound proteins were probed with MAb 4E9 and detectedby chemiluminescence or colormetric methods. For the chemiluminescencemethod, nonspecific binding was blocked with 10% NGS in 10 mMTris-HCl-150 mM sodium chloride (pH 8.0) (TBS) for 1 h beforeincubation with MAb 4E9 in 5% NGS in 0.1% Tween 20 in TBS (0.1%T-TBS) for 90 min at RT. After being washed three times with 0.1%T-TBS, strips were incubated with horseradish peroxidase-conjugatedgoat anti-mouse antibody (Immunopure; Pierce) diluted in 5% NGS-0.1%T-TBS for 1 h at RT. The strips were washed, incubated in SuperSignalsubstrate (Pierce), exposed to film, and developed. For the colormetricmethod, nonspecific binding was blocked with 5% nonfat milk (NFM)in TBS for 1 h before incubation with MAb 4E9 in 1% NFM in TBSfor 1 h at RT. After being washed with 0.05% T-TBS, strips wereincubated with alkaline phosphatase-conjugated goat anti-mouseantibody (Promega, Madison, Wis.) in 1% NFM in TBS for 1 h atRT. The strips were washed and developed with nitroblue tetrazolium(NBT)-5-bromo-4-chloro-3-indolylphosphate (BCIP) substrate. Competitiveinhibition of 4E9 binding by HPA was evaluated by incubating thestrips with HPA (50 µg/ml) for 10 min at RT before incubationwith4E9.

For lectin blotting, nonspecific binding was blocked with 0.1% Tween 20 in PBS (0.1% T-PBS) for 1 h at RT. Blots were incubatedwith the following biotinylated lectins (EY Laboratories, Inc.,San Mateo, Calif.) diluted in 0.1% T-PBS (10 µg/ml) for 1 h atRT: HPA, AIA, MPA, SNA, Glycine max agglutinin (soybean agglutinin[SBA]), Dolichos biflorus agglutinin (DBA), Arachis hypogaea agglutinin(peanut agglutinin [PNA]), Sophora japonica agglutinin (SJA),Ulex europaeus agglutinin-1 (UEA-1), Maackia amurensis agglutinin(MAA), Canavalia ensiformis agglutinin (concanavalin A agglutinin[ConA]), and Triticum vulgare (wheat germ agglutinin [WGA]). Toassess specificity of binding, lectins were preincubated withthe following specific sugars (250 mM): N-acetylgalactosamine(GalNAc) (for SBA, HPA, DBA, and SJA), $beta$ -lactose (for PNA, SNA,and MAA), N-acetylglucosamine (for WGA), melibiose (for AIA andMPA), methyl- $alpha$ -mannopyranoside (for ConA), and fucose (for UEA-1).Blots were washed with 0.1% T-PBS, incubated with an avidin-biotin-alkalinephosphatase complex (ABC reagent; Vector, San Mateo, Calif.) for1 h at RT, washed, and developed with NBT-BCIPsubstrate.

Immunoprecipitation. A mixture of sporozoites and oocysts (derived from excystation of 10⁸ oocysts) in PBS containing protease inhibitors (described above)was lysed by five freeze-thaw cycles and detergent extractionwith 1% Triton X-100. The lysate was centrifuged at 10,000 × gfor 30 min. Detergent-soluble material was incubated with MAb7B3 overnight, followed by incubation with protein G-Sepharose(Pharmacia Biotech Inc.) for 2 h at 4°C. After extensive washingwith 20 mM sodium phosphate-0.5 M NaCl-0.5% Triton X-100-0.1%SDS-0.1% deoxycholate, immunoprecipitated proteins were analyzedby SDS-PAGE and immunoblotting with MAb4E9.

Infection and attachment assays. The effect of MAb 4E9 on C. parvum infection of Caco-2A cells was studied by a modification of an in vitro assay describedearlier (37). Briefly, oocysts (1 × 10⁴/well) preincubated with 4E9 or B9A4 IgM for 30 min at RT wereincubated with Caco-2A cells (2 × 10⁴/well) grown in 96-well tissue culture plates for 24 h at 37°Cwith 5% CO₂. Cells were fixed, permeabilized with methanol for10 min at RT, and washed three times with TBS. Infection was quantifiedby ELISA (37) using a polyclonal rabbit anti-C. parvum antibody(20) that recognizes >30 proteins, ranging from 14 to >200 kDa,present on sporozoites, merozoites, and intracellular stages butnotoocysts.

The effect of MAb 4E9 or lectins on attachment of sporozoites to glutaraldehyde-fixed Caco-2A cells was studied using an invitro assay as described previously (22). Briefly, Caco-2A cellsgrown to confluence in 96-well plates were fixed with glutaraldehydeto prevent invasion. Sporozoites were preincubated with test orcontrol antibodies or lectins for 30 min at 4°C. For attachmentassays using lectins, sporozoites were washed twice with assaybuffer after preincubation with the lectins. Controls (sporozoitesin assay buffer) were treated in the same way. The sporozoiteswere then incubated with the glutaraldehyde-fixed Caco-2A monolayersfor 1 h at 37°C. Unbound parasites were washed off, and attachedsporozoites were quantified by ELISA using the same antibody asfor the infectionassay.

Cytotoxicity assay. Caco-2A cells grown in 96-well plates were incubated with or without purified MAb IgM (100 µg/ml) for 24 h at 37°C with 5%CO₂. Possible cytotoxicity of the MAbs for the cells was assessedby measuring viability using a CellTiter96 AQ_ueous kit(Promega).

Periodate oxidation and glycosidase digestion. SP were separated by SDS-PAGE and transferred to nitrocellulose. Strips were incubated with 50 mM sodium acetate buffer (pH4.5) (SAB) alone (as a control) or with 10 mM periodic acid inSAB in the dark for 1 h at RT. The strips were rinsed with SABand incubated with 50 mM sodium borohydride in PBS for 30 minat RT and then probed with 4E9 as describedabove.

SP were treated with the following glycosidases (Oxford Glycosciences, Bedford, Mass.) at 37°C overnight, according to themanufacturer's recommendations: peptide-N-glycosidase F (recombinant)(50 U/ml), endo- $alpha$ -N-acetylgalactosaminidase (from Streptococcuspneumoniae) (111 mU/ml), and $alpha$ -N-acetylgalactosaminidase (fromchicken liver) (300 mU/ml). As controls for the various glycosidases,SP were incubated with buffer alone under identical conditions.Specificity of $alpha$ -N-acetylgalactosaminidase activity was assessedby addition of paranitrophenyl $alpha$ -N-acetylgalactosaminide to afinal concentration of 2.5mM.

Statistical methods. Attachment, infection, antigen-binding, and cytotoxicity assays were performed in three to six replicates, and the mean andstandard error (SE) of the mean were determined. All assays wererepeated at least three times. Results from representative assaysare shown. Comparison of means was performed using a nonpairedStudent t test. A P value of <0.05 was considered statisticallysignificant.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

MAb 4E9 neutralizes C. parvum infection of intestinal epithelial cells and inhibits sporozoite attachment to these cells in vitro. In order to identify putative C. parvum adhesion- and invasion-specific proteins, we raised MAbs to sporozoites and screenedthem by IF to identify clones reactive with the surface or anteriorportion of sporozoites (suggestive of an apical complex localization).Using this approach, we identified 4E9, an IgM MAb, which showedthe strongest reactivity of all the clones by IF. To determinewhether proteins recognized by 4E9 were involved in initial host-parasiteinteractions, we evaluated the effect of this MAb on C. parvuminfection of intestinal epithelial cells using an in vitro assay(37). Compared to an irrelevant isotype-matched control MAb,4E9 IgM neutralized infection of Caco-2A cells in a dose-dependentmanner, with almost complete inhibition occurring at a concentrationof 100 µg/ml (Fig. 1A). The results obtained with this assay weresimilar to those obtained using a previously described IF-basedassay (37) in which intracellular stages are directly visualizedby phase-contrast and epifluorescence microscopy (R. Verdon andH. Ward, unpublished data). The inhibition of infection was notdue to toxicity of 4E9 for host cells, since the MAb had no effecton viability (data not shown). 4E9 IgM did not agglutinate sporozoitesor oocysts at the concentrations used, indicating that the inhibitoryeffect was not due to agglutination of the parasite.

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FIG. 1. Effect of MAb 4E9 on C. parvum infection of and attachment to Caco-2A cells. Oocysts (A) or sporozoites (B) were preincubated with increasing concentrations of 4E9 or control IgM and allowed to infect (A) or attach to (B) Caco-2A cells. Infection and attachment were quantified by ELISA. Results are expressed as the mean of absorbance values at 405 nm ± SE. *, P < 0.001 compared to control IgM, **, P < 0.05 compared to control IgM.

In order to determine if the antibody inhibited infection by blocking adherence of sporozoites to intestinal cells, we studiedits effect on attachment using an in vitro assay in which cellsare fixed to prevent invasion (22). As seen in Fig. 1B, 4E9inhibited sporozoite attachment to fixed Caco-2A cells in a dose-dependentmanner, with 50% inhibition occurring at 100 µg/ml. The decreasein attachment measured by ELISA was not due to reduced bindingof the detecting polyclonal antibody to proteins recognized by4E9, since similar results were obtained using an IF-based assay(20) in which attached sporozoites are directly visualized byphase-contrast and epifluorescence microscopy (D. Hamer and H.Ward, unpublished data). These results suggested that the neutralizingeffect of the MAb is mediated at least in part by blocking ofsporozoite attachment to host cells, resulting in subsequent inhibitionofinfection.

The epitope recognized by 4E9 is present in multiple developmental stages. We used an IF assay to localize the epitope recognized by 4E9 in various developmental stages (Fig. 2). This MAb reacted withmaterial shed from oocysts that were undergoing excystation (Fig.2A) as well as with the surface of newly excysted sporozoites(Fig. 2B). In addition, 4E9 reacted with the surface and apicalregion of purified sporozoites as well as with material shed intrails from sporozoites during gliding motility (Fig. 2C). Ininfected Caco-2A cells, 4E9 reacted with the surface of merozoiteswithin meronts or newly released from them (Fig. 2D). These findingswere confirmed and extended by IEM (Fig. 3). Label was detectedat the surface of sporozoites and in locations surrounding thesporozoite (Fig. 3A and B), consistent with shedding of the proteinfrom the surface. Apical complex organelles were not visualizedin this preparation. In oocysts (Fig. 3C), label was localizedon the surface of sporozoites. Examination of meronts in infectedpig ileum (Fig. 3D) revealed labeling on the surface of merozoites.In addition, there was reactivity with microgametes in IFN- $gamma$ -knockoutmouse infected intestine (Fig. 3E). Taken together, these resultsshowed that proteins containing the epitope recognized by MAb4E9 are shed in trails during gliding motility and suggested asurface as well as possible apical complex organelle localizationin sporozoites and merozoites.

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FIG. 2. Reactivity of MAb 4E9 with C. parvum stages as determined by IF. (A and B) Oocysts. Material shed from excysting oocysts (A) and the surface of newly excysted sporozoites (arrow) (B) is labeled. (C) Sporozoites. The surface and apical region of sporozoites and of material shed in trails (arrow) from sporozoites allowed to glide on poly-L-lysine coated slides are labeled. (D) Intracellular stages. Meronts and merozoites newly emerged from them (arrow) in infected Caco-2A cells are labeled.

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FIG. 3. Localization of the epitope recognized by MAb 4E9 on C. parvum stages as determined by immunoelectron microscopy. (A and B) Sporozoites. Label is present on the surface (arrows) and in locations surrounding the sporozoites (arrowheads). (C) Oocysts. Label is present on the surface of sporozoites (S) within the oocyst. (D) Meront from ileum of infected piglet intestinal tissue. Label (arrows) is on the surface of merozoites (M). (E) Microgamont from intestine of infected IFN- $gamma$ -knockout mouse. Label (arrow) is present on microgametes (G). Bars, 1 µm.

MAb 4E9 recognizes two major C. parvum peptides of 40 and >900 kDa. The epitope recognized by MAb 4E9 was present on two major bands as determined by immunoblotting: a 40-kDa peptide and a very-high-molecular-masspeptide of >220 kDa (Fig. 4A). The latter peptide comigrated witha previously described >900-kDa glycoprotein (GP900) recognizedby MAb 7B3 (26) by immunoblotting (data not shown). Oocyst andsporozoite proteins immunoprecipitated by MAb 7B3 were recognizedby 4E9 by immunoblotting, confirming that this peptide was GP900(data not shown). The 40-kDa protein (designated gp40) and GP900were present in oocysts and sporozoites. An additional 250-kDaband was also detected only in oocysts (Fig. 4A). There was noreactivity of the control IgM MAb B4A9 (not shown) with any ofthese proteins, confirming the specificity of 4E9. In addition,4E9 did not react with proteins from other protozoa (Giardia lamblia,E. histolytica, Toxoplasma gondii, Trypanosoma cruzi, and L. major)in immunoblotting (not shown), indicating that the epitope recognizedby MAb 4E9 is specific for Cryptosporidium.

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FIG. 4. Identification of proteins recognized by 4E9. Oocysts, sporozoites, and SP were analyzed for reactivity with MAb 4E9 by immunoblot analysis. (A) Reactivity of MAb 4E9 with oocysts (lane 1), sporozoites (lane 2), and shed proteins (lane 3) by immunoblotting. (B and C) Protein profiles of oocyst and sporozoite proteins (lane 1) and SP (lane 2) as determined by silver staining (B) and immunoblotting with 4E9 (C). Numbers are molecular weights in thousands.

Analysis of SP by SDS-PAGE and silver staining revealed the presence of ~5 major bands of >900, 120, 55, 40, and 35 kDa (Fig.4B). Two of these, the >900- and 40-kDa bands, were recognizedby MAb 4E9 by immunoblotting, confirming the IF finding that theseproteins are shed from the parasite (Fig. 4C). Since this preparation(SP) was enriched in these two proteins, it was used for furthercharacterization of the epitope recognized by4E9.

The epitope recognized by 4E9 is glycosylated and contains $alpha$ -linked GalNAc residues. Reactivity of 4E9 with GP900 and gp40 was abolished by mild periodate treatment, suggesting that the epitope is glycosylated(not shown). In order to determine the nature of the carbohydratespresent, SP were probed with a panel of biotinylated lectins withvarious sugar specificities (Table 1). Of these, HPA, SBA, AIA,MPA, UEA-1, and WGA bound to both GP900 and gp40, whereas ConAand DBA bound to GP900 but not gp40. Binding was specific, sinceit could be inhibited by the appropriate cognate sugar hapten(not shown). Of note was the binding of a number of $alpha$ GalNAc-specificlectins. The patterns of reactivity of $alpha$ GalNAc-specific lectinssuch as HPA were identical to that of 4E9 (Fig. 5A and B). Inaddition, reactivity of 4E9 could be competitively inhibited byHPA (Fig. 5C). These results suggested that the epitope recognizedby 4E9 contains the same carbohydrate residues as that bound bythe $alpha$ GalNAc-specific lectins.

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TABLE 1. Lectin binding profiles of GP900 and gp40

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FIG. 5. Glycosylation of proteins recognized by 4E9. (A and B) SP were treated with increasing concentration of $alpha$ -N-acetylgalactosaminidase (lane 1, no enzyme; lane 2, 100 mU/ml; lane 3, 200 mU/ml; lane 4, 300 mU/ml; lane 5, 300 mU/ml with 2.5 mM para-nitrophenyl- $alpha$ -N-acetylgalactosaminide) and analyzed by immunoblotting with 4E9 (A) and lectin blotting with HPA (B). (C) Blots of SP were pre-incubated with HPA (lane 2) or buffer alone (lane 1) and then analyzed by immunoblotting with 4E9. Numbers are molecular weights in thousands.

In order to determine the nature of the glycosidic linkage of the saccharides in the epitope recognized by 4E9, SP were treatedwith specific glycosidases and probed with 4E9 by immunoblotting.Treatment with peptide-N-glycosidase F (which cleaves N-linkedglycans) had no effect on 4E9 reactivity (data not shown). Treatmentwith endo- $alpha$ -N-acetylgalactosaminidase, which is specific for Gal $beta$ 1-3GalNAclinked to Ser or Thr, also had no effect (not shown), suggestingthat (i) this disaccharide is not part of the epitope recognizedby 4E9, or (ii) if it is present, it is substituted with sialicacid, fucose, or GalNAc residues. Treatment with increasing concentrationsof $alpha$ -N-acetylgalactosaminidase, which cleaves terminal $alpha$ 1- 3GalNAcor GalNAc $alpha$ 1-Ser/Thr from O-linked glycoproteins, resulted indecreasing reactivity with both 4E9 and the lectin HPA and a shiftto 36 kDa for gp40 (Fig. 5A and B). This effect was specific sinceit could be inhibited by the substrate pNP $alpha$ -N-acetyl-galactosaminide.These results suggest that GP900 and gp40 contain $alpha$ GalNAc residuesand that these residues are terminal ingp40.

$alpha$ GalNAc-specific lectins bind to sporozoites and inhibit attachment to host cells. To investigate the possibility that $alpha$ GalNAc residues present in the epitope recognized by 4E9 are involved in attachment,we first determined whether lectins specific for these residuesbound to sporozoites. The results showed that the lectins HPA(Fig. 6A) and MPA and AIA (data not shown) all bound to the surfaceand apical region of sporozoites in a pattern similar to thatof MAb 4E9. The binding was specific, since it could be inhibitedby preincubation with the cognate sugar hapten (not shown). Wenext determined the effect of these lectins on sporozoite attachmentto host cells. The results (Fig. 6B) showed that all three $alpha$ GalNAc-specificlectins significantly inhibited attachment at a concentrationof 10 µg/ml, whereas SNA, which did not bind to sporozoites (datanot shown) or to GP900 and gp40 (Table 1) had no significanteffect. Since the lectins were washed off after preincubationwith the sporozoites, the inhibitory effect was not due to bindingof the lectins to the host cells. These results strongly implicatethe $alpha$ GalNAc residues of GP900 and/or gp40 in mediating sporozoiteattachment to host cells.

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FIG. 6. Binding of HPA to sporozoites and effect of lectins on attachment to host cells. (A) Binding of FITC-conjugated HPA to the surface and apical region of sporozoites. (B) Sporozoites were preincubated with lectins, washed, and allowed to attach to Caco-2A cells. Attachment was quantified by ELISA. Results are expressed as the mean of absorbance values at 405 nm ± SE. *, P < 0.001 compared to the control.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

In this study, we have shown that 4E9, a MAb to a carbohydrate epitope present on two glycoproteins in multiple developmentalstages of C. parvum, blocks attachment to and consequent infectionof host cells in vitro. This suggested that the epitope recognizedby the antibody and/or the glycoprotein(s) on which it is presentis involved in mediating initial host-parasite interactions andcould be a potential target for intervention. We therefore proceededto characterize the epitope recognized by 4E9 and the glycoproteinson which it ispresent.

The epitope recognized by 4E9 was carbohydrate in nature, suggesting that the proteins on which it was present were glycosylated.This was confirmed by lectin binding to proteins recognized by4E9. A striking finding was the binding of $alpha$ GalNAc-specific lectinssuch as HPA, AIA, and MPA. Competitive inhibition of 4E9 bindingby the lectin HPA and a similar pattern of binding of the FITC-conjugatedlectins as determined by IF and immunoblotting confirmed thatthe epitope recognized by the MAb contains $alpha$ GalNAc residues andsuggested that these glycans may be involved in mediating attachment.This possibility was strengthened by the finding that the $alpha$ GalNAc-specificlectins inhibited sporozoite attachment to host cells. The inhibitoryeffect of the lectins on attachment is consistent with a recentstudy which reported irreversible inhibition of C. parvum infectionof epithelial cells in vitro by $alpha$ GalNAc-specific lectins (19).The $alpha$ GalNAc residues may mediate attachment by direct interactionwith host carbohydrate-binding proteins. Alternatively, theseglycans may function as a bridge between host and parasite carbohydrate-bindingproteins. The latter possibility is consistent with our earlierfinding of a Gal- and GalNAc-specific sporozoite lectin whichis implicated in C. parvum attachment (21, 22) and with arecent study confirming the involvement of Gal/GalNAc-specificlectin-carbohydrate interactions in attachment (4). Whetherthe protein moieties of these glycoproteins are also involvedin attachment and, if so, the relative roles of the carbohydrateand protein components remain to bedetermined.

The major protein recognized by 4E9 by immunoblotting is a 40-kDa glycoprotein (gp40), which is present in oocysts and sporozoitesand is shed from the parasite. The pattern of reactivity of $alpha$ GalNAc-specificlectins with gp40 is suggestive of the presence of the Tn determinant,which consists of terminal $alpha$ GalNAc residues linked to Ser/Thrresidues of the protein backbone (40). The presence of terminal $alpha$ GalNAc residues in gp40 was further confirmed by the decreasein reactivity and shift in M_r caused by $alpha$ -N-acetylgalactosaminidasetreatment. We have recently cloned and sequenced the gene encodinggp40 (3). Analysis of the deduced amino acid sequence of thisgene revealed the presence of multiple predicted mucin-type O-glycosylationsites (many of which are present in a polyserine domain), whichis consistent with the biochemical findings of O-linked GalNAcresidues in gp40 in the presentstudy.

The other protein recognized by 4E9 is a previously described glycoprotein named GP900, which is localized to micronemes ofinvasive stages and is shed from the surface of sporozoites (2,26). GP900 has previously been shown to be N glycosylated (26).The pattern of lectin binding to GP900 was consistent with thepresence of internal or terminal $alpha$ GalNAc residues (40). $alpha$ -N-Acetylgalactosaminidasetreatment had no discernible effect on 4E9 reactivity with GP900,suggesting that the $alpha$ GalNAc residues may be internal or that ifthey are terminal, as in the case of gp40, a small shift in molecularweight may not be resolved due to the very high M_r of the protein.The presence of $alpha$ GalNAc residues suggests that GP900 containsmucin-type O-linked oligosaccharides. This possibility is strengthenedby the presence of multiple threonine residues in two mucin-likedomains of GP900, which could provide sites for O-glycosylation(2).

Mucins are a group of heterogeneous high-molecular-weight glycoproteins which are heavily O glycosylated (14). The lectinbinding profiles of gp40 and GP900 are suggestive of the presenceof mucin-type O glycosylation and in particular of the Tn (GalNAc $alpha$ 1-Ser/Thr) and T (Gal $beta$ 1-3GalNAc) carbohydrate determinants. Thesedeterminants are commonly present in core structures of the carbohydrateside chains of mucins. They are usually cryptic in O-linked oligosaccharidesof mucins in normal tissue, but they may be terminally exposedin mucins on tumor cells (40). In addition to GalNAc, N-acetylglucosamine(GlcNAc) and galactose (Gal) O-glycans of human intestinal andother mucins contain peripheral sugars, including sialic acid,which mask the core structures. However, unlike those of othermucins, the O-glycans of gp40 and GP900 do not appear to containsialic acid (based on lack of reactivity with the sialic acid-specificlectins SNA and MAA), which is consistent with the presence ofcore structures such as the T and Tn determinants being terminallyexposed. Binding of the lectin WGA (and lack of binding of thesialic-acid-specific lectins SNA and MAA) to both gp40 and GP900is suggestive of the presence of GlcNAc residues. These residuesmay be present on N-linked oligosaccharides, since there are potentialN-glycosylation sites in the deduced amino acid sequences of bothGP900 and gp40 (2, 3). Alternatively, GlcNAc may be presentin an O-glycosidic linkage to serine and threonine residues. Interestingly,this type of glycosylation is present in SREHP, a serine-richsurface membrane protein of the intestinal protozoan parasiteEntameba histolytica, which is also implicated in host-parasiteinteractions (31).

The O-glycosylated state of mucins contributes greatly to their adhesive as well as protective functional properties. Themucin-type O-glycosylation profiles of both gp40 and GP900 andthe finding of mucin-like domains in the deduced amino acid sequencesof GP900 (2) and gp40 may therefore be consistent with a functionalrole for these proteins in mediating adherence to host cells.Mucin-like proteins of other protozoa have also been implicatedas playing a role in host-parasite interactions. Thus, Trypanosomacruzi expresses an abundance of mucin-like proteins on the surface,encoded by a large gene family (6, 30). These proteins areshed from the surface and are believed to mediate invasion ofhost cells by theparasite.

Other investigators have described the presence of high-molecular-weight glycoproteins with features similar to GP900 in C.parvum (reviewed in reference 38). Riggs et al. described a1,300-kDa glycoprotein, CSL, which was identified using a MAbto a carbohydrate epitope (28). This MAb neutralized infectionin vitro, suggesting that the protein may be involved in attachmentand/or invasion. A recent study by that group confirmed that CSLcontains a sporozoite ligand for attachment to intestinal epithelialcells (23). However, as those authors point out, CSL and GP900appear to be different, since the former but not the latter islocalized to dense granules (28). In addition, posterior translocationof CSL (but not GP900) occurs along the sporozoite pellicle bya cytoskeletal-dependent process (28). A high-molecular-weightglycoprotein identified in association with 190- and 40-kDa bandsby an IgM MAb, which reacted with sporozoites and intracellularstages as determined by IF, was described by McDonald et al. (25).Robert et al. also described a high-molecular-weight glycoproteinrecognized by MAbs to a carbohydrate epitope, which reacted withmultiple developmental stages, as determined by IEM (29). Therelationship, if any, between GP900, CSL, and the other high-molecular-weightglycoproteins remains to be determined. However, as suggestedby Langer and Riggs, the presence of multiple distinct high-M_rglycoproteins in C. parvum is consistent with their finding ofseveral high-molecular-weight species of varying pI in silver-stainedtwo-dimensional gels (23).

Gut and Nelson described a 15-kDa glycoprotein which also had a lectin-binding profile suggestive of Tn (GalNAc $alpha$ 1-Ser/Thr)or T (Gal $beta$ 1-3GalNAc) carbohydrate determinants (18). This proteinis also localized to the surface of sporozoites and is shed fromthem during gliding motility. Since the Tn and T determinantshave been implicated in adhesion in other systems, those authorssuggested that these determinants present on C. parvum glycoproteinsmight be involved in attachment and invasion and showed that C.parvum infection could be irreversibly inhibited by T- and Tn-specificlectins in vitro (19), a result consistent with our findingsin the present study. Recently, the gene encoding this proteinhas been cloned and sequenced (3, 27, 32). Interestingly,we (3) and Strong et al. (32) have shown that this protein(named gp15) is encoded by the same gene encoding gp40 and thatboth proteins are most likely proteolytic fragments of a precursorprotein expressed in intracellular stages of the parasite. Althoughgp15 has also been shown to display O-linked glycosylation, thisprotein apparently does not contain the epitope recognized by4E9, since it is not recognized by this MAb onimmunoblots.

Attachment and invasion of other Apicomplexans such as Toxoplasma and Plasmodium have been shown to be mediated by proteinsexocytosed or shed from apical complex organelles (8). Theproteins recognized by 4E9 have many features in common with theseother Apicomplexan proteins. They are present in the invasivestages of the parasite, have a surface and/or apical location,are shed from the parasite, and are deposited in trails duringgliding movement. Neutralization of attachment and infection byMAb 4E9 and by lectins specific for the epitope recognized byit implicates these proteins and/or their glycotopes in theseinteractions. A previous study showed that native GP900, a cysteine-richdomain of the recombinant protein, and antibodies to it competitivelyinhibited C. parvum infection of MDCK cells in vitro, suggestingthat GP900 mediates attachment and invasion. We have recentlyshown that antibodies to gp40 block infection in vitro and thatnative gp40 binds specifically to intestinal epithelial cells,suggesting that this protein is also involved in attachment and/orinvasion (3). The relative contributions of GP900 and gp40to attachment and invasion are currently under investigation.However, it is very likely, as is the case in other Apicomplexanswhere multiple parasite and host molecules are involved, thatboth may have a role in these processes. The involvement of theseglycoproteins in the initial host-parasite interaction providesa basis for devising strategies designed to inhibit this interactionand raises the possibility that they may serve as targets of potentialspecific preventive or therapeuticmodalities.

	ACKNOWLEDGMENTS

This work was supported by Public Health Service (PHS) grants AI33384 and AI40344 and by the cell culture core of the GRASPDigestive Disease Center (PHS grant DK34928P30). Davidson Hamerwas supported by PHS training grant AI07389. Renaud Verdon wassupported by a fellowship from the Programme Lavoisier (Ministèredes Affaires Etrangères,France).

We gratefully acknowledge Smitha Jaison for technical assistance, Carolyn Petersen and Clothilde Carlow for MAbs, Kami Kimand Anne Kane for parasites, and Carolyn Petersen, Ajit Varki,and Shiv Pillai for helpfuldiscussions.

	FOOTNOTES

^* Corresponding author. Mailing address: Division of Geographic Medicine and Infectious Diseases, New England Medical Center,Box 041, 750 Washington St., Boston, MA 02111. Phone: (617) 636-7032.Fax: (617) 636-5292. E-mail: hward{at}lifespan.org.

Present address: Reanimation Medicale, Maladies Infectieses et Tropicales, Centre Hospitalier Universitaire Cote-de-Nacre,Caen 14033,France.

Editor: W. A. Petri Jr.

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