Neutralizing Antibodies Protect against Lethal Flavivirus Challenge but Allow for the Development of Active Humoral Immunity to a Nonstructural Virus Protein

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J Virol, April 1998, p. 3076-3081, Vol. 72, No. 4
0022-538X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.

Neutralizing Antibodies Protect against Lethal Flavivirus Challenge but Allow for the Development of Active Humoral Immunity to a Nonstructural Virus Protein

Thomas R. Kreil,¹^,^* Elisabeth Maier,¹ Sabine Fraiss,¹ and Martha M. Eibl²

IMMUNO AG, A-1220 Vienna,¹ and Institute for Immunology, A-1090 Vienna,² Austria

Received 8 September 1997/Accepted 23 December 1997

	ABSTRACT

Top Abstract Introduction Materials & Methods Results Discussion References

Antibody-mediated neutralization of viruses has been extensively studied in vitro, but the precise mechanisms that accountfor antibody-mediated protection against viral infection in vivostill remain largely uncharacterized. The two points under discussionare antibodies conferring sterilizing immunity by neutralizingthe virus inoculum or protection against the development of diseasewithout complete inhibition of virus replication. For tick-borneencephalitis virus (TBEV), a flavivirus, transfer of neutralizingantibodies specific for envelope glycoprotein E protected micefrom subsequent TBEV challenge. Nevertheless, short-term, low-levelvirus replication was detected in these mice. Furthermore, micethat were exposed to replicating but not to inactivated viruswhile passively protected developed active immunity to TBEV rechallenge.Despite the priming of TBEV-specific cytotoxic T cells, adoptivetransfer of serum but not of T cells conferred immunity upon naiverecipient mice. These transferred sera were not neutralizing andwere predominantly specific for NS1, a nonstructural TBEV proteinwhich is expressed in and on infected cells and which is alsosecreted from these cells. Results of these experiments showedthat despite passive protection by neutralizing antibodies, limitedvirus replication occurs, indicating protection from disease ratherthan sterilizing immunity. The protective immunity induced byreplicating virus is surprisingly not T-cell mediated but is dueto antibodies against a nonstructural virus protein absent fromthe virion.

	INTRODUCTION

Top Abstract Introduction Materials & Methods Results Discussion References

For flaviviruses, envelope glycoprotein E plays a central role in the viral life cycle, and the importance of antibodies toE in antiviral protection has been demonstrated by passive transferexperiments (12, 30). Whereas some studies have shown in vivoprotection only by in vitro neutralizing antibodies (13, 23),others have shown antibody-mediated protection irrespective ofin vitro neutralization (2). More generally, antibody-mediatedneutralization of viruses has been extensively studied in vitro(6), but the precise mechanisms that account for antibody-mediatedprotection against viral infection in vivo still remain largelyuncharacterized. The two points under discussion are antibodiesconferring sterilizing immunity by neutralizing the virus inoculum(29) or protection against the development of disease, not essentiallysynonymous with the complete inhibition of virus replication (15).

Tick-borne encephalitis virus (TBEV), a flavivirus highly pathogenic for humans, is endemic in several European countries,Russia, and China. Transfer of monoclonal antibodies specificfor TBEV E (13, 25, 26) or of E-specific antisera as wellas of polyclonal immunoglobulin preparations with the same specificities(14, 16, 21) into mice resulted in protection of experimentalanimals from subsequent TBEV challenge, and in vivo protectionby antivirion antibodies correlated with in vitro neutralization(13, 25, 26). In a recent study (21), we confirmed theprotection of mice against a lethal intraperitoneal (i.p.) TBEVchallenge by E-specific antibodies. Infectious virus could notbe detected in the blood or brain of passively protected micesubsequent to TBEV challenge. Local virus replication, however,might have gone undetected in these experiments. To answer thequestion of whether passive antibody-mediated immunity to TBEVreflects protection against disease or sterilization of the TBEVinoculum, we sought to refine our method for the determinationof infectious virus in passively protected animals. Furthermore,because low levels of virus replication are known to induce long-lastingand even lifelong immunity for other viruses, we rechallengedmice exposed to TBEV under passive protection after the passivelyadministered antibodies had disappeared from these animals. Resultsof these experiments showed that limited virus replication occursin animals passively protected by neutralizing antibodies and,as a consequence, these animals develop long-lasting immunityto TBEV challenge.

	MATERIALS AND METHODS

Top Abstract Introduction Materials & Methods Results Discussion References

Animals. Female BALB/c mice (Charles River Wiga, Sulzfeld, Federal Republic of Germany) were given dry food pellets and water ad libitumand were used for experiments at 15 to 17 g of body weight.

Virus. TBEV, a flavivirus (37), was kindly donated by P. Noel Barrett (Biomedical Research Center, IMMUNO AG, Orth/Donau, Austria).The virus was titrated by a plaque assay on PS cells as describedpreviously (21), and the concentrations of infectious TBEV areexpressed as PFU per milliliter of sample.

To detect TBEV in blood, brain, spleen, or peritoneal exudate cells (PEC) of infected animals with a high sensitivity, specimensobtained from two donor mice after TBEV challenge were preparedas outlined below, and one-third of the resulting sample was transferredi.p. into each of three recipient mice. Blood was asepticallycollected by cardiac puncture of ether-anesthetized animals, andthe approximately 1-ml sample obtained was diluted with an equalvolume of phosphate-buffered saline (PBS) before transfer. Brainsor spleens were aseptically removed and, after the addition ofan equal volume of PBS, homogenized through steel mesh. PEC werewashed from the peritoneal cavity, pelleted by centrifugation,and resuspended in PBS for transfer. After transfer, survivalof recipient mice was monitored for 28 days. As determined byspiking of samples with TBEV, the limit of detection of this methodis approximately 10 PFU/organ (22).

Inactivation of TBEV. When needed TBEV was inactivated by treatment with UV-psoralen. As described earlier (20), the infectivity of TBEV is entirelylost after exposure for 10 min to UV A irradiation at 2 mW/cm² in the presence of 1 µg of 4'-aminomethyl-4, 5'-8-trimethylpsoralenhydrochloride (Lee Biomolecular Research Inc., San Diego, Calif.)per ml.

TBEV exposure and passive protection of mice. Mice were experimentally inoculated with virus by i.p. injection of 0.2 ml of an appropriately diluted TBEV stock containing1,000 PFU of TBEV, with approximately 4 PFU comprising a 50% lethaldose (21). When needed, other challenge doses were used or thevirus was administered intravenously (i.v.) to experimental animals.Passive protection of mice was achieved by subcutaneous (s.c.)administration of 0.2 ml of either a preparation of human TBEVimmunoglobulin (Ig) or mouse TBEV hyperimmune serum, diluted withPBS (for details, see reference 21). The human TBEV Ig preparationis commercially available (FSME BULIN; IMMUNO AG, Vienna, Austria;90 to 153 mg of gamma globulin per ml; hemagglutination inhibition[HAI] titer [mean ± standard error of the mean {SEM}; 16 determinations],1:1,100 ± 60; neutralization titer [NT] [mean ± SEM; 9 determinations],1:4,406 ± 518), and mouse TBEV hyperimmune serum was preparedfrom blood collected by retro-orbital puncture under light etheranesthesia from mice hyperimmunized with a commercially availablewhole killed virus vaccine (FSME IMMUN Inject; IMMUNO AG; HAItiter [mean ± SEM; 6 determinations], 1:747 ± 107; NT [mean ±SEM; 6 determinations], 1:983 ± 126). Survival of TBEV-exposedanimals was monitored for at least 28 days after infection oruntil no further deaths occurred for another 7 days.

Transfer of serum, spleen cells, or T-enriched spleen cells. Serum was prepared from blood collected by retro-orbital puncture from ether-anesthetized mice and was administered i.v. tonaive animals. Spleens were aseptically removed, and a spleensingle-cell suspension (SPC) was prepared by maceration of spleensthrough steel mesh. After hemolysis (hypotonic NH₄Cl buffer),cells were counted and appropriately diluted in PBS for transfer.T-enriched cells were prepared from crude spleen cells with nylonwool columns (18) and were judged to contain approximately 80%T cells by staining for the Thy-1.2 antigen in a fluorescence-activatedcell sorter analysis (data not shown). Both spleen cells and T-enrichedspleen cells were administered i.p. to naive animals.

ELISA for TBEV antibodies. An enzyme-linked immunosorbent assay (ELISA) was performed with formaldehyde-inactivated TBEV as a coating antigen and a goatanti-mouse immunoglobulin G (IgG)-horseradish peroxidase conjugate(Accurate Chemical & Scientific Corp., Westbury, N.Y.) for thedetection of bound antibodies. Serial twofold dilutions of sampleswere tested in duplicate, and titers were the highest dilutionyielding greater than twofold the absorption of a control mouseserum, with the cutoff value being set to 1:100.

NT₅₀. TBEV neutralization was tested as described previously (21). Briefly, serial dilutions of samples were incubated with 100tissue culture infective doses of TBEV, and then the mixtureswere incubated for 7 days on TBEV-susceptible Vero cell (CCL-81;American Type Culture Collection [ATCC]) monolayers. The resultingtissue culture supernatants were tested for the presence of TBEVantigen, indicative of TBEV replication, by an ELISA, and thesample dilution resulting in virus neutralization in 50% of thereplicates (NT₅₀) was calculated.

HAI titer. Serial dilutions of samples were incubated with TBEV, and then triplicates of the resulting samples were incubated with gooseerythrocytes to allow antibody-free TBEV to induce hemagglutination.The HAI titer was the reciprocal of the highest sample dilutionresulting in complete HAI.

Western blotting. TBEV-infected 3T3 fibroblasts (CCL-92; ATCC) were lysed with NP-40 buffer (20 mM Tris, 150 mM NaCl, 1% Nonidet P-40 [pH 7.5])containing phenylmethylsulfonyl fluoride (2 mM), aprotinin (10µg/ml), and leupeptin (10 µg/ml), and the proteins were separatedby nonreducing sodium dodecyl sulfate-polyacrylamide gel electrophoresis,either with or without heating of the samples for 2 min to 100°C.For calculation of the apparent molecular weights of proteins,a standard was included with all gels (SeeBlue; NOVEX, San Diego,Calif.). Proteins were transferred to nitrocellulose by electroblotting,the membranes were blocked with skim milk powder (5% in PBS),and the blotted proteins were incubated with antisera that hadbeen preadsorbed to uninfected-cell lysates at various dilutions(see Fig. 2). Bound antibodies were reacted with horseradish peroxidase-coupledanti-mouse IgG (Jackson Immuno Research Laboratories Inc., WestGrove, Pa.) as a second step, and bands were visualized by enhancedchemiluminescence (ECL kit; Amersham LIFE SCIENCE, Buckinghamshire,United Kingdom). The identity of TBEV surface protein E or TBEVnonstructural protein NS1 on Western blots was confirmed by stainingof sera obtained from mice immunized either with a whole killedTBEV vaccine (FSME IMMUN Inject) or with Escherichia coli-derivedrecombinant NS1 protein (generously provided by Barbara Plaimauer,IMMUNO AG; 26a).

⁵¹Cr release assay. Spleens were obtained from three or more donor mice after cervical dislocation, and an SPC was prepared from the pooled organs.After restimulation of SPC for 5 days with live TBEV at a multiplicityof infection of 0.2 as described by Rothman et al. (31), theSPC was tested for cytotoxic activity. P815 cells (TIB-64; ATCC)were either used as uninfected control target cells or infectedwith TBEV at a multiplicity of infection of 1 for 7 days, resultingin approximately 90% TBEV-infected cells, as judged by immunofluorescence.The target cells were labeled with Na⁵¹CrO₄ (400 µCi per 5 × 10⁶ cells), and 10⁴ target cells were incubated with restimulated effector cellsat various effector/target cell ratios for 4 h. ⁵¹Cr release in supernatants was determined, and specific releasewas calculated as [(experimental release $-$ spontaneous release)/(maximumrelease $-$ spontaneous release)] × 100. For the results obtained,the mean ± SEM of virus-specific cytotoxicity (percent releasefrom TBEV-infected target cells $-$ percent release from uninfectedcontrol target cells) is reported.

	RESULTS

Top Abstract Introduction Materials & Methods Results Discussion References

After challenge of passively protected mice, low levels of TBEV can be recovered. When in a recent study blood and brain samples from mice passively protected with TBEV antibodies (0.2 ml of a human TBEVIg preparation diluted 1:10 in PBS and delivered s.c.) were obtainedat daily intervals after i.p. challenge with 1,000 PFU of TBEVand tested for the presence of infectious TBEV by a plaque assayor by sample transfer into naive recipient mice (a more sensitiveassay) (22), no virus was detectable up to the time at whichunprotected control mice died (21). To detect the eventual localreplication of TBEV, we also tested spleen cells or PEC from passivelyprotected mice for TBEV replication by sample transfer in thisstudy. Organs from antibody-protected mice were thus obtainedat daily intervals after i.p. TBEV exposure (1,000 PFU per mouse),the samples from two donor mice were pooled, and equal volumesof the specimens were transferred into each of three naive recipientmice (see Materials and Methods). While the transfer of blood,brain, or spleen samples was never lethal for recipient mice,the transfer of PEC induced lethality in recipient mice. For threeexperiments, however, TBEV was only detectable on a single dayafter TBEV exposure, i.e., on day 3, 4, or 6, and resulted inTBEV-induced death in two, two, or one of the three recipients,respectively. These low levels of lethality in recipient mice(67, 67, and 33%) were recently determined to correspond to 1to 10 PFU of TBEV in the samples (22). Thus, despite passiveprotection by TBEV antibodies, short-term, low-level virus replicationcan be detected after virus exposure. Among mice receiving identicallyprepared tissues from uninfected mice, none died in several consecutiveexperiments.

TBEV exposure under passive protection results in active immunity. As demonstrated earlier (21), s.c. treatment of mice with a human TBEV Ig preparation (diluted 1:10) or a mouse TBEV hyperimmuneserum (diluted 1:3) 2 h prior to a lethal i.p. TBEV challenge(1,000 PFU) resulted in complete protection against the developmentof tick-borne encephalitis. After 28 or 70 days, i.e., at a timewhen protection by passively administered human or mouse TBEVantibodies had declined to low residual levels, the animals wererechallenged with TBEV. As a control for the decline of passiveprotection, groups of mice were initially treated with eitherhuman or murine TBEV Ig but were left unchallenged. As antibody-neutralizednonreplicating virus might also induce an immune response, anothergroup of animals was treated with TBEV antibodies and UV-inactivatedTBEV corresponding in amount to the challenge dose, i.e., 1,000PFU. Only a low percentage of mice $---$ or none at all $---$ that receivedthe initial passive protection regimen without TBEV challengesurvived when challenged with TBEV 28 or 70 days later (Table1), indicative of few residual TBEV antibodies present at thetime of rechallenge. In contrast, mice that were initially challengedwith infectious TBEV while being passively protected by TBEV antibodieswere immune to this second TBEV exposure. Active immunity in thesemice was not the result of previous exposure to nonreplicatingviral antigen, as mice that were injected with the same amountof UV-inactivated TBEV succumbed to this second TBEV exposure.To determine the minimum dose of infectious virus required atthe first challenge to induce this immunity, different amountsof TBEV were applied to passively protected animals. As shownin Fig. 1, there was a dose-dependent relationship between thedose of the initial TBEV challenge and the resulting degree ofimmunity to rechallenge, with as little as 10 PFU at the firstchallenge significantly increasing survival of rechallenge.

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TABLE 1. Rechallenge after initial TBEV exposure under passive protection^a

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FIG. 1. Active immunity to TBEV. Female BALB/c mice were administered s.c. 0.2 ml of a 1:10-diluted human TBEV Ig preparation 2 h before they were injected i.p. with different amounts of TBEV (1,000, 100, 10, 1, or 0.1 PFU per animal), with PBS, or with the equivalent of 1,000 PFU of UV-psoralen-inactivated TBEV. After 28 days (d), mice were rechallenged i.p. with 1,000 PFU of TBEV, and their survival was monitored for 28 days or until no further deaths occurred for a consecutive week. The data presented are cumulative survival in percentages from three to eight independent experiments with 10 animals per group in each experiment. Differences in the survival of groups of mice were compared to the survival of mice which received UV-inactivated TBEV instead of the initial TBEV challenge by a two-sided log-rank test, and significances are indicated by asterisks (P < 0.0001).

Active immunity after TBEV exposure under passive protection can be transferred by serum. To determine the effector mechanisms of the observed TBEV immunity, mice were treated with human TBEV antibodies (0.2 ml,1:10 in PBS, s.c.) and challenged 2 h later with TBEV (1,000 PFUi.p.). At 28 days after this first TBEV challenge, the mice wereused for further experiments or received another i.p. challengewith 1,000 PFU of TBEV and were used 28 days after this secondchallenge. Titers of TBEV E-specific antibodies in serum weretested by an ELISA (five experiments with 10 mice each; sera from2 to 10 mice were pooled) after the first or the second challenge.Both, however, were found to be low to negative (mean ± SEM afterthe first challenge, 1:180 ± 100, 25 determinations; after thesecond challenge, 1:230 ± 160, 19 determinations). A positivecontrol, i.e., serum from mice immunized with FSME IMMUN Inject,validated the ELISA (mean ± SEM, 1:46,280 ± 11,090, 13 determinationsfrom seven experiments; sera from 2 to 10 mice were pooled). Serafrom mice after both single and double challenges were furthermorefound to be nonneutralizing in a TBEV NT₅₀ test (i.e., NT, <1:2,six determinations each from six experiments; sera from two micewere pooled).

To identify the mechanism responsible for the observed protective immunity to TBEV, serum, crude spleen cells, or T-enrichedspleen cells from 6 to 30 donor animals were pooled after survivalof the second challenge and were then transferred into naive recipients.Recipient animals were subsequently challenged i.p. with 1,000PFU of TBEV per animal. Table 2 shows that i.p. transfer of crude(10⁸) or of T-enriched (4 × 10⁷) spleen cells 2 h prior to challenge exerted no significant influenceon the percent survival or mean survival times (MST) of the recipientanimals. In contrast, i.v. transfer of serum (0.2 ml each at 2days and 2 h before challenge) conferred complete protection uponnaive recipient animals. When combinations of serum and cellswere transferred into naive mice, they did not provide protectionin excess of that provided by serum alone. In experiments withdonors after a single challenge, serum provided partial protection,whereas crude or T-enriched spleen cells had no effect; transferof serum or crude or T-enriched spleen cells from naive controlanimals had no effect (data not shown).

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TABLE 2. Adoptive transfer of serum, spleen cells, or T-enriched spleen cells^a

Humoral immunity is predominantly specific for a nonstructural virus protein. As demonstrated by the transfer experiments, protective immunity that developed after TBEV challenge under passive protectioncould be passed to naive recipients only by immune serum. Thisserum, as well as that obtained from mice after the first challenge,however, had low to negative titers of TBEV E-specific antibodiesin an ELISA and negative titers in a TBEV NT₅₀ test. Thus, serafrom mice after a single challenge were tested by Western blottingfor reactivity with different TBEV proteins; TBEV-infected cellswere used as the blotted antigen. Depending on whether sampleswere boiled or not prior to use in nonreducing sodium dodecylsulfate-polyacrylamide gel electrophoresis, sera from mice renderedimmune by having survived a TBEV challenge under passive protection(Fig. 2, lanes 3 and 4, sera pooled from 10 donor mice) stainedproteins with apparent molecular masses of approximately 45 and88 kDa on Western blots, as well as a heat-stable protein of approximately51 kDa. The size and behavior upon heating of these proteins werein agreement with those of the NS1 protein monomer (heated) anddimer (unheated) (39) and protein E of TBEV, respectively. Theidentity of these proteins was subsequently confirmed by use ofmurine sera specific for either the E protein (Fig. 2, lanes 5and 6) or the NS1 protein (lanes 1 and 2) of TBEV.

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FIG. 2. Reactivity of mouse sera with TBEV proteins. A Western blot of a lysate of TBEV-infected cells (5 × 10⁵ cells per lane) was prepared as described in Materials and Methods, either with (lanes 1, 3, and 5) or without (lanes 2, 4, and 6) heating of the samples to 100°C prior to electrophoresis. The membrane was then probed with an NS1 antiserum (lanes 1 and 2), serum obtained from mice 28 days after they were challenged with TBEV while being passively protected (lanes 3 and 4), or an E-monospecific TBEV hyperimmune serum (lanes 5 and 6), all diluted 1:300. Bound antibodies were subsequently reacted with the second-step antibody and visualized by enhanced chemiluminescence. gE, glycoprotein E.

TBEV replication under passive protection induces CTL activity. Virus replication in vivo is recognized to induce cytotoxic T-cell (CTL) responses. Although virus replication after TBEVchallenge of passively protected mice was demonstrated above,T cells from these mice could not confer protection upon naiverecipient mice. To directly determine eventual CTL priming, spleencells were obtained from mice having survived a TBEV challengeunder passive protection. After in vitro restimulation with TBEVfor 5 days (31), these cells were tested for TBEV-specific cytolysisin a ⁵¹Cr release assay on TBEV-infected or uninfected control P815 targetcells. In parallel, spleen cells from mice immunized three timesat 3-week intervals with a commercially available whole killedTBEV vaccine (FSME IMMUN Inject, 0.2 ml s.c., diluted 1:10 inPBS) were tested as a control. Hyperimmunization with the wholekilled TBEV vaccine did not induce detectable TBEV-specific ⁵¹Cr release in our experiments (Fig. 3A). In contrast, however,mice that had been challenged with TBEV while being passivelyprotected by TBEV antibodies manifested pronounced TBEV-specificcytotoxic activity (Fig. 3B).

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FIG. 3. TBEV-specific ⁵¹Cr release assay. Spleen cells were obtained from mice vaccinated with a whole killed TBEV vaccine (A) or from mice passively protected by administration of human TBEV antibodies after they had been challenged with TBEV (B). After in vitro restimulation with TBEV, cells were tested for cytotoxicity against TBEV-infected or uninfected control P815 cells in a ⁵¹Cr release assay. Percent specific lysis [(experimental release $-$ spontaneous release)/(maximum release $-$ spontaneous release)] × 100, all in counts per minute, at the indicated effector/target cell ratios is given as TBEV-specific lysis (percent lysis of TBEV-infected target cells $-$ percent lysis of uninfected control target cells). The results presented are the means ± SEM for four (A) or five (B) experiments. The significance of the differences between the lysis of uninfected target cells (about 20%) and that of TBEV-infected target cells, i.e., the significance of TBEV-specific lysis, was tested by a paired Student's t test; the results are indicated as follows: *, P < 0.05; ns, not significant.

Neutralization occurs in vitro but cannot be accomplished in vivo. Results so far indicated short-term, low-level TBEV replication in vivo, despite passive protection by TBEV antibodies withneutralizing capacity in vitro. To determine whether this resultwas due to insufficient concentrations of TBEV antibodies, thefollowing experiments were performed. Mice were treated s.c. with1:10-diluted human TBEV Ig as before; after 2 days, i.e., whenTBEV antibodies have reached their maximum concentration in serum(21), some animals were challenged i.v. with TBEV, whereas otherswere bled for serum. Aliquots (0.1 ml) of these sera were thenincubated for 1 h with an equivalent of the TBEV challenge dose,i.e., 1,000 or 100 PFU, contained in a volume of 0.1 ml of PBS.These virus-Ig mixtures were further applied to PS cell monolayersfor a plaque assay. Sera from mice treated with the 1:10-dilutedTBEV Ig showed close to complete neutralization of 1,000 PFU ofTBEV (residual virus, 2.3% ± 0.8%; six experiments), while 100PFU was always entirely neutralized in vitro. The protective immuneresponse with NS1 specificity was nevertheless comparably inducedafter i.v. challenge with 100 or 1,000 PFU of TBEV (Fig. 1). Theseresults suggest that under conditions that are generally suitedfor neutralization in vitro, complete neutralization does notnecessarily occur in vivo.

	DISCUSSION

Top Abstract Introduction Materials & Methods Results Discussion References

As demonstrated earlier, the administration of a human TBEV Ig preparation or mouse TBEV hyperimmune serum protected miceagainst an otherwise highly lethal challenge with TBEV (21).The precise mechanism of protection, however, has remained enigmatic.Here we demonstrate that infectious TBEV can be recovered frompassively protected mice, although in very small amounts and fora short period. These results indicate that short-term, low-levelvirus replication takes place in passively protected animals.Antibody treatment thus provides protection from disease, notprotection from infection. For many viruses, low-level replicationis known to potently induce long-lasting or even lifelong immunity,a phenomenon that has been successfully exploited by some of themost efficient antiviral vaccines available. In agreement withthis notion, only infectious virus induced immunity to rechallengein our experiments (Table 1), and the resulting degree of immuneprotection was directly related to the amount of infectious virusinitially administered to the experimental animals (Fig. 1). Asonly replicating virus induced the immunity observed, T-cell-mediatedeffector mechanisms were considered a likely explanation. To providedirect proof for such effector mechanisms, adoptive-transfer experimentswere performed. Surprisingly, however, only the transfer of serumprovided some passive protection (donors after a single challenge;data not shown) or almost complete passive protection (donorsafter a double challenge; Table 2) for naive recipient mice;the transfer of crude or T-enriched spleen cells had no effect(donors after a first challenge; data not shown) (donors aftera second challenge; Table 2).

Providing further evidence of virus replication in these animals, serum antibodies from animals actively immune after survivalof an initial virus challenge (Fig. 2) as well as after survivalof a second virus challenge (data not shown) showed a predominantspecificity for NS1, a flavivirus protein which is expressed withinand on virus-infected cells (8, 33, 38) and is secretedfrom these cells (4, 8, 27) but which is not containedwithin the virion. Protection by antibodies to the NS1 proteinhas been described for several flaviviruses (9) and for TBEV(17). As the sera were negative in TBEV neutralization assaysand furthermore had a borderline TBEV E ELISA titer, the pronouncedreactivity with the TBEV NS1 protein likely represents the maineffector mechanism of the immunity discussed. Although a contributionto protection by antibodies recognizing the native E protein,as detected in Western blots, cannot be formally ruled out, acomparison of these sera with an E-monospecific TBEV hyperimmuneserum (ELISA titer, 1:180 ± 100 versus 1:46,280 ± 11,090; NT,negative versus 1:983 ± 126; see Materials and Methods) whichconfers complete protection under identical challenge conditionsonly when administered to mice concentrated or as a 1:3 dilution(21) makes a major role for these E-specific antibodies in protectionunlikely. The seeming discrepancy between E staining of the seraon Western blots and only a borderline ELISA titer of these samesera is not considered to arise from differences in the sensitivitiesof the two methods. Rather it may be due to the different natureof the test antigens, i.e., formaldehyde-inactivated TBEV particles(denatured) in the ELISA versus TBEV-infected cell lysates (native)on Western blots.

The induction of high levels of NS1 antibodies as compared to rather low levels of E antibodies by virus replication in passivelyprotected mice may seem discrepant. It is known, however, thatthe presence of antibodies may specifically suppress the inductionof a primary immune response to the respective antigen (32);this fact has been demonstrated for the TBEV E protein as well(19). This fact is increasingly recognized to be of particularimportance for simultaneous passive and active immunization (10,24, 36), and coligation of the Fc receptor on B cells (Fcgamma RIIB1) with the B-cell antigen receptor, leading to abortiveB-cell antigen receptor signaling, has been suggested as a mechanism(5). As human Ig is able to bind to mouse Fc receptors (28),the presence of E antibodies in the course of antigen exposure,i.e., virus challenge in the described model, may thus explainthe reduced amounts of E antibodies actively produced. Alternatively,NS1, in contrast to E, is expressed on the surface of infectedcells (8, 38) and even secreted from them (4, 27) andmay therefore be more readily available for the induction of ahumoral immune response.

Clearance from mice of TBEV-infected cells, at least some of which reside in the peritoneal cavity of these animals, wouldin our model be accomplished by the upcoming antibody responseto NS1, a protein which in addition to being secreted is alsoexpressed on the surface of infected cells (8, 38). Consistentwith this idea, antibody-dependent cellular cytotoxicity (34)and complement-mediated lysis (33) of flavivirus-infected cells,as mediated by NS1 antibodies, have both been demonstrated. Alternatively,the TBEV-specific CTL activity (Fig. 3B) that we demonstratedin the present study might have served to eliminate virus-infectedcells from the challenged mice.

Protection against tick-borne encephalitis by neutralizing antibodies is not brought about by sterilizing immunity, i.e.,extensive neutralization of the virus inoculum; low-level virusreplication does occur. Failure of in vivo neutralization wasobserved despite conditions in experimental animals suitable forin vitro neutralization of the amount of virus used for challenge.Such a situation was recently also described for human immunodeficiencyvirus (HIV) (3), but in contrast to our results, chimpanzeesin those experiments were not protected against the developmentof disease. For HIV, however, follicular dendritic cells wereshown earlier to harbor antibody-neutralized virus such that itmay subsequently be transmitted to susceptible target cells (11).A similar mechanism allowing for local virus replication despitethe presence of neutralizing antibodies may also be operativein our model. Whereas for HIV the ubiquitous presence of targetcells did not allow for protection against disease by neutralizingantibodies, TBEV is a neurotropic virus, and the passive-protectionregimen used in our study precluded its gaining access to itstarget organ, the brain. Thus, while local virus replication gaverise to active immunity, disease did not occur. The developmentof active immunity following virus exposure under passive antibody-mediatedprotection was observed earlier for hepatitis A virus (40).However, the development of immunity was preceded by abnormalliver functions indicative of subclinical infection (7, 35),so the symptoms resulting from hepatitis A virus infection ofits target organ, the liver, were only ameliorated by Ig treatment.

Results from our present study showed that protection against infection by a flavivirus was readily afforded by the administrationof TBEV-neutralizing antibodies. Neutralization, however, didnot occur in vivo. As recently suggested by others (1), thebasis for the widely used correlation between in vitro neutralizationand in vivo protection must be reexamined.

	ACKNOWLEDGMENTS

We thank Ingrid Burger and Eva Attakpah for skillful help with animal experimentation, Barbara Plaimauer for generously providingTBEV NS1 protein, P. Noel Barrett for constructive advice andfor providing TBEV, Aysen Samstag and Katja Olas for TBEV ELISAtesting, and Oskar Enzersberger and Friedrich Dorner for providingTBEV neutralization testing (all from IMMUNO AG, Vienna, Austria).Also, we are grateful to Alan L. Rothman (University of Massachusetts,Worcester) for sharing details on the assay of flavivirus-specificCTLs.

We thank IMMUNO AG for financial support.

	FOOTNOTES

^* Corresponding author. Mailing address: IMMUNO AG, Industriestrasse 67, A-1220 Vienna, Austria. Phone: 43-1-20100-4640. Fax:43-2212-2716. E-mail: kreilt{at}baxter.com.

REFERENCES

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

1. Bachmann, M. F., U. Kalinke, A. Althage, G. Freer, C. Burkhart, H. Roost, M. Aguet, H. Hengartner, and R. M. Zinkernagel. 1997. The role of antibody concentration and avidity in antiviral protection. Science 276:2024-2027[Abstract/Free Full Text].

2. Brandriss, M. W., J. J. Schlesinger, E. E. Walsh, and M. Briselli. 1986. Lethal 17D yellow fever encephalitis in mice. I. Passive protection by monoclonal antibodies to the envelope proteins of 17D yellow fever and dengue 2 viruses. J. Gen. Virol. 67:229-234[Abstract/Free Full Text].

3. Conley, A. J., J. A. Kessler, L. J. Boots, P. M. Mckenna, W. A. Schleif, E. A. Emini, G. E. Mark, H. Katinger, E. K. Cobb, S. M. Lunceford, S. R. Rouse, and K. K. Murthy. 1996. The consequence of passive administration of an anti-human immunodeficiency virus type 1 neutralizing monoclonal antibody before challenge of chimpanzees with a primary virus isolate. J. Virol. 70:6751-6758[Abstract/Free Full Text].

4. Crooks, A. J., J. M. Lee, L. M. Easterbrook, A. V. Timofeev, and J. R. Stephenson. 1994. The NS1 protein of tick-borne encephalitis virus forms multimeric species upon secretion from the host cell. J. Gen. Virol. 75:3453-3460[Abstract/Free Full Text].

5. D'Ambrosio, D., K. L. Hippen, S. A. Minskoff, I. Mellman, G. Pani, K. A. Siminovitch, and J. C. Cambier. 1995. Recruitment and activation of PTP1C in negative regulation of antigen receptor signaling by Fc gamma RIIB1. Science 268:293-297[Abstract/Free Full Text].

6. Dimmock, N. J. 1995. Update on the neutralisation of animal viruses. Rev. Med. Virol. 5:165-179.

7. Drake, M. E., and C. Ming. 1954. Gamma globulin in epidemic hepatitis: comparative value of two dosage levels, apparently near the minimal effective level. JAMA 155:1302.

8. Fan, W. F., and P. W. Mason. 1990. Membrane association and secretion of the Japanese encephalitis virus NS1 protein from cells expressing NS1 cDNA. Virology 177:470-476[Medline].

9. Gibson, C. A., J. J. Schlesinger, and A. D. Barrett. 1988. Prospects for a virus non-structural protein as a subunit vaccine. Vaccine 6:7-9[Medline].

10. Green, M. S., D. Cohen, Y. Lerman, M. Sjogren, L. N. Binn, S. Zur, R. Slepon, G. Robin, C. Hoke, W. Bancroft, et al. 1993. Depression of the immune response to an inactivated hepatitis A vaccine administered concomitantly with immune globulin. J. Infect. Dis. 168:740-743[Medline].

11. Heath, S. L., J. G. Tew, A. K. Szakal, and G. F. Burton. 1995. Follicular dendritic cells and human immunodeficiency virus infectivity. Nature 377:740-744[Medline]. (Comments.)

12. Heinz, F. X. 1986. Epitope mapping of flavivirus glycoproteins. Adv. Virus Res. 31:103-168[Medline].

13. Heinz, F. X., R. Berger, W. Tuma, and C. Kunz. 1983. A topological and functional model of epitopes on the structural glycoprotein of tick-borne encephalitis virus defined by monoclonal antibodies. Virology 126:525-537[Medline].

14. Heinz, F. X., W. Tuma, and C. Kunz. 1981. Antigenic and immunogenic properties of defined physical forms of tick-borne encephalitis virus structural proteins. Infect. Immun. 33:250-257[Abstract/Free Full Text].

15. Hemming, V. G., G. A. Prince, J. R. Groothuis, and G. R. Siber. 1995. Hyperimmune globulins in prevention and treatment of respiratory syncytial virus infections. Clin. Microbiol. Rev. 8:22-33[Abstract/Free Full Text].

16. Hofmann, H., W. Frisch-Niggemeyer, and C. Kunz. 1978. Protection of mice against tick-borne encephalitis by different classes of immunoglobulins. Infection 6:154-157[Medline].

17. Jacobs, S. C., J. R. Stephenson, and G. W. Wilkinson. 1992. High-level expression of the tick-borne encephalitis virus NS1 protein by using an adenovirus-based vector: protection elicited in a murine model. J. Virol. 66:2086-2095[Abstract/Free Full Text].

18. Julius, M. H., E. Simpson, and L. A. Herzenberg. 1973. A rapid method for the isolation of functional thymus-derived murine lymphocytes. Eur. J. Immunol. 3:645-649[Medline].

19. Kreil, T. R., I. Burger, E. Attakpah, K. Olas, and M. M. Eibl. Passive protection reduces immunity resulting from simultaneous immunization against tick-borne encephalitis virus. Vaccine, in press.

20. Kreil, T. R., and M. M. Eibl. 1995. Viral infection of macrophages profoundly alters requirements for induction of nitric oxide synthesis. Virology 212:174-178[Medline].

21. Kreil, T. R., and M. M. Eibl. 1997. Pre- and postexposure protection by passive immunoglobulin but no enhancement of infection with a flavivirus in a mouse model. J. Virol. 71:2921-2927[Abstract/Free Full Text].

22. Kreil, T. R., K. Zimmermann, I. Burger, E. Attakpah, J. W. Mannhalter, and M. M. Eibl. 1997. Detection of tick-borne encephalitis virus by sample transfer, plaque assay and strand-specific reverse transcriptase polymerase chain reaction: what do we detect? J. Virol. Methods 68:1-8[Medline].

23. Mathews, J. H., and J. T. Roehrig. 1984. Elucidation of the topography and determination of the protective epitopes on the E glycoprotein of Saint Louis encephalitis virus by passive transfer with monoclonal antibodies. J. Immunol. 132:1533-1537[Abstract].

24. Murphy, B. R., G. A. Prince, P. L. Collins, S. W. Hildreth, and P. R. Paradiso. 1991. Effect of passive antibody on the immune response of cotton rats to purified F and G glycoproteins of respiratory syncytial virus (RSV). Vaccine 9:185-189[Medline].

25. Niedrig, M., U. Klockmann, W. Lang, J. Roeder, S. Burk, S. Modrow, and G. Pauli. 1994. Monoclonal antibodies directed against tick-borne encephalitis virus with neutralizing activity in vivo. Acta Virol. 38:141-149[Medline].

26. Phillpotts, R. J., J. R. Stephenson, and J. S. Porterfield. 1987. Passive immunization of mice with monoclonal antibodies raised against tick-borne encephalitis virus. Brief report. Arch. Virol. 93:295-301[Medline].

26a. Plaimauer, B. Unpublished data.

27. Pryor, M. J., and P. J. Wright. 1993. The effects of site-directed mutagenesis on the dimerization and secretion of the NS1 protein specified by dengue virus. Virology 194:769-780[Medline].

28. Ravetch, J. V., and J. P. Kinet. 1991. Fc receptors. Annu. Rev. Immunol. 9:457-492[Medline].

29. Robbins, J. B., R. Schneerson, and S. C. Szu. 1995. Perspective: hypothesis: serum IgG antibody is sufficient to confer protection against infectious diseases by inactivating the inoculum. J. Infect. Dis. 171:1387-1398[Medline].

30. Roehrig, J. T. 1986. The use of monoclonal antibodies in studies of the structural proteins of togaviruses and flaviviruses, p. 251-278. In S. Schlesinger, and M. J. Schlesinger (ed.), The Togaviridae and Flaviviridae. Plenum Press, New York, N.Y.

31. Rothman, A. L., I. Kurane, C. J. Lai, M. Bray, B. Falgout, R. Men, and F. A. Ennis. 1993. Dengue virus protein recognition by virus-specific murine CD8⁺ cytotoxic T lymphocytes. J. Virol. 67:801-806[Abstract/Free Full Text].

32. Rowley, D. A., F. W. Fitch, F. P. Stuart, H. Kohler, and H. Cosenza. 1973. Specific suppression of immune responses. Science 181:1133-1141[Abstract/Free Full Text].

33. Schlesinger, J. J., M. W. Brandriss, J. R. Putnak, and E. E. Walsh. 1990. Cell surface expression of yellow fever virus non-structural glycoprotein NS1: consequences of interaction with antibody. J. Gen. Virol. 71:593-599[Abstract/Free Full Text].

34. Schlesinger, J. J., M. Foltzer, and S. Chapman. 1993. The Fc portion of antibody to yellow fever virus NS1 is a determinant of protection against YF encephalitis in mice. Virology 192:132-141[Medline].

35. Schneider, A. J., and J. W. Mosley. 1959. Studies of variations of glutamic-oxaloacetic transaminase in the serum in infectious hepatitis. Pediatrics 24:367-377[Abstract/Free Full Text].

36. Schumacher, C. L., H. C. Ertl, H. Koprowski, and B. Dietzschold. 1992. Inhibition of immune responses against rabies virus by monoclonal antibodies directed against rabies virus antigens. Vaccine 10:754-760[Medline].

37. Wengler, G., D. W. Bradley, M. S. Collett, F. X. Heinz, R. W. Schlesinger, and J. H. Strauss. 1995. Flaviviridae, p. 415-427. In F. A. Murphy, C. M. Fauquet, D. H. L. Bishop, S. A. Ghabrial, A. W. Jarvis, G. P. Martelli, M. A. Mayo, and M. D. Summers (ed.), Virus taxonomy. Classification and nomenclature of viruses. Sixth report of the International Committee on Taxonomy of Viruses. Springer-Verlag, New York, N.Y.

38. Winkler, G., S. E. Maxwell, C. Ruemmler, and V. Stollar. 1989. Newly synthesized dengue-2 virus nonstructural protein NS1 is a soluble protein but becomes partially hydrophobic and membrane-associated after dimerization. Virology 171:302-305[Medline].

39. Winkler, G., V. B. Randolph, G. R. Cleaves, T. E. Ryan, and V. Stollar. 1988. Evidence that the mature form of the flavivirus nonstructural protein NS1 is a dimer. Virology 162:187-196[Medline].

40. Winokur, P. L., and J. T. Stapleton. 1992. Immunoglobulin prophylaxis for hepatitis A. Clin. Infect. Dis. 14:580-586[Medline].

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1.	Bachmann, M. F., U. Kalinke, A. Althage, G. Freer, C. Burkhart, H. Roost, M. Aguet, H. Hengartner, and R. M. Zinkernagel. 1997. The role of antibody concentration and avidity in antiviral protection. Science 276:2024-2027[Abstract/Free Full Text].
2.	Brandriss, M. W., J. J. Schlesinger, E. E. Walsh, and M. Briselli. 1986. Lethal 17D yellow fever encephalitis in mice. I. Passive protection by monoclonal antibodies to the envelope proteins of 17D yellow fever and dengue 2 viruses. J. Gen. Virol. 67:229-234[Abstract/Free Full Text].
3.	Conley, A. J., J. A. Kessler, L. J. Boots, P. M. Mckenna, W. A. Schleif, E. A. Emini, G. E. Mark, H. Katinger, E. K. Cobb, S. M. Lunceford, S. R. Rouse, and K. K. Murthy. 1996. The consequence of passive administration of an anti-human immunodeficiency virus type 1 neutralizing monoclonal antibody before challenge of chimpanzees with a primary virus isolate. J. Virol. 70:6751-6758[Abstract/Free Full Text].
4.	Crooks, A. J., J. M. Lee, L. M. Easterbrook, A. V. Timofeev, and J. R. Stephenson. 1994. The NS1 protein of tick-borne encephalitis virus forms multimeric species upon secretion from the host cell. J. Gen. Virol. 75:3453-3460[Abstract/Free Full Text].
5.	D'Ambrosio, D., K. L. Hippen, S. A. Minskoff, I. Mellman, G. Pani, K. A. Siminovitch, and J. C. Cambier. 1995. Recruitment and activation of PTP1C in negative regulation of antigen receptor signaling by Fc gamma RIIB1. Science 268:293-297[Abstract/Free Full Text].
6.	Dimmock, N. J. 1995. Update on the neutralisation of animal viruses. Rev. Med. Virol. 5:165-179.
7.	Drake, M. E., and C. Ming. 1954. Gamma globulin in epidemic hepatitis: comparative value of two dosage levels, apparently near the minimal effective level. JAMA 155:1302.
8.	Fan, W. F., and P. W. Mason. 1990. Membrane association and secretion of the Japanese encephalitis virus NS1 protein from cells expressing NS1 cDNA. Virology 177:470-476[Medline].
9.	Gibson, C. A., J. J. Schlesinger, and A. D. Barrett. 1988. Prospects for a virus non-structural protein as a subunit vaccine. Vaccine 6:7-9[Medline].
10.	Green, M. S., D. Cohen, Y. Lerman, M. Sjogren, L. N. Binn, S. Zur, R. Slepon, G. Robin, C. Hoke, W. Bancroft, et al. 1993. Depression of the immune response to an inactivated hepatitis A vaccine administered concomitantly with immune globulin. J. Infect. Dis. 168:740-743[Medline].
11.	Heath, S. L., J. G. Tew, A. K. Szakal, and G. F. Burton. 1995. Follicular dendritic cells and human immunodeficiency virus infectivity. Nature 377:740-744[Medline]. (Comments.)
12.	Heinz, F. X. 1986. Epitope mapping of flavivirus glycoproteins. Adv. Virus Res. 31:103-168[Medline].
13.	Heinz, F. X., R. Berger, W. Tuma, and C. Kunz. 1983. A topological and functional model of epitopes on the structural glycoprotein of tick-borne encephalitis virus defined by monoclonal antibodies. Virology 126:525-537[Medline].
14.	Heinz, F. X., W. Tuma, and C. Kunz. 1981. Antigenic and immunogenic properties of defined physical forms of tick-borne encephalitis virus structural proteins. Infect. Immun. 33:250-257[Abstract/Free Full Text].
15.	Hemming, V. G., G. A. Prince, J. R. Groothuis, and G. R. Siber. 1995. Hyperimmune globulins in prevention and treatment of respiratory syncytial virus infections. Clin. Microbiol. Rev. 8:22-33[Abstract/Free Full Text].
16.	Hofmann, H., W. Frisch-Niggemeyer, and C. Kunz. 1978. Protection of mice against tick-borne encephalitis by different classes of immunoglobulins. Infection 6:154-157[Medline].
17.	Jacobs, S. C., J. R. Stephenson, and G. W. Wilkinson. 1992. High-level expression of the tick-borne encephalitis virus NS1 protein by using an adenovirus-based vector: protection elicited in a murine model. J. Virol. 66:2086-2095[Abstract/Free Full Text].
18.	Julius, M. H., E. Simpson, and L. A. Herzenberg. 1973. A rapid method for the isolation of functional thymus-derived murine lymphocytes. Eur. J. Immunol. 3:645-649[Medline].
19.	Kreil, T. R., I. Burger, E. Attakpah, K. Olas, and M. M. Eibl. Passive protection reduces immunity resulting from simultaneous immunization against tick-borne encephalitis virus. Vaccine, in press.
20.	Kreil, T. R., and M. M. Eibl. 1995. Viral infection of macrophages profoundly alters requirements for induction of nitric oxide synthesis. Virology 212:174-178[Medline].
21.	Kreil, T. R., and M. M. Eibl. 1997. Pre- and postexposure protection by passive immunoglobulin but no enhancement of infection with a flavivirus in a mouse model. J. Virol. 71:2921-2927[Abstract/Free Full Text].
22.	Kreil, T. R., K. Zimmermann, I. Burger, E. Attakpah, J. W. Mannhalter, and M. M. Eibl. 1997. Detection of tick-borne encephalitis virus by sample transfer, plaque assay and strand-specific reverse transcriptase polymerase chain reaction: what do we detect? J. Virol. Methods 68:1-8[Medline].
23.	Mathews, J. H., and J. T. Roehrig. 1984. Elucidation of the topography and determination of the protective epitopes on the E glycoprotein of Saint Louis encephalitis virus by passive transfer with monoclonal antibodies. J. Immunol. 132:1533-1537[Abstract].
24.	Murphy, B. R., G. A. Prince, P. L. Collins, S. W. Hildreth, and P. R. Paradiso. 1991. Effect of passive antibody on the immune response of cotton rats to purified F and G glycoproteins of respiratory syncytial virus (RSV). Vaccine 9:185-189[Medline].
25.	Niedrig, M., U. Klockmann, W. Lang, J. Roeder, S. Burk, S. Modrow, and G. Pauli. 1994. Monoclonal antibodies directed against tick-borne encephalitis virus with neutralizing activity in vivo. Acta Virol. 38:141-149[Medline].
26.	Phillpotts, R. J., J. R. Stephenson, and J. S. Porterfield. 1987. Passive immunization of mice with monoclonal antibodies raised against tick-borne encephalitis virus. Brief report. Arch. Virol. 93:295-301[Medline].
26a.	Plaimauer, B. Unpublished data.
27.	Pryor, M. J., and P. J. Wright. 1993. The effects of site-directed mutagenesis on the dimerization and secretion of the NS1 protein specified by dengue virus. Virology 194:769-780[Medline].
28.	Ravetch, J. V., and J. P. Kinet. 1991. Fc receptors. Annu. Rev. Immunol. 9:457-492[Medline].
29.	Robbins, J. B., R. Schneerson, and S. C. Szu. 1995. Perspective: hypothesis: serum IgG antibody is sufficient to confer protection against infectious diseases by inactivating the inoculum. J. Infect. Dis. 171:1387-1398[Medline].
30.	Roehrig, J. T. 1986. The use of monoclonal antibodies in studies of the structural proteins of togaviruses and flaviviruses, p. 251-278. In S. Schlesinger, and M. J. Schlesinger (ed.), The Togaviridae and Flaviviridae. Plenum Press, New York, N.Y.
31.	Rothman, A. L., I. Kurane, C. J. Lai, M. Bray, B. Falgout, R. Men, and F. A. Ennis. 1993. Dengue virus protein recognition by virus-specific murine CD8⁺ cytotoxic T lymphocytes. J. Virol. 67:801-806[Abstract/Free Full Text].
32.	Rowley, D. A., F. W. Fitch, F. P. Stuart, H. Kohler, and H. Cosenza. 1973. Specific suppression of immune responses. Science 181:1133-1141[Abstract/Free Full Text].
33.	Schlesinger, J. J., M. W. Brandriss, J. R. Putnak, and E. E. Walsh. 1990. Cell surface expression of yellow fever virus non-structural glycoprotein NS1: consequences of interaction with antibody. J. Gen. Virol. 71:593-599[Abstract/Free Full Text].
34.	Schlesinger, J. J., M. Foltzer, and S. Chapman. 1993. The Fc portion of antibody to yellow fever virus NS1 is a determinant of protection against YF encephalitis in mice. Virology 192:132-141[Medline].
35.	Schneider, A. J., and J. W. Mosley. 1959. Studies of variations of glutamic-oxaloacetic transaminase in the serum in infectious hepatitis. Pediatrics 24:367-377[Abstract/Free Full Text].
36.	Schumacher, C. L., H. C. Ertl, H. Koprowski, and B. Dietzschold. 1992. Inhibition of immune responses against rabies virus by monoclonal antibodies directed against rabies virus antigens. Vaccine 10:754-760[Medline].
37.	Wengler, G., D. W. Bradley, M. S. Collett, F. X. Heinz, R. W. Schlesinger, and J. H. Strauss. 1995. Flaviviridae, p. 415-427. In F. A. Murphy, C. M. Fauquet, D. H. L. Bishop, S. A. Ghabrial, A. W. Jarvis, G. P. Martelli, M. A. Mayo, and M. D. Summers (ed.), Virus taxonomy. Classification and nomenclature of viruses. Sixth report of the International Committee on Taxonomy of Viruses. Springer-Verlag, New York, N.Y.
38.	Winkler, G., S. E. Maxwell, C. Ruemmler, and V. Stollar. 1989. Newly synthesized dengue-2 virus nonstructural protein NS1 is a soluble protein but becomes partially hydrophobic and membrane-associated after dimerization. Virology 171:302-305[Medline].
39.	Winkler, G., V. B. Randolph, G. R. Cleaves, T. E. Ryan, and V. Stollar. 1988. Evidence that the mature form of the flavivirus nonstructural protein NS1 is a dimer. Virology 162:187-196[Medline].
40.	Winokur, P. L., and J. T. Stapleton. 1992. Immunoglobulin prophylaxis for hepatitis A. Clin. Infect. Dis. 14:580-586[Medline].