Identification of a Polyclonal B-Cell Activator in Plasmodium falciparum

Polyclonal B-cell activation and hypergammaglobulinemia areprominent features of human malaria. We report here that Plasmodiumfalciparum-infected erythrocytes directly adhere to and activateperipheral blood B cells from nonimmune donors. The infectederythrocytes employ the cysteine-rich interdomain region 1 ${alpha}$ (CIDR1 ${alpha}$ )of P. falciparum erythrocyte membrane protein 1 (PfEMP1) tointeract with the B cells. Stimulation with recombinant CIDR1 ${alpha}$ induces proliferation, an increase in B-cell size, expressionof activation molecules, and secretion of immunoglobulins (immunoglobulinM) and cytokines (tumor necrosis factor alpha and interleukin-6).Furthermore, CIDR1 ${alpha}$ binds to Fab and Fc fragments of human immunoglobulinsand to immunoglobulins purified from the sera of different animalspecies. This binding pattern is similar to that of the polyclonalB-cell activator Staphylococcus aureus protein A. Our findingsshed light on the understanding of the molecular basis of polyclonalB-cell activation during malaria infections. The results suggestthat the var gene family encoding PfEMP1 has evolved not onlyto mediate the sequestration of infected erythrocytes but alsoto manipulate the immune system to enhance the survival of theparasite.

INTRODUCTION

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Introduction

Parasites that proliferate in restricted ecological niches suchas Plasmodium spp. control the contact with their hosts in orderto colonize, divide, and transmit themselves. Chronic infectionswith Plasmodium falciparum lead to a severely dysregulated immunesystem, and B cells are overactivated with the subsequent secretionof an array of different autoantibodies (2, 8), the presenceof hyperglobulinemia (1), and the frequent occurrence of B-celltumors (Burkitt's lymphoma) (17). B-cell activation has beenreported in studies involving the stimulation of total peripherallymphocytes with P. falciparum-derived products, and it hasbeen suggested to be the result of direct and indirect mechanismsmediated by T lymphocytes and accessory cells (18, 19). However,the identity of the antigens and mechanisms that lead to polyclonalactivation in the course of malaria infection are currentlyunknown.

It has previously been shown that a large proportion (83%) offresh isolates of P. falciparum-infected erythrocytes (IE) bindnonimmune immunoglobulins (Igs) though to various degrees (25,26). One of the domains of the P. falciparum erythrocyte membraneprotein 1 (PfEMP1), the cysteine-rich interdomain region 1 ${alpha}$ (CIDR1 ${alpha}$ )of FCR3S1.2 (amino acids 395 to 700), binds to CD36, PECAM-1/CD31,and nonimmune Igs (4, 5, 26). Microbial Ig binding proteins(IBPs) are produced by protozoa, viruses, parasites and bothgram-positive and gram-negative bacteria (31) and play importantphysiological roles (20). It has been suggested that duringan infectious process these IBPs may act as an evasion mechanismto divert specific antibody (Ab) responses (7, 21). The bindingof CIDR1 ${alpha}$ to nonimmune Igs led us to investigate the interactionbetween human B cells and P. falciparum-IE and the involvementof CIDR1 ${alpha}$ . The present study identifies the CIDR1 ${alpha}$ domain of PfEMP1as one of the molecules that may be involved in the polyclonalB-cell activation that characterizes human malaria infection.CIDR1 ${alpha}$ directly binds to and activates purified B lymphocytesin vitro, an interaction that is mediated, at least in part,by binding to surface Igs.

MATERIALS AND METHODS

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Materials and Methods

Medium and reagents. B-cell cultures were maintained in RPMI 1640 (GIBCO-BRL, Gaithersburg,Md.) with 10% fetal calf serum, 100 U of penicillin per ml,and 2 mM glutamine. P. falciparum cells were cultured accordingto standard procedures in RPMI medium supplemented with 10%human AB⁺ Rh⁺ serum. Phycoerythrin (PE)- or fluorescein (FITC)-conjugatedmonoclonal Abs (MAbs) and enzyme-linked immunosorbent assay(ELISA) kits were purchased from Becton & Dickinson/Pharmingen(Mountain View, Calif.). Mouse anti-human IgG, IgA, and IgMAbs were purchased from DAKO (Copenhagen, Denmark). Anti-glutathioneS-transferase (GST) Abs and human IgM were purchased from Sigma.Ig from different species, human Ig classes, and Ig fragmentswere purchased from Jackson Immunoresearch Laboratories, Inc.(West Grove, Pa.).

Production of recombinant antigens. The cloning and expression of CIDR1 ${alpha}$ and Duffy binding-like domain1 ${alpha}$ (DBL1 ${alpha}$ ) of the cloned strain FCR3S1.2 were conducted as previouslydescribed (5). The CIDR1 ${alpha}$ -GST fusion protein, referred to asCIDR1 ${alpha}$ , was expressed and purified according to the instructionsof the manufacturer. GST produced by the empty vector was usedas a control, referred to as GST.

B cells and cell culture. Buffy coats from the blood of healthy individuals who had notbeen exposed to malaria were obtained from the blood bank ofthe Karolinska Hospital. Mononuclear cells were isolated bycentrifugation over Lymphoprep (Nycomed Pharma, Oslo, Norway).B cells were isolated by positive selection by using CD19⁺ magneticbeads and DETACHaBEAD (Dynal, Oslo, Norway) according to themanufacturer's instructions; B-cell purity varied between 94and 99%. In some experiments B cells were further separatedinto IgG- and IgM-enriched populations by depleting the IgM-and IgA-positive and the IgG- and IgA-positive cells, respectively,by using M-450 rat anti-mouse coated Dynabeads. The recoverednegative fraction usually contained $≤$ 3% of the cells that hadformed rosettes. Purified B cells were cultured in round-bottomed96-well plates (5 x 10⁴ cells/well) in a final volume of 200µl or in 48-well plates (5 x 10⁵ cells/well) in a finalvolume of 500 µl and incubated at 37°C in 5% CO₂.Cultures were seeded in triplicates (96-well) when the proliferationof cells was studied and in duplicates (48-well) when phenotype,IgM, or cytokine production was analyzed. Unless otherwise specified,the final concentration of GST and CIDR1 ${alpha}$ was 50 µg/mleach. All experiments were carried out at least three times.

Binding assays. B cells or IgM-positive B-cell lines were incubated for 1 hat room temperature (RT) in medium containing GST, CIDR1 ${alpha}$ , orDBL1 ${alpha}$ at concentrations ranging from 0 to 200 µg/ml. Aftertwo washes in phosphate-buffered saline, the cells were incubatedwith mouse anti-GST Ab for 30 min at 4°C. After two washes,anti-mouse biotinylated Ab was added for 30 min at 4°C,followed by PE-conjugated streptavidin. In binding competitionassays, CIDR1 ${alpha}$ was preincubated with various concentrations ofIgG or IgM for 1 h at RT before being added to the B cells (finalconcentration of CIDR1 ${alpha}$ , 50 µg/ml). The binding was analyzedby using FACSort. B-cell-erythrocyte binding analysis was carriedout as follows: B cells were stained with 1 µg of acridineorange per ml; Percoll-enriched infected (11) and noninfectederythrocytes were stained for 15 min at RT with 0.1 µgof ethidium bromide per ml. Cell mixtures with a final erythrocyte-to-B-cellratio of 5:1 were seeded into 96-well plates and incubated at37°C for 1 h; thereafter, the binding was visualized byphase-contrast microscopy and scored in fluorescence light microscopy.In competition studies, B cells were incubated for 1 h withdifferent concentrations of recombinant CIDR1 ${alpha}$ or GST prior toincubation with IE.

Proliferation assays. Cultures stimulated with CIDR1 ${alpha}$ or GST were incubated for 72h and pulsed with 1 µCi of [³H]thymidine (Amersham, LittleChalfont, United Kingdom) during the last 12 h of the incubationperiod. As a positive control, phorbol myristate acetate (PMA;Sigma) and ionomycin (Calbiochem) were used at concentrationsof 5 ng/ml and 500 ng/ml, respectively. Cells were harvestedonto a fiberglass filter, and the [³H]thymidine incorporationwas determined by liquid scintillation counting. Results areexpressed as mean counts per minute of triplicate samples oras a reactivity index (RI), calculated as follows: RI = countsper minute in stimulated cultures/counts per minute in controlcultures. The standard deviations (SD) of the triplicates weregenerally in the range of 10 to 15% of the mean. In some experimentsCIDR1 ${alpha}$ and GST were incubated for 1 h with soluble human IgMprior being added to the B cells. Results are expressed as percentinhibition, calculated as follows: (1 – counts per minutein cultures of GST or CIDR1 ${alpha}$ preincubated with IgM/counts perminute in cultures of GST or CIDR1 ${alpha}$ preincubated in medium alone)x 100.

Phenotypic analysis. B cells were harvested after culture periods varying from 60to 72 h. FITC- or PE-conjugated MAbs were added to the cellpellets at saturating concentrations, and the cells were thenincubated for 30 min at 4°C. PE- and FITC-conjugated isotype-matchedMAbs with irrelevant specificities were used as negative controls.Fluorescence intensity was measured with a FACSort flow cytometerand analyzed by using Cell Quest software (Becton Dickinson).

Cytokines and IgM determination. Supernatants were collected at 24 h (tumor necrosis factor alpha[TNF- ${alpha}$ ] determination), 48 to 72 h (interleukin-6 [IL-6] andIL-10 determinations), and 10 days (IgM content) after B-cellactivation. Cytokines and IgM content were determined by usingcommercial specific ELISAs, according to the manufacturer'sinstructions. The sensitivities of the ELISAs were 10 pg/ml,5 pg/ml, and 8 pg/ml for IL-10, IL-6, and TNF- ${alpha}$ , respectively.

Mapping of the Ig binding of CIDR1 ${alpha}$ . ELISA plates were coated overnight at 4°C with NaHCO₃ buffercontaining 5 µg of the Igs or Ig fragments per ml. Afterblocking for 2 h at RT, GST control or CIDR1 ${alpha}$ was added in aseries of double dilutions at concentrations from 3 to 100 µg/ml.Binding was detected by using an anti-GST Ab and a secondaryanti-mouse MAb coupled to alkaline phosphatase. Binding to GST,bovine serum albumin, and phosphate-buffered saline served asinternal controls. The absorption was determined from the opticaldensity at 405 nm.

RESULTS

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Results

The CIDR1 ${alpha}$ domain of PfEMP1 is involved in the interaction betweenB cells and IE. When B lymphocytes from malaria nonimmune donorswere cultured together with IE of the PfEMP1-expressing clonedstrain FCR3S1.2 (11) at an IE/B-cell ratio of 5:1, large clumpsof cells having as many as 30 to 50 IE and B cells were frequentlyobserved (Fig. 1A). In contrast, IE of the sister clone FCR3S1.6which lacks PfEMP1 (11) did not adhere to B cells (Fig. 1B).No physical interaction was observed between B cells and uninfectederythrocytes (Fig. 1C).

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FIG. 1. IE and CIDR1 ${alpha}$ bind to B cells. Ethidium bromide-stained P. falciparum-IE (red and yellow) of the FCR3S1.2 subclone (A) or the FCR3S1.6 subclone (B) coincubated with acridine orange-stained B cells (green) at a red blood cell-to-B-cell ratio of 5 to 1 (UV light image). (C) Uninfected erythrocytes coincubated with acridine orange-stained B cells at a red blood cell-to-B-cell ratio of 5 to 1 (UV light image). (D) Fluorescence-activated cell sorter analysis of purified B cells incubated in medium control (black) or medium containing either GST (red), DBL1 ${alpha}$ (green), or CIDR1 ${alpha}$ (blue) (50 µg/ml) and stained with biotinylated anti-GST Ab and PE-conjugated streptavidin. (E) Inhibition of CIDR1 ${alpha}$ binding to B cells with increasing concentrations of soluble IgG (upper panel) and IgM (lower panel). Binding of GST (gray), CIDR1 ${alpha}$ (black), and CIDR1 ${alpha}$ preincubated with IgG or IgM at a concentration of 1.5 or 1 mg/ml, respectively (green); with IgM at a concentration of 0.2 mg/ml (red); and with IgG or IgM at a concentration of 0.3 or 0.04 mg/ml, respectively (blue). Results are representative of at least three independent experiments. For further details, see Materials and Methods. (F) Inhibition of IE-B-cell binding by soluble CIDR1 ${alpha}$ . Values represent percent inhibition of the IE-B-cell binding by preincubation of B cells with CIDR1 ${alpha}$ in relation to the IE/B-cell ratio of 5:1 in the absence of CIDR1 ${alpha}$ . Shown are the means ± SD of three independent experiments.

As CIDR1 ${alpha}$ has been shown to bind to IgM (5), we assessed thebinding of recombinant CIDR1 ${alpha}$ of FCR3S1.2 to freshly isolatedB cells or to surface IgM-positive B-cell lines (Daudi and Bjab)by fluorescence-activated cell sorter analysis using FITC-conjugatedsecondary Abs. B lymphocytes bound CIDR1 ${alpha}$ , as reflected by ashift in the fluorescence intensity when compared to B cellsincubated in medium alone or with the GST control antigen. Thebinding of the recombinant N-terminal DBL1 ${alpha}$ , a domain known tolack Ig binding capacity (5), was identical to that of the GSTcontrol antigen (Fig. 1D). The binding was also confirmed byindirect fluorescence microscopy (data not shown). The incubationof Daudi cells with increasing concentrations of CIDR1 ${alpha}$ led toa fluorescence shift proportional to the concentration used(data not shown). Given the binding of CIDR1 ${alpha}$ to B lymphocytes,we determined its participation in the interaction between IEand B cells. To this end, we performed competition experimentsin which B cells were preincubated with increasing concentrationsof recombinant CIDR1 ${alpha}$ before exposure to IE. CIDR1 ${alpha}$ but not GSTcompeted away in a dose-dependent manner the IE-B-cell bindingat concentrations ranging from 0 to 200 µg/ml (Fig. 1E).These results demonstrate the involvement of the CIDR1 ${alpha}$ domainof PfEMP1 in the IE-B-cell interaction.

We next analyzed the functional consequences of the IE-B-cellinteraction. Coincubation of highly purified synchronized late-stageIE of FCR3S1.2 with B cells from healthy donors (not previouslyexposed to malaria) induced proliferation (Fig. 2A) and TNF- ${alpha}$ production (Fig. 2B). This B-cell response was specific anddose dependent; uninfected erythrocytes did not activate thecells, and the response correlated with the IE/B-cell ratio.In accordance with the observed lack of B-cell binding, IE ofthe FCR3S1.6 clone not expressing PfEMP1 did not induce B-cellproliferation or TNF- ${alpha}$ production (data not shown).

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FIG. 2. CIDR1 ${alpha}$ and IE induce B-cell proliferation. Proliferative (A) and TNF- ${alpha}$ (B) production response of B cells to increasing numbers of uninfected or P. falciparum-IE. (C) Proliferative response of B cells to increasing concentrations of purified GST and CIDR1 ${alpha}$ . Values represent mean counts per minute ± SD of a representative experiment. (Inset) Summary of the proliferative response of B cells to 50 µg of GST or CIDR1 ${alpha}$ per ml. Values represent mean ± standard error of the mean of the RI in 26 independent experiments. (D) Comparison of the proliferative response of B cells to recombinant CIDR1 ${alpha}$ and DBL1 ${alpha}$ . Results are representative of three experiments; the SD bars ( $≤$ 15%) have been omitted. (E) Proliferation of total B cells in response to GST or CIDR1 ${alpha}$ (50 µg/ml) previously incubated with increasing concentrations of soluble IgM. Values are expressed as percent inhibition of the proliferation of B cells in response to GST or CIDR1 ${alpha}$ preincubated in medium alone. (F) Comparative proliferative response of total, IgG-positive, and IgM-positive B cells to 50 µg of GST or CIDR1 ${alpha}$ per ml. Results are representative of five independent experiments. RBC, red blood cells.

Recombinant CIDR1 ${alpha}$ induces B-cell proliferation and activation. The stimulatory capacity of recombinant CIDR1 ${alpha}$ on purified Bcells was subsequently studied. Recombinant CIDR1 ${alpha}$ induced B-cellproliferation in a dose-dependent manner at concentrations varyingfrom 0.5 to 200 µg of CIDR1 ${alpha}$ per ml and at time pointsbetween 48 and 96 h. Figure 2C shows a representative dose titrationexperiment where optimal B-cell proliferation was seen at concentrationsbetween 33 and 100 µg of CIDR1 ${alpha}$ per ml. On the basis ofthese results, a concentration of 50 µg/ml and a timepoint of 72 h of stimulation were used in further experiments.Results of 26 independent experiments performed with B cellsfrom healthy donors who had not been exposed to malaria (n =26) are summarized in Fig. 2C (inset). Cells stimulated withCIDR1 ${alpha}$ proliferated 2.5 times above control levels (RI of 2.5± 0.2); in contrast, the control antigen GST only inducedminimal proliferation of a magnitude comparable to that occurringin medium alone (RI of 1.2 ± 0.1). CIDR1 ${alpha}$ without thefusion partner (GST) induced a response of the same magnitudeas with the whole fusion protein (data not shown). Conversely,no proliferation was observed in response to the other PfEMP1domain, the GST recombinant DBL1 ${alpha}$ domain (Fig. 2D). The responseto the positive control PMA-ionomycin was vigorous (RI of 80± 25) (data not shown).

To investigate the participation of IgM and IgG in the CIDR1 ${alpha}$ -B-cellinteraction, we performed binding competition experiments inwhich CIDR1 ${alpha}$ was incubated with soluble IgM or IgG before beingadded to the B cells. The results presented in Fig. 1F revealthat soluble IgM and IgG compete out in a dose-dependent mannerthe binding of CIDR1 ${alpha}$ to B cells. The proliferation induced byCIDR1 ${alpha}$ is related to its Ig binding capacity. Accordingly, theproliferation induced was also inhibited by preincubation ofCIDR1 ${alpha}$ with soluble IgM at concentrations ranging from 0.125to 0.5 µg/ml (Fig. 2E). These concentrations of IgM didnot affect the proliferation of B cells activated with PMA-ionomycin(data not shown). We further compared the response of differentsubpopulations of B cells separated on the basis of IgG andIgM surface expression. Both IgG- and IgM-enriched populationsresponded to CIDR1 ${alpha}$ , though the background responsiveness washigher among the IgM-enriched B cells (Fig. 2F). These resultsshow that the CIDR1 ${alpha}$ domain of PfEMP1 induces the proliferationof B lymphocytes and that the CIDR1 ${alpha}$ -B-cell interaction is mediated,at least in part, through the binding to surface Ig.

The activation of B cells leads to the up-regulation of HLA-DR,adhesion molecules, costimulatory molecules, and other B-cellactivation-specific antigens (30). CIDR1 ${alpha}$ induced a moderatebut consistent up-regulation in the expression of HLA-DR, CD23,CD40, CD54, CD58, CD80, and CD86 (Fig. 3A). There were no significantchanges in the levels of expression of other markers includingsurface Ig, CD10, CD11a, CD21, CD69, and CD95 (data not shown).Consistent with this activation, there was also an increasein the size of the CIDR1 ${alpha}$ -stimulated B cells, reflected by anincrease in the forward side scatter (Fig. 3A). Therefore, CIDR1 ${alpha}$ induces not only proliferation but also the up-regulation ofa series of activation antigens on normal B cells.

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FIG. 3. Stimulation with recombinant CIDR1 ${alpha}$ activates B cells. (A) CIDR1 ${alpha}$ induces the expression of B-cell activation markers and increased B-cell size. B cells incubated in medium alone (black) and in medium containing 50 µg of either GST (green) or CIDR1 ${alpha}$ (red) per ml for 72 h were stained with FITC- or PE-conjugated MAbs and analyzed by flow cytometry. Dotted-black-line histograms represent control staining with irrelevant Ab. Results are representative of at least 10 independent experiments. (B) CIDR1 ${alpha}$ stimulates B cells to produce IgM, IL-6, and TNF- ${alpha}$ . Supernatants of B cells cultured in medium alone and in medium containing 50 µg of either GST or CIDR1 ${alpha}$ per ml were analyzed for the content of TNF- ${alpha}$ (24 h), IL-6 (72 h), or IgM (10 days) by specific ELISA. For further details, see Materials and Methods. FSC, forward scatter.

The serum of individuals exposed to P. falciparum malaria isknown to contain high levels of Ig and a repertoire of circulatingcytokines and autoantibodies that reflect polyclonal B-cellactivation (2, 6, 15, 28). Hence, we examined whether CIDR1 ${alpha}$ could provoke similar B-cell responses. Stimulation with CIDR1 ${alpha}$ induced a moderate but consistent production of TNF- ${alpha}$ and IL-6compared to levels of the control antigen (Fig. 3B). IL-10 wasnot detected in any of the supernatants collected either at24, 48, or 72 h after activation (data not shown). CIDR1 ${alpha}$ activationalso led to an increased production of IgM that was measured10 days after stimulation (Fig. 3B). Taken together, these resultsdemonstrate that the CIDR1 ${alpha}$ domain of PfEMP1 induces polyclonalactivation in normal peripheral B cells.

The Ig binding pattern of CIDR1 ${alpha}$ . Due to the capacity of CIDR1 ${alpha}$ to bind nonimmune Igs (5) and toactivate B cells, we further studied its reactivity with differentIgs and Ig fragments. CIDR1 ${alpha}$ bound equally well to Fab( ${kappa}$ or ${lambda}$ )and to Fc fragments of human Igs as well as to IgG and IgM (Fig.4A). Furthermore, CIDR1 ${alpha}$ bound dose-dependently to Igs purifiedfrom the sera of different animal species (Fig. 4B). The controlantigen (GST) or other similarly produced recombinant domainssuch as DBL1 ${alpha}$ and DBL2 ${delta}$ did not bind to any of the Ig or Ig-derivedfragments (not shown).

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FIG. 4. Mapping of the Ig binding of CIDR1 ${alpha}$ by ELISA. (A) Binding of CIDR1 ${alpha}$ to human Igs and Ig fragments. (B) Binding of CIDR1 ${alpha}$ to IgG of different species. For further details, see Materials and Methods. OD, optical density.

DISCUSSION

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Discussion

It has previously been shown that IE bind nonimmune Igs andthat PfEMP1 can be characterized as a multiadhesive parasiteligand in which the CIDR1 ${alpha}$ domain mediates binding to severalindependent host receptors including CD36 and PECAM-1/CD31 andto nonimmune Igs (4, 5). The data presented in this report demonstratethe direct interaction between human B cells and P. falciparum-IE,the involvement of the CIDR1 ${alpha}$ domain of PfEMP1, and its capacityto activate B cells from nonimmune donors.

The expression of PfEMP1 in the IE was required for the bindingto B lymphocytes because IE of the sister clone FCR3S1.6 lackingPfEMP1 (11) did not adhere to or activate B cells. Other IEmoieties may also participate in this binding, as suggestedby the partial competition ( $≤$ 50%) mediated by recombinant CIDR1 ${alpha}$ .Although the competition curve did not reach a plateau, theconcentrations of recombinant CIDR1 ${alpha}$ used (up to 200 µg/ml)may exceed the molar concentration present at the surface ofIE.

Recombinant CIDR1 ${alpha}$ bound to and activated B cells; this interactionis mediated, at least in part, through binding to surface IgMand IgG, as indicated by decreased binding and activation followingpreincubation of CIDR1 ${alpha}$ with soluble IgM and IgG. The bindingof CIDR1 ${alpha}$ seems to be specific because the binding of anotherGST recombinant fusion protein, DBL1 ${alpha}$ , is identical to that ofthe GST control. It could be argued that since the recombinantantigen was produced in Escherichia coli, the proliferationobserved could be due to contaminating endotoxin. We can ruleout this possibility because the expression system and purificationsteps for the control antigen GST and the recombinant DBL1 ${alpha}$ domainthat did not induce proliferation were the same as those usedfor CIDR1 ${alpha}$ . Moreover, the response to CIDR1 ${alpha}$ was not inhibitedby polymyxin B, and in contrast to murine B cells, human B cellsdo not respond to endotoxin or lipopolysaccharide as they donot express the toll-like receptor 4, an essential componentof the lipopolysaccharide receptor signaling complex (22). Therelatively low magnitude of the proliferative response to CIDR1 ${alpha}$ observed in our study seems to be inherent to primary humanperipheral B cells, yet splenic B cells from Toll 4^–/–mice displayed a robust proliferation in response to this antigen(data not shown).

The capacity of PfEMP1 to stimulate B cells seems to be relatedto the Ig binding property of its domains. Accordingly, theDBL1 ${alpha}$ domain that lacks the Ig binding capacity (5) did not bindto or induce B-cell proliferation. CIDR1 ${alpha}$ bound to Ig of differentspecies and to different portions and subclasses of human Igs;this extensive Ig binding pattern is similar to that of othermicrobial IBPs such as protein A of Staphylococcus aureus (SpA)(10, 24). Crystallographic work has disclosed that the Ig bindingdomains in SpA are within areas of the polypeptide carrying ${alpha}$ -helices and that the Fab- and Fc-binding sites are structurallyseparated (14). It should be noted that the IgM binding domainof CIDR1 ${alpha}$ also harbors potential ${alpha}$ -helical structures (amino acids550 to 700) and similar contact residues as those present inprotein A, yet the molecular details of the interaction remainto be explored. Taken together, these facts suggest that CIDR1 ${alpha}$ binds to B cells via the Fab fragments of Ig expressed at theB-cell surface, much as SpA does.

Malaria-induced polyclonal B-cell activation has been reportedin vivo (17, 18) and in in vitro studies involving the stimulationof total peripheral blood lymphocytes (16, 18). The identificationof P. falciparum-derived products and of the mechanisms responsiblefor B-cell activation has remained elusive though direct andindirect mechanisms mediated by T cells and accessory cellshave been proposed to explain this phenomenon (9, 12, 16, 19).Here we show that CIDR1 ${alpha}$ directly activates in vitro purifiedB cells from nonimmune donors and binds to various Ig fragmentsand to Igs from different species and, therefore, could be definedas a superantigen. Since the proliferative response to CIDR1 ${alpha}$ was not high (a 2.5-fold increase compared to control antigenand media), the question arises whether this level of responsewould result in the polyclonal activation seen in vivo duringmalaria infections. It should be noted that in the present studythe proliferation occurred in the absence of accessory cellsand cytokines and was consistently observed in 26 of 26 experimentsperformed with lymphocytes from donors never exposed to malariapreviously. We envisage that in vivo the stimulatory capacityof CIDR1 ${alpha}$ may be enhanced by a multitude of cofactors: splenicB cells would be exposed to CIDR1 ${alpha}$ presented not only on theIE but phagocytosed and presented as soluble antigen or as immunecomplexes by follicular dendritic cells and dendritic cellsin the presence of cytokines, T helper cells, and costimulatorysignals. Additionally, CIDR1 ${alpha}$ has been shown to induce CD4 T-cellresponses in malaria immune and nonimmune donors (3), a factorthat in vivo could amplify by many times the magnitude of theresponse observed in the present study. It must be noted thatin the present study purified T cells did not proliferate inresponse to CIDR1 ${alpha}$ (data not shown), suggesting that the activationof CD4 Th cells reported by Allsopp et al. (3) may involve cognaterecognition on B cells or other antigen-presenting cells.

The activation of B cells in vivo may occur in compartmentswith relatively high local concentrations of CIDR1 ${alpha}$ or as theresult of direct binding to IE expressing CIDR1 ${alpha}$ , in which neighboringadhesive moieties of PfEMP1 may further enhance the IE-B-cellinteraction. Moreover, blood-borne antigens (and thus malarialantigens related to the erythrocytic phase) are trapped mainlyin the spleen, where B cells represent $~$ 50% of the splenocytes.The Ig binding properties of CIDR1 ${alpha}$ may serve to amplify itsinteraction with B cells, making it a key molecule, but potentiallynot the only one, involved in malaria-induced polyclonal B-cellactivation. The fact that Ig-binding parasites (and thereforeintravascular superantigens) are frequent in children in areaswhere malaria is endemic (26) may explain, at least in part,the prominent hypergammaglobulinemia and polyclonal B-cell activationthat characterize human malaria (1, 8, 17).

It has been suggested that during an infectious process IBPsof bacteria, viruses, and now CIDR1 ${alpha}$ of P. falciparum may divertspecific Ab responses (21). P. falciparum, one of the most successfulhuman pathogens, has evolved multiple evasion mechanisms includingclonal antigenic variation and diversity (23, 29), T-cell antagonism(13), and hindrance of dendritic cell maturation (27). It istempting to speculate that the polyclonal B-cell activationdescribed here is another virulence mechanism that contributesto the evasion of efficient host responses. The results maysuggest that the large var gene family encoding PfEMP1 has evolvednot only to mediate the sequestration of IE but also in orderto manipulate the immune system and to allow for the survivalof the parasite.

ACKNOWLEDGMENTS

This work was supported by grants from The Karolinska Institutet,The Swedish Medical Association, The Swedish International DevelopmentCooperation Agency (Sida/SAREC), The Swedish Cancer Society,The Swedish Research Council, and Barncancerfonden.

We thank B. J. Chambers and Victor Fernández for stimulatingdiscussions.

FOOTNOTES

* Corresponding author. Mailing address: Center for Infectious Medicine (CIM), Department of Medicine, Karolinska Institutet, Huddinge University Hospital, F59, S-141 86 Stockholm, Sweden. Phone: 46 8 58581158. Fax: 46 8 7467637. E-mail: marbej{at}ki.se.

Editor: S. H. E. Kaufmann

D.D. and L.P.Z. contributed equally to this work.

REFERENCES

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