Bivalency Is Required for Anticapsular Monoclonal Antibodies To Optimally Suppress Activation of the Alternative Complement Pathway by the Cryptococcus neoformans Capsule

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Infect Immun, April 1998, p. 1547-1553, Vol. 66, No. 4
0019-9567/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.

Bivalency Is Required for Anticapsular Monoclonal Antibodies To Optimally Suppress Activation of the Alternative Complement Pathway by the Cryptococcus neoformans Capsule

Thomas R. Kozel,^* Randall S. MacGill, and Kevin K. Wall

Department of Microbiology and the Cell and Molecular Biology Program, School of Medicine, University of Nevada, Reno, Nevada 89557

Received 12 September 1997/Returned for modification 27 October 1997/Accepted 9 January 1998

	ABSTRACT

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Encapsulated cells of Cryptococcus neoformans are potent activators of the alternative complement pathway. Previous studiesfound that monoclonal antibodies (MAbs) specific for the majorcapsular polysaccharide, termed glucuronoxylomannan (GXM), canmarkedly suppress the ability of the capsule to accumulate C3from normal human serum via the alternative pathway. The presentstudy examined the abilities of F(ab)₂ and Fab fragments of threeMAbs (MAbs 439, 3C2, and 471) to mediate the suppressive effect.The results showed that F(ab)₂ fragments of all three MAbs suppressedactivation and binding of C3 via the alternative pathway in amanner similar to that of intact antibodies. In contrast, Fabfragments of MAb 439 and MAb 3C2 showed no suppressive activity,and Fab fragments of MAb 471 were markedly reduced in suppressiveactivity. Indeed, there was an earlier accumulation of C3 on encapsulatedcryptococci in the presence of the Fab fragments. Study of subclassswitch families of MAb 439 and MAb 471 found that MAbs of an immunoglobulinG (IgG) subclass with increased flexibility in the hinge region(IgG2b) had less suppressive activity than MAbs of IgG subclasseswith less flexibility (IgG1 or IgG2a). Taken together, these resultsindicate that cross-linking of the capsular matrix is an essentialcomponent in suppression of the alternative complement pathwayby anti-GXM MAbs.

	INTRODUCTION

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The capsule of the pathogenic yeast Cryptococcus neoformans is a powerful activator of the alternative complement pathway(8, 16). Incubation of encapsulated cryptococci in normalhuman serum (NHS) leads to deposition of 10⁷ to 10⁸ molecules of C3 onto the typical yeast cell (18, 38); thecapsule itself is the site for C3 binding (19, 21). Such activationand binding of C3 is due solely to the action of the alternativepathway (20, 21, 37). Binding of C3 via the alternativepathway in NHS is characterized by a delay of approximately 4to 6 min before bound C3 is readily detectable (20).

The major component of the cryptococcal capsule is the high-molecular-weight polysaccharide glucuronoxylomannan (GXM). Severalanti-GXM monoclonal antibodies (MAbs) have been shown to providea measure of protection in a murine model of cryptococcosis (9,24, 30). In the accompanying report, we have examined theability of anti-GXM MAbs to initiate the classical pathway, leadingto accelerated deposition of C3 onto the yeast (17). These studiesshowed that most anti-GXM MAbs promote early deposition of C3fragments into the capsule. However, depending on the epitopespecificity of the MAb, some anti-GXM MAbs markedly reduced theapparent rate of amplification of bound C3, with the net resultthat fewer C3 molecules bound to the cell over a 20- to 30-minincubation period than would have bound in the absence of theantibody. When classical pathway initiation was blocked by theuse of EGTA to chelate Ca²⁺ (12, 28), antibodies with the suppressive epitope specificityalmost completely blocked the normal alternative pathway activationand binding of C3 that would have occurred in the absence of theMAbs.

The ability of an antibody to block antibody-independent activation of the alternative pathway is without an obvious parallelin the literature. There are several potential mechanisms forantibody-mediated suppression. First, the antibody could bindto and occlude specific sites on the capsule that might be preferredacceptors for metastable C3b. Second, the capsule could containspecific domains that regulate the ability of the capsule to activatethe alternative pathway. Antibodies specific for such regulatorydomains could influence the ability of the cell to activate thealternative pathway. Finally, multivalent antibody could cross-linkthe capsule in a manner that prevents effective amplification.For example, binding of a multivalent antibody could reduce theability of metastable C3b to diffuse from sites of C3 convertaseactivity. We have reasoned that the first two mechanisms for antibody-inducedsuppression of C3 binding would be mediated by intact antibody,F(ab)₂ fragments of the antibody, and Fab fragments. In contrast,inhibition that is dependent on cross-linking of the capsularmatrix would be mediated by intact antibodies and F(ab)₂ fragmentsbut not by Fab fragments.

The objective of our study was to examine three anticapsular MAbs that suppress alternative pathway-dependent C3 binding.The suppressive activities of intact antibodies, F(ab)₂ fragments,and Fab fragments were compared. The results showed that intactantibodies and F(ab)₂ fragments of the antibodies suppressed accumulationof C3 fragments on the capsule. In contrast, Fab fragments ofthe suppressive antibodies showed markedly reduced or no abilityto block alternative pathway activation by the capsule; indeed,Fab fragments derived from suppressive antibodies acceleratedactivation and binding of C3 via the alternative pathway.

	MATERIALS AND METHODS

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Yeast cells. Unless otherwise indicated, formalin-killed cells of C. neoformans 388, an encapsulated strain of serotype A, were used throughoutthe study. The conditions for growth, formalin inactivation andstorage of the cells have been described elsewhere (38).

Serum and serum proteins. Peripheral blood samples were collected from at least 10 adult volunteer donors. The sera were isolated, pooled, and storedat $-$ 85°C until use. C3 was isolated from frozen human plasma asdescribed elsewhere (19, 36). C3 was labeled with ¹²⁵I by the Iodogen (Pierce, Rockford, Ill.) procedure (13) accordingto the manufacturer's directions.

Antibody production and fragmentation. Three anti-GXM MAbs were used in this study, i.e., MAbs 439, 3C2, and 471. The characteristics of these antibodies have beenpreviously described (1, 2, 10, 35). The MAbs were isolatedfrom mouse ascites fluid and purified as described elsewhere (31).All three antibodies have similar properties, including (i) reactivitywith GXM serotypes A, B, C and D, (ii) belonging to the same moleculargroup as described by Casadevall et al. (2), (iii) immunoglobulinG1 (IgG1) isotype, (iv) modest ability to facilitate early activationand binding of C3 to the cryptococcal capsule via the classicalpathway (17), and (v) strong ability to suppress activationand binding of C3 to the capsule via the alternative pathway (17).Subclass switch families (IgG1 $right-arrow$ IgG2b $right-arrow$ IgG2a) of the cell linessecreting MAbs 439 and 471 were produced as described elsewhere(33), and the antibodies were isolated from ascites fluids (31).

F(ab)₂ and Fab fragments were prepared by using the ImmunoPure IgG1 Fab and F(ab')₂ preparation kit (Pierce) according tothe manufacturer's directions. Briefly, the intact antibody wasdigested with ficin under conditions optimized for productionof Fab or F(ab)₂ fragments from murine IgG1, and the fragmentswere separated from whole IgG and Fc fragments by affinity chromatographywith immobilized protein A (Pierce). The MAb 471 Fab fragmentswere further purified by molecular sieve chromatography on Superdex200 (Pharmacia Biotech Inc., Piscataway, N.J.) and affinity chromatographyon protein A-Sepharose CL-4B (Pharmacia Biotech). Sodium dodecylsulfate-polyacrylamide gel electrophoresis (SDS-PAGE) of the F(ab)₂and Fab fragments followed by staining with Coomassie BrilliantBlue showed protein bands of the expected molecular weights andan absence of contaminating proteins.

Analysis of MAb binding to yeast cells. The numbers of whole antibodies, F(ab)₂ fragments, and Fab fragments binding to cells of strain 388 were determined by useof ¹²⁵I-labeled proteins as described elsewhere (17). The numbersof MAb molecules bound per cell were calculated according to themethod of Scatchard (32).

Kinetic analysis of C3 binding. The kinetics for activation and binding of C3 fragments to cryptococcal cells were assessed in 1.5-ml reaction mixtures consistingof (i) 40% NHS, (ii) GVB-Mg-EGTA (5 mM sodium Veronal-bufferedsaline [pH 7.3] containing 0.1% gelatin, 10 mM EGTA, and 10 mMMgCl₂), (iii) ¹²⁵I-labeled C3 sufficient to provide a specific activity of 50,000cpm/µg of C3 for the mixture of labeled and unlabeled C3 in theserum, (iv) anti-GXM MAbs or their fragments at 50 or 200 µg/ml,and (v) 6.0 × 10⁵ cryptococcal cells. The tubes containing all reagents exceptthe cryptococcal cells were prewarmed for 5 min at 37°C, and thereaction was initiated by addition of the yeast cells. Sampleswere withdrawn in duplicate at various time intervals, and theamount of specifically bound C3 was determined as described elsewhere(17). Binding data are reported as the number of C3 moleculesper yeast cell versus incubation time. The time to 50% of maximumbinding was determined by use of a four-parameter logistic equationwhich was calculated with the assistance of SigmaPlot 3.0 forWindows (Jandel Scientific, San Rafael, Calif.).

Immunofluorescence analysis of C3 binding patterns. Reaction mixtures were prepared as described above for the C3 kinetic binding assay, with the exception that radiolabeledC3 was not included. Samples were taken at various time intervalsand stained for the presence of bound C3 by use of fluoresceinisothiocyanate (FITC)-labeled antiserum to human C3 (Kent LaboratoriesInc., Redmond, Wash.) by previously described procedures (17,20).

The pattern of C3 deposition was determined by epifluorescence microscopy with a Nikon Eclipse E800 microscope with an oilimmersion objective of ×100. Images were collected at 0.4-µm intervalswith a Photonic Science integrating charge-coupled device camera(Millham, United Kingdom) and Image Pro Plus version 2.0 imageanalysis software (Media Cybernetics, Silver Spring, Md.). Unlessotherwise indicated, images shown within a series of experimentswere collected with an identical number of integrations and identicalgain settings. Deconvolution of the images was done with MicroTomeIP for Windows 95 version 5.1 (VayTek, Inc., Fairfield, Iowa)operating within an Image Pro Plus version 3.0 environment. Finalassembly of the images was done with CorelDRAW 7. The images areshown as a projection of a 1.2-µm section through the center ofthe cell.

	RESULTS

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Effect of intact MAbs, F(ab)₂ fragments, and Fab fragments on the kinetics of alternative-pathway-dependent C3 deposition. MAbs 439, 3C2, and 471 all suppress the ability of encapsulated cryptococci to activate and bind C3 via the alternative pathway(17). This suppression occurs regardless of whether the cellsare live or formalin killed (data not shown). An initial experimentevaluated the abilities of F(ab)₂ and Fab fragments of these antibodiesto influence the kinetics of C3 accumulation on the cells. Cryptococcalcells were incubated in the presence of 10 mM Mg-EGTA with NHSand 50 or 200 µg of intact antibody, F(ab)₂ fragments, or Fabfragments per ml. Samples were taken after various incubationtimes, and the amounts of bound C3 were determined.

The results (Fig. 1) showed that incubation of encapsulated cryptococci with NHS alone showed little or no binding for thefirst 4 min. This was followed by a burst of binding in whichthe amount of bound C3 rapidly accumulated until approximately3 × 10⁷ molecules were bound per yeast cell when the elapsed incubationtime reached approximately 10 min. Addition of either 50 or 200µg of intact MAb per ml produced a marked suppression of boththe apparent rate of accumulation of bound C3 as well as the amountof C3 that bound over a 25-min incubation period. All three MAbshad a suppressive effect. These results confirm our report thatMAbs 439, 3C2, and 471 suppress alternative-pathway-mediated activationand binding of C3 (17). Similar results occurred when F(ab)₂fragments of the MAbs were incorporated into the incubation mixture.These results indicate that the Fc portion of the antibody isnot necessary to mediate suppression of C3 binding.

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FIG. 1. Effect of intact antibodies, F(ab)₂ fragments, and Fab fragments of MAbs 439, 3C3, and 471 on the kinetics of activation and binding of C3 fragments to encapsulated cryptococci via the alternative pathway. Cryptococci were incubated with 40% NHS containing ¹²⁵I-C3, 10 mM Mg-EGTA, and 50 or 200 µg of intact antibody, F(ab)₂ fragments, or Fab fragments per ml. Samples were taken at various times, and the amounts of bound C3 were determined.

No suppression was observed in the presence of Fab fragments of either MAb 439 or 3C2. Instead, there was a reduction of theinitial lag from 4 to approximately 2 min. Once past the lag,there was rapid accumulation of C3 on the yeast cells at a ratethat resembled the rate observed for NHS alone. The time to 50%of maximum binding was 5.8 min when cryptococci were incubatedwith NHS alone and was reduced to 3.9 min when they were incubatedwith NHS and 50 or 200 µg of Fab fragments of MAbs 439 or 3C2per ml.

Fab fragments of MAb 471 produced an effect that differed from the effect produced by Fab fragments of MAbs 439 and 3C2. Atthe highest concentration (200 µg/ml), there was a suppressionof the rate of accumulation of C3 on the yeast cells. However,the level of suppression was markedly less than the level of suppressionproduced by comparable amounts of either intact or F(ab)₂ fragmentsof MAb 471. At 50 µg/ml, Fab fragments of MAb 471 produced a slightreduction in the lag time before measurable amounts of C3 boundto the cells, but a reduction in the overall rate and total amountof C3 accumulation was also observed. We considered the possibilitythat the Fab fragments of MAb 471 contained undigested or onlypartially digested antibodies. If this were the case, the undigestedantibodies could produce an overall effect that was suppressive.As a consequence, the Fab fragments of MAb 471 were passed overa Superdex 200 molecular sieve column and protein A-Sepharosein an effort to eliminate contaminants. Neither passage over themolecular sieve alone nor use of the molecular sieve and proteinA had any effect on the ability of Fab fragments of MAb 471 tomediate modest suppression of C3 binding.

One explanation for the failure of Fab fragments to block alternative-pathway-mediated C3 binding is the possibility thatthe Fab fragments bind poorly to the encapsulated cells. As aconsequence, we radiolabeled the intact antibodies and their F(ab)₂and Fab fragments and determined the level of binding of eachprotein according to the method of Scatchard (32). This analysisallowed a calculation of the maximum number of protein moleculesbound under saturating conditions as well as the number boundunder the conditions used in the C3 binding experiments (50 and200 µg/4 × 10⁵ yeast cells). The results (Table 1) showed that each of theantibodies, as well as their cleavage fragments, readily boundto the yeast cells. Indeed, the Fab fragments exhibited a two-to eightfold increase in numbers of bound molecules compared tothe intact antibodies.

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TABLE 1. Binding of MAbs and MAb fragments to encapsulated cryptococci as determined by Scatchard analysis

The above results showed strikingly different effects of intact MAbs and their Fab fragments. Intact antibodies suppressedalternative-pathway-mediated activation and binding of C3, whereasFab fragments of MAbs 439 and 3C2 accelerated C3 binding at theearly time points. This raised a question as to which is the dominanteffect, suppression or facilitation. An experiment was done inwhich cryptococci were incubated with NHS in the presence of Mg-EGTA,to which was added either (i) no antibody, (ii) intact MAb 3C2(50 µg/ml), (iii) Fab fragments of MAb 3C2 (50 µg/ml), or (iv)both intact MAb 3C2 and its Fab fragments (50 µg each per ml).The results (Fig. 2) showed the expected findings that intactantibody suppressed and the Fab fragment facilitated C3 binding.The combination of intact antibody and Fab fragments producedan overall effect of suppression, although this result was slightlydiminished from the suppression observed with intact antibodyalone. A replicate experiment produced an identical result (notshown).

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FIG. 2. Effect of mixing intact antibodies and Fab fragments on the kinetics of activation and binding of C3 fragments to encapsulated cryptococci via the alternative pathway. Cryptococci were incubated with 40% NHS containing ¹²⁵I-labeled C3, 10 mM Mg-EGTA, and 50-µg/ml intact MAb 3C2 or Fab fragments of MAb 3C2 either alone or in combination. Samples were taken at various times, and the amounts of bound C3 were determined.

Effect of intact MAbs, F(ab)₂ fragments, and Fab fragments on the sites for alternative-pathway-mediated C3 deposition. Previous studies found that initiation of the alternative pathway by encapsulated cryptococci is characterized by a focaldeposition of C3 molecules in which the initial foci appear toexpand with incubation time to eventually fill the capsule (20).As a consequence, an experiment was done to assess the effectsof intact antibodies, F(ab)₂ fragments and Fab fragments on thefocal initiation patterns that would normally occur in the absenceof the antibodies. Encapsulated cryptococci were incubated forvarious times with NHS or NHS combined with intact IgG, F(ab)₂fragments, or Fab fragments of MAb 3C2 (50 µg/ml). Cryptococcithat were incubated with NHS for 2 min showed very limited amountsof bound C3 that occurred as minute foci at apparently randomsites in the capsule (Fig. 3). At 4 min, the foci had expandedand appeared as larger patches that were beginning to coalesce.At 8 min, the C3 bound uniformly throughout the capsule.

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FIG. 3. Effect of intact antibodies, F(ab)₂ fragments, and Fab fragments of MAb 3C2 on the sites of binding of C3 fragments to encapsulated cryptococci via the alternative pathway. Cryptococci were incubated with 40% NHS, 10 mM Mg-EGTA, and 50-µg/ml intact antibody, F(ab)₂ fragments, or Fab fragments. Samples were taken at various times, and the sites of C3 binding were determined by use of FITC-labeled anti-human C3. Conditions used for image acquisition were varied to optimally visualize the binding of C3 to each cell: *, 5, image integrations and gain of 0; **, 25 image integrations and gain of 0; ***, 25 image integrations and gain of 9.

Intact antibodies and F(ab)₂ fragments of the antibodies produced similar effects. C3 binding was focal in an effect thatclosely mimicked the results observed in the absence of antibody.However, the apparent rate of expansion of the foci was much lowerthan that observed in the absence of antibody. At 4 min of incubation,foci remained quite distinct, and there was little tendency towardcoalescence of the sites. At 8 min, there was a somewhat uniformdistribution of the C3 in the capsule; however, sites of moreintense focal binding were present on some cells, e.g., the cellshown for incubation with NHS and intact IgG for 8 min (Fig. 3).Although not readily evident from the photographs, the intensityof fluorescence was much less with cells incubated in the presenceof either intact antibody or the F(ab)₂ fragments; a greater numberof integrations were required to produce a printable image.

Incorporation of Fab fragments of MAb 3C2 into the reaction mixture produced an effect that differed from the results foundwith NHS alone or with NHS and either intact antibody or F(ab)₂fragments. C3 was readily detectable on cells incubated for 2min with NHS and the Fab fragments. Although the C3 was ratheruniformly distributed throughout the capsule, there were patchesof intense fluorescence that suggested appreciable amplificationof the initial focal deposits of C3. By 4 min, the cells showeddense deposition of C3 throughout the capsule.

Effect of IgG subclass on the ability to regulate C3 deposition via the alternative pathway. MAbs 439, 3C2, and 471 are all of the IgG1 isotype. Previous studies found that these antibodies also produced suppressionof the rate of C3 accumulation when the classical pathway wasoperative, i.e., when Mg-EGTA was not present. In contrast, IgG2aand IgG2b subclass switch variants of MAbs 439 and 471 markedlyenhanced activation and binding of C3 via the classical pathway(17). This raised a question as to the abilities of the subclassswitch antibodies to mediate suppression of alternative pathwaydependent activation and binding of C3, i.e., binding in the presenceof Mg-EGTA. This is a particularly relevant question in view ofthe need for bivalency for suppression (Fig. 1) and the observationthat antibodies of different IgG subclasses display differencesin the flexibilities of their hinge regions (5, 26).

Encapsulated cryptococci were incubated with NHS in the presence of Mg-EGTA, to which was added (i) no antibody or (ii) 50or 200 µg of MAb 471 or MAb 439 per ml having the IgG1, IgG2a,or IgG2b isotype, and the kinetics for activation and bindingof C3 were determined. The results (Fig. 4) showed that antibodiesof the IgG1 and IgG2a subclasses were similarly suppressive. TheIgG2b subclass switch antibodies of both MAb 471 and MAb 439 wereless suppressive than either the IgG1 or IgG2a isotype.

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FIG. 4. Effect of IgG subclass on the kinetics of activation and binding of C3 fragments to encapsulated cryptococci via the alternative pathway. Cryptococci were incubated with 40% NHS containing ¹²⁵I-labeled C3, 10 mM Mg-EGTA, and 50 or 200-µg/ml subclass switch antibodies (IgG1 $right-arrow$ IgG2b $right-arrow$ IgG2a) of MAbs 439 and 471. Samples were taken at various times, and the amounts of bound C3 were determined.

	DISCUSSION

Top Abstract Introduction Materials & Methods Results Discussion References

The present study considered two potential mechanisms for suppression of the alternative pathway by anticapsular MAbs. Inthe first mechanism, the capsule is viewed as a mosaic of specificdomains that are essential for activation of the alternative pathway.The specific domains could represent preferred binding sites formetastable C3b (29) and could therefore be essential to efficientinitiation and/or amplification of the alternative pathway. Alternatively,the specific domains could promote activation of the alternativepathway by favoring the binding or activity of factor B or bysuppressing the binding or activity of factor H. If specific regulatorydomains exist, an antibody reactive with such domains could suppressactivation of the alternative pathway. If this mechanism is operative,we have reasoned that inhibition should occur regardless of whetherthe suppressive antibody is used as the intact antibody or asF(ab)₂ or Fab fragments of the antibody.

The second general mechanism for suppression of the alternative pathway is inhibition of the amplification process througha mechanical or physical alteration of the capsular environment.According to this mechanism, the suppressive antibody could cross-linkthe capsular matrix and thereby alter its physical properties.This could occur in an epitope-specific manner if some epitopesare exposed in positions that permit such cross-linking whileother epitopes might be exposed in positions in which the necessarycross-linking could not occur. Cross-linking could suppress activationof the alternative pathway in several ways. First, the antibodycould create a shell at the surface of the capsule and block penetrationof complement components to sites beneath the shell. Second, thecross-linking could create mini-cages within the capsule thatwould allow activation within each cage but would not permit amplificationbeyond the cage. Finally, cross-linking could reduce the rateof diffusion of macromolecules through the capsular matrix suchthat diffusion of metastable C3b from activation sites would beretarded. Given the short half-life of metastable C3b, estimatedat 60 µS (34), decreased diffusion rates could greatly reduceexpansion of focal initiation sites. Regardless of the specificmechanism by which a physical alteration in the capsular matrixoccurs, cross-linking of the capsular matrix would require a multivalentantibody; suppression would occur with intact antibodies and theirF(ab)₂ fragments but would not occur with their Fab fragments.

Our results showed that F(ab)₂ fragments of all three MAbs readily suppressed alternative-pathway-mediated activation andbinding of C3 to the cryptococcal cells. In contrast, Fab fragmentsof two of the three MAbs (MAbs 439 and 3C2) were not suppressive.Fab fragments of the third antibody (MAb 471) showed markedlyreduced suppressive activity, but some suppressive activity remained.These results support the argument that cross-linking of the capsularmatrix is a critical component of antibody-mediated suppressionof the alternative pathway. The mildly anomalous behavior of Fabfragments of MAb 471 may be related to the fact that the serotypespecificity of MAb 471 is slightly different from the specificitiesof MAbs 3C2 and 439 (1). Although it is a less likely explanation,our data do not exclude the alternative possibility that regulationof C3 deposition is a function of a large domain on the polysaccharidelocated near, but not at, the binding site of the suppressiveMAb. In such a case, the adjacent regulatory domain might be blockedby the larger IgG or F(ab)₂ molecules but not the Fab fragment.However, this latter explanation is not consistent with the contributionof IgG isotype to the suppressive effect (Fig. 4).

Reduced binding to the capsule is an alternative explanation for the lack of suppression by Fab fragments. An analysis ofthe binding of intact antibodies, F(ab)₂ fragments, and Fab fragmentsto cryptococcal cells showed that all three forms of the MAbsreadily bound to the cells under the conditions used to assesssuppressive activity. Indeed, approximately two to eight timesmore Fab molecules bound to the cells than did intact molecules.The reduced molecular size of the Fab fragments may allow increasedaccess by Fab fragments to binding sites within the capsular matrix.Alternatively, cross-linking of the capsule by intact antibodiesmay block binding of subsequent antibody molecules.

Because cross-linking of the capsule is a critical component of antibody-mediated suppression, we examined the suppressiveactivity of isotype switch (IgG1 $right-arrow$ IgG2b $right-arrow$ IgG2a) families of MAbs471 and 439. These immunoglobulin isotypes differ in the lengthsof the upper hinge sequences (IgG2b > IgG2a > IgG1) and in theflexibility of the hinge region (also IgG2b > IgG2a > IgG1) (5,26). Results of the comparison showed that MAbs of the IgG1and IgG2a isotypes strongly suppressed alternative-pathway-mediatedbinding of C3. The IgG2b variants of MAbs 471 and 439 were alsosuppressive, but the levels of suppression were reduced and requiredmore antibody to produce the suppressive effect than did the IgG1and IgG2a antibodies. Notably, the IgG2b switch antibody of MAb471 also has a reduced ability to precipitate GXM compared tothe IgG1 and IgG2a antibodies (33). It is not clear why an antibodywith increased hinge flexibility should exhibit decreased suppressionof the alternative pathway. Perhaps antibodies with rigid hingeregions produce tighter cross-linking than antibodies with moreflexibility in the hinge.

An unexpected activity of the Fab fragments was facilitation of early C3 binding via the alternative pathway. Fifty percentof maximum binding occurred 2 min earlier in the presence of Fabfragments of MAbs 439 and 3C2 than in the absence of the MAbs.This accelerated binding of C3 fragments in the presence of Fabfragments was readily evident when immunofluorescence was usedto evaluate the sites for deposition of C3. Cryptococci incubatedfor 2 min in NHS containing Fab fragments of MAb 3C2 showed easilydiscernible C3 that was distributed over the surface of the capsule.In contrast, cryptococci incubated for 2 min in NHS alone showeda few very faint foci of C3.

To date, we have not examined potential mechanisms by which Fab fragments might facilitate the alternative pathway. In a converseof possible mechanisms for inhibition by antibody, the Fab fragmentscould provide favorable binding sites for metastable C3b. Alternatively,the Fab fragments could facilitate the binding or activity offactor B or could block the binding or activity of factor H. Reducedbinding of factor H to particle-bound C3b has been shown to distinguishparticulate activators of the alternative pathway from nonactivators(11, 14, 15, 27).

These studies further illustrate the complexity of the interaction between anti-GXM antibodies and the cryptococcal capsule.Previous studies found that MAbs reactive with cryptococcal serotypesA, B, C, and D suppress alternative-pathway-mediated C3 binding,whereas MAbs reactive with cryptococcal serotypes A and D arenot suppressive (17). Epitope-specific effects of anti-GXM antibodieshave also been demonstrated with other systems. Some anti-GXMIgM MAbs are protective in a murine model of cryptococcosis, whereasIgM MAbs with another specificity are not protective (22, 25).MAbs with the protective specificity produce an annular patternof binding in the capsule; MAbs with the nonprotective specificityproduce a punctate pattern (22, 25). We speculate that thesediverse biological activities have a common molecular mechanism.Identification of a unifying mechanism may prove important inthe selection of MAbs for use in passive immunization (4, 9,23, 24, 30) and in vaccine design for prevention of cryptococcosis(3, 6, 7). Such studies also have the potential to contributeto our understanding of the mechanism of action of antibody-dependentprotection against encapsulated bacteria.

	ACKNOWLEDGMENT

This work was supported by Public Health Service grant AI 14209 from the National Institute of Allergy and Infectious Diseases.

	FOOTNOTES

^* Corresponding author. Mailing address: Department of Microbiology/320, School of Medicine, University of Nevada, Reno, NV89557. Phone: (702) 784-6161. Fax: (702) 784-1620. E-mail: trkozel{at}med.unr.edu.

Editor: V. A. Fischetti

	REFERENCES

Top Abstract Introduction Materials & Methods Results Discussion References

1.	Belay, T., R. Cherniak, T. R. Kozel, and A. Casadevall. 1997. Reactivity patterns and epitope specificities of anti-Cryptococcus neoformans monoclonal antibodies by enzyme-linked immunosorbent assay and dot enzyme assay. Infect. Immun. 65:718-728[Abstract].
2.	Casadevall, A., M. DeShaw, M. Fan, F. Dromer, T. R. Kozel, and L. Pirofski. 1994. Molecular and idiotypic analysis of antibodies to Cryptococcus neoformans glucuronoxylomannan. Infect. Immun. 62:3864-3872[Abstract/Free Full Text].
3.	Casadevall, A., J. Mukherjee, S. J. N. Devi, R. Schneerson, J. B. Robbins, and M. D. Scharff. 1992. Antibodies elicited by a Cryptococcus neoformans-tetanus toxoid conjugate vaccine have the same specificity as those elicited in infection. J. Infect. Dis. 165:1086-1093[Medline].
4.	Casadevall, A., and M. D. Scharff. 1994. Serum therapy revisited: animal models of infection and development of passive antibody therapy. Antimicrob. Agents Chemother. 38:1695-1702[Free Full Text].
5.	Dangl, J. L., T. G. Wensel, S. L. Morrison, L. Stryer, L. A. Herzenberg, and V. T. Oi. 1988. Segmental flexibility and complement fixation of genetically engineered chimeric human, rabbit and mouse antibodies. EMBO J. 7:1989-1994[Medline].
6.	Devi, S. J. 1996. Preclinical efficacy of a glucuronoxylomannan-tetanus toxoid conjugate vaccine of Cryptococcus neoformans in a murine model. Vaccine 14:841-844[Medline].
7.	Devi, S. J. N., R. Schneerson, W. Egan, T. J. Ulrich, D. Bryla, J. B. Robbins, and J. E. Bennett. 1991. Cryptococcus neoformans serotype A glucuronoxylomannan-protein conjugate vaccines: synthesis, characterization, and immunogenicity. Infect. Immun. 59:3700-3707[Abstract/Free Full Text].
8.	Diamond, R. D., J. E. May, M. A. Kane, M. M. Frank, and J. E. Bennett. 1974. The role of the classical and alternate complement pathways in host defenses against Cryptococcus neoformans infection. J. Immunol. 112:2260-2270[Abstract/Free Full Text].
9.	Dromer, F., J. Charreire, A. Contrepois, C. Carbon, and P. Yeni. 1987. Protection of mice against experimental cryptococcosis by anti-Cryptococcus neoformans monoclonal antibody. Infect. Immun. 55:749-752[Abstract/Free Full Text].
10.	Eckert, T. F., and T. R. Kozel. 1987. Production and characterization of monoclonal antibodies specific for Cryptococcus neoformans capsular polysaccharide. Infect. Immun. 55:1895-1899[Abstract/Free Full Text].
11.	Fearon, D. T., and K. F. Austen. 1977. Activation of the alternative complement pathway due to resistance of zymosan-bound amplification convertase to endogenous regulatory mechanisms. Proc. Natl. Acad. Sci. USA 74:1683-1687[Abstract/Free Full Text].
12.	Fine, D. P., S. R. Marney, Jr., D. G. Colley, J. S. Sergent, and R. M. Des Prez. 1972. C3 shunt activation in human serum chelated with EGTA. J. Immunol. 109:807-809[Abstract/Free Full Text].
13.	Fraker, P. J., and J. C. Speck, Jr. 1978. Protein and cell membrane iodinations with a sparingly soluble chloroamide, 1,3,4,6-tetrachloro-3a,6a-diphenylglycoluril. Biochem. Biophys. Res. Commun. 80:849-857[Medline].
14.	Horstmann, R. D., M. K. Pangburn, and H. J. Müller-Eberhard. 1985. Species specificity of recognition by the alternative pathway of complement. J. Immunol. 134:1101-1104[Abstract].
15.	Kazatchkine, M. D., D. T. Fearon, and K. F. Austen. 1979. Human alternative complement pathway: membrane-associated sialic acid regulates the competition between B and $beta$ 1H for cell-bound C3b. J. Immunol. 122:75-81[Abstract/Free Full Text].
16.	Kozel, T. R. 1996. Activation of the complement system by pathogenic fungi. Clin. Microbiol. Rev. 9:34-46[Abstract].
17.	Kozel, T. R., B. C. H. deJong, M. M. Grinsell, R. S. MacGill, and K. K. Wall. 1998. Characterization of anticapsular monoclonal antibodies that regulate activation of the complement system by the Cryptococcus neoformans capsule. Infect. Immun. 66:1538-1546[Abstract/Free Full Text].
18.	Kozel, T. R., and G. S. T. Pfrommer. 1986. Activation of the complement system by Cryptococcus neoformans leads to binding of iC3b to the yeast. Infect. Immun. 52:1-5[Abstract/Free Full Text].
19.	Kozel, T. R., G. S. T. Pfrommer, A. S. Guerlain, B. A. Highison, and G. J. Highison. 1988. Strain variation in phagocytosis of Cryptococcus neoformans: dissociation of susceptibility to phagocytosis from activation and binding of opsonic fragments of C3. Infect. Immun. 56:2794-2800[Abstract/Free Full Text].
20.	Kozel, T. R., M. A. Wilson, and J. W. Murphy. 1991. Early events in initiation of alternative complement pathway activation by the capsule of Cryptococcus neoformans. Infect. Immun. 59:3101-3110[Abstract/Free Full Text].
21.	Kozel, T. R., M. A. Wilson, G. S. T. Pfrommer, and A. M. Schlageter. 1989. Activation and binding of opsonic fragments of C3 on encapsulated Cryptococcus neoformans by using an alternative complement pathway reconstituted from six isolated proteins. Infect. Immun. 57:1922-1927[Abstract/Free Full Text].
22.	Mukherjee, J., G. Nussbaum, M. D. Scharff, and A. Casadevall. 1995. Protective and non-protective monoclonal antibodies to Cryptococcus neoformans originating from one B-cell. J. Exp. Med. 181:405-409[Abstract/Free Full Text].
23.	Mukherjee, J., L. Pirofski, M. D. Scharff, and A. Casadevall. 1993. Antibody-mediated protection in mice with lethal intracerebral Cryptococcus neoformans infection. Proc. Natl. Acad. Sci. USA 90:3636-3640[Abstract/Free Full Text].
24.	Mukherjee, J., M. D. Scharff, and A. Casadevall. 1992. Protective murine monoclonal antibodies to Cryptococcus neoformans. Infect. Immun. 60:4534-4541[Abstract/Free Full Text].
25.	Nussbaum, G., W. Cleare, A. Casadevall, M. D. Scharff, and P. Valadon. 1997. Epitope location in the Cryptococcus neoformans capsule is a determinant of antibody efficacy. J. Exp. Med. 185:685-695[Abstract/Free Full Text].
26.	Oi, V. T., T. M. Vuong, R. Hardy, J. Reidler, J. Dangl, L. A. Herzenberg, and L. Stryer. 1984. Correlation between segmental flexibility and effector function of antibodies. Nature 307:136-140[Medline].
27.	Pangburn, M. K., and H. J. Müller-Eberhard. 1978. Complement C3 convertase: cell surface restriction of $beta$ 1H control and generation of restriction on neuraminidase-treated cells. Proc. Natl. Acad. Sci. USA 75:2416-2420[Abstract/Free Full Text].
28.	Platts-Mills, T. A. E., and K. Ishizaka. 1974. Activation of the alternative pathway of human complement by rabbit cells. J. Immunol. 113:348-357[Abstract/Free Full Text].
29.	Sahu, A., T. R. Kozel, and M. K. Pangburn. 1994. Specificity of the thioester-containing reactive site of human C3 and its significance to complement activation. Biochem. J. 302:429-436.
30.	Sanford, J. E., D. M. Lupan, A. M. Schlageter, and T. R. Kozel. 1990. Passive immunization against Cryptococcus neoformans with an isotype-switch family of monoclonal antibodies reactive with cryptococcal polysaccharide. Infect. Immun. 58:1919-1923[Abstract/Free Full Text].
31.	Savoy, A. C., D. M. Lupan, P. B. Manalo, J. S. Roberts, A. M. Schlageter, L. C. Weinhold, and T. R. Kozel. 1997. Acute lethal toxicity following passive immunization for treatment of murine cryptococcosis. Infect. Immun. 65:1800-1807[Abstract].
32.	Scatchard, G. 1949. The attractions of proteins for small molecules and ions. Ann. N. Y. Acad. Sci. 51:660-672.
33.	Schlageter, A. M., and T. R. Kozel. 1990. Opsonization of Cryptococcus neoformans by a family of isotype-switch variant antibodies specific for the capsular polysaccharide. Infect. Immun. 58:1914-1918[Abstract/Free Full Text].
34.	Sim, R. B., T. M. Twose, D. S. Paterson, and E. Sim. 1981. The covalent-binding reaction of complement component C3. Biochem. J. 193:115-127[Medline].
35.	Spiropulu, C., R. A. Eppard, E. Otteson, and T. R. Kozel. 1989. Antigenic variation within serotypes of Cryptococcus neoformans detected by monoclonal antibodies specific for the capsular polysaccharide. Infect. Immun. 57:3240-3242[Abstract/Free Full Text].
36.	Tack, B. F., J. Janatova, M. L. Thomas, R. A. Harrison, and C. H. Hammer. 1981. The third, fourth, and fifth components of human complement: isolation and biochemical properties. Methods Enzymol. 80:64-101.
37.	Wilson, M. A., and T. R. Kozel. 1992. Contribution of antibody in normal human serum to early deposition of C3 onto encapsulated and nonencapsulated Cryptococcus neoformans. Infect. Immun. 60:754-761[Abstract/Free Full Text].
38.	Young, B. J., and T. R. Kozel. 1993. Effects of strain variation, serotype and structural modification on the kinetics for activation and binding of C3 to Cryptococcus neoformans. Infect. Immun. 61:2966-2972[Abstract/Free Full Text].

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