DNA from Mycobacterium bovis Bacillus Calmette-Guerin (MY-1) Inhibits Immunoglobulin E Production by Human Lymphocytes

DNA from Mycobacterium bovis Bacillus Calmette-Guérin (MY-1) Inhibits Immunoglobulin E Production by Human Lymphocytes

SHIGEHARU FUJIEDA, SUMIKO IHO, YUICHI KIMURA, HIROSHI SUNAGA, HIDEKI IGAWA, CHIZURU SUGIMOTO, SABURO YAMAMOTO, and HITOSHI SAITO

Departments of Otorhinolaryngology and Immunology, Fukui Medical University, Fukui; and Department of Bacterial and Blood Products, National Institute of Infectious Diseases, Tokyo, Japan

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

A DNA fraction purified from Mycobacterium bovis bacillus Calmette-Guérin (BCG) and designated MY-1 induced interferon (IFN)- $gamma$ production by human peripheral blood mononuclear cells (PBMC).IFN- $gamma$ is well known as a downregulator of IgE production. In thisstudy we investigated whether MY-1 regulates IgE production byhuman PBMC in vitro. MY-1 inhibited IgE production in PBMC takenfrom normal donors and stimulated with interleukin (IL)-4 plusmonoclonal anti-CD40 antibody, without affecting production ofIgA. MY-1 enhanced production of IFN- $gamma$ and IL-12 by PBMC. Inhibitionby MY-1 of IgE production was mediated by both IFN- $gamma$ and IL-12,since the MY-1-induced suppression was blocked by the additionof monoclonal anti-IFN- $gamma$ antibody, monoclonal anti-IL-12 antibodyor a monoclonal antibody (mAb) directed at the IL-12 receptor.MY-1 inhibited the induction of $varepsilon$ germ-line transcript by IL-4.Additionally, MY-1 inhibited spontaneous in vitro production ofIgE by PBMC from atopic donors in the absence of IL-4 plus anti-CD40mAb. These results suggest that exposure to MY-1 may be a novelstrategy for the treatment of IgE-related allergic disease. FujiedaS, Iho S, Kimura Y, Sunaga H, Igawa H, Sugimoto C, Yamamoto S,Saito H. DNA from Mycobacterium bovis bacillus Calmette-Guérin(MY-1) inhibits immunoglobulin E production by humanlymphocytes.

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

MY-1, a DNA-rich fraction extracted and purified from Mycobacterium bovis bacillus Calmette-Guérin (BCG), showed antitumoractivity against various kinds of syngeneic tumors in mice (1).The antitumor mechanism of MY-1 is due to augmentation of naturalkiller (NK) cell activity and production of interferon (IFN)- $alpha$ / $beta$ and - $gamma$ in vivo (2). Also, MY-1 enhanced the NK activity ofhuman peripheral blood mononuclear cells (PBMC) and induced productionof IFN- $gamma$ in vitro (3). MY-1 contains 98% nucleic acid (70.0%DNA and 28.0% RNA), 0.15% protein, 0.27% sugar, and 0.1% lipid(1). Because MY-1 was not toxic in humans, an immunotherapeutictrial was conducted of MY-1 against human malignant tumors (4).

Human B cells have been shown to produce immunoglobulin (Ig)E following stimulation with interleukin (IL)-4 plus ligationof CD40 (5). Downregulation of IgE production was caused byIFN- $gamma$ secretion, mainly from T and NK cells. IFN- $gamma$ and IL-4 haveantagonistic effects on Ig class switching, with IFN- $gamma$ inhibitingboth IL-4 and T-cell-mediated human IgE production (6). Indoing this, IFN- $gamma$ appears to act early to prevent switching, sinceit fails to suppress IgE secretion stimulated by CD40 ligationand IL-4 (7, 8).

These results prompted us to investigate whether MY-1 might be useful for treating allergic disease, as a downregulator ofIgE in vivo. In this study, we examined whether MY-1 inhibitsIgE production by human PBMC stimulated with IL-4 and monoclonalanti-CD40 antibody in vitro.

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Reagents

Human IL-4 was the gift of Ono Pharmaceutical Co. Ltd (Osaka, Japan) and monoclonal anti-CD40 antibody G28-5 was a gift fromDr. E. A. Clark of the University of Washington (Seattle, WA).Mouse monoclonal antihuman IgE antibodies (CIA-E-7.12 and CIA-E-4.15)were a gift from Dr. A. Saxon of the University of California,Los Angeles (Los Angeles, CA). Monoclonal antibody (mAb) directedagainst the IL-12 receptor (12R $beta$ .44) was a gift from Dr. J. Gollobof the Dana-Farber Cancer Institute (Boston, MA) (9). MY-1was extracted from Mycobacterium bovis BCG and was purified accordingto the method previously described (1). The following reagentswere obtained commercially: alkaline phosphatase-labeled goatantihuman IgE (Kirkegaard and Perry Laboratories, Inc., Gaithersburg,MD), mouse monoclonal antihuman IFN- $gamma$ antibody (Biosource International,Camarillo, CA), mouse monoclonal antihuman IL-12 antibody (Genzyme,Cambridge, MA), an enzyme-linked immunosorbent assay (ELISA) kitfor human IFN- $gamma$ (Biosource), an ELISA kit for human IL-12 (Biosource)and deoxyribonuclease (DNase) (Sigma Chemical Co., St. Louis,MO).

Cells and Cell Cultures

PBMC were isolated from healthy volunteers by centrifugation on Ficoll-Hypaque. PBMC (1 × 10⁶ cells/ml) were cultured for 14 d in complete medium preparedfrom RPMI-1640 medium supplemented with 2 mM glutamine, 100 U/mlpenicillin, and 100 µg/ml streptomycin in the presence of IL-4(100 U/ml) and monoclonal anti-CD40 antibody (0.1 µg/ml), whichconstitute optimal conditions for IgE production (10, 11).

Ig Measurements

Total IgE levels in the supernatants of stimulated cells were measured with an ELISA as previously described (10, 11).Briefly, microtiter plates were coated overnight at 4° C withtwo types of monoclonal antihuman IgE antibody (CIA-E-7.12 andCIA-E-4.15). After the wells were blocked with 0.1% gelatin forat least 1 h, 100 µl of culture supernatants was plated in duplicatewells and the plates were incubated for 2 h at room temperature.After washing, alkaline phosphatase- labeled IgE was added fordetection. Absorbance was read at 405 nm with an ELISA reader(Bio-Tek Instruments, Burlingame, CA). The sensitivity of theassay for IgE subclasses was 0.1 ng/ml.

RNA Extraction and Reverse Transcription-Polymerase Chain Reaction

Total messenger RNA (mRNA) was obtained from stimulated and nonstimulated human PBMC through the use of Trizol reagent (GIBCOBRL, Gaithersburg, MD), a monophasic solution of phenol and guanidineisothiocyanate, which is an improvement over the single-step RNAisolation method (12, 13). RNA suspended in 0.1% diethylpyrocarbonate-treatedwater was digested with DNase I (Sigma) to remove contaminatingDNA, and the digest was then extracted with phenol/chloroform,followed by precipitation of the RNA in ethanol. Total RNA (0.5µg) was reverse-transcribed to complementary DNA (cDNA), usingoligodeoxythymidine₁₅ (Boehringer-Mannheim, Indianapolis, IN)as primer and mouse Moloney leukemia virus reverse transcriptase(GIBCO BRL), under conditions recommended by themanufacturer.

All polymerase chain reaction (PCR) assays were done in 50-µl reaction volumes containing 50 mM KCl, 20 mM Tris-HCl (pH 8.4),2.5 mM MgCl₂, 5% dimethylsulfoxide, 50 pM primer per reaction,and 2.5 U of Taq polymerase. For detection of $varepsilon$ germline transcriptsand $beta$ actin, PCR was conducted with 40 cycles of 94° C for 1 min,65° C for 1 min, and 72° C for 1 min. The primer sequences were,for $varepsilon$ germline transcripts I $varepsilon$ and C $varepsilon$ , respectively: AGGCTCCACTGCCCGGCACAGAAATAand GGACAAGTCCACGTCCATGA; and for $beta$ actin: TCACCAACTGGGACGACATGGAGand CTCCTTAATGTCACGCACGATTTC (12).

Detection of IFN- $gamma$ and IL-12

The concentrations of IFN- $gamma$ and IL-12 in the supernatants of PBMC stimulated with IL-4 and anti-CD40 mAb in the absence orpresence of MY-1 were measured with ELISA kits, as previouslydescribed. Using protocols provided with the kits, IFN- $gamma$ and IL-12can be measured in the range of 4 to 1,000 pg/ml and 7.8 to 500pg/ml,respectively.

Statistics

Data are expressed as mean ± SEM. Statistical significance of effects on Ig production was determined with Wilcoxon's signedrankstest.

	RESULTS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

MY-1 Inhibited IgE Production by PBMC

PBMC were cultured for 14 d with IL-4 plus anti-CD40 mAb and various concentrations of MY-1, and the production of IgE wasmeasured through ELISA. As shown in Figure 1, MY-1 inhibited theproduction of IgE induced by IL-4 plus anti-CD40 mAb in a dose-dependentmanner. The maximum effect of MY-1 on suppression of IgE productionwas obtained at concentrations above 10 µg/ml (p < 0.01) in fiveindependent preparations of PBMC. On the basis of these results,all subsequent experiments were done at an MY-1 concentrationof 50 µg/ml. In 12 experiments, MY-1 (50 µg/ml) inhibited theproduction of IgE (72 ± 6% inhibition) induced by IL-4 plus anti-CD40mAb without affecting production of IgA (9 ± 17% inhibition) (Table1). MY-1 had no effect on the viability or cell number of PBMC,as shown by trypan blue dye exclusion (data not shown). To confirmthat the DNA in MY-1 is crucial for the suppression of IgE production,MY-1 was treated with DNase for 5 h (1). The DNase digestsof MY-1 lost the ability to inhibit IgE synthesis (data not shown).

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Figure 1. Effect of MY-1 on IgE production. Human PBMC from nonatopic healthy donors (n = 5) were cultured with IL-4 (100 U/ ml) and anti-CD40 mAb (0.1 µg/ml) for 14 d in the presence of various concentrations of MY-1. MY-1 inhibited IgE production in a dose-dependent manner. Data are expressed as mean ± SEM (*p < 0.05, p < 0.01, compared with IgE values for stimulation with IL-4 plus anti-CD40 mAb in the absence of MY-1).

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TABLE 1

MY-1 INHIBITS IMMUNOGLOBULIN E BUT NOT IMMUNOGLOBULIN A PRODUCTION BY PERIPHERAL BLOOD MONONUCLEAR CELLS

MY-1 Enhanced Production of IFN- $gamma$ and IL-12 by PBMC

MY-1 has been shown to induce production of large amounts of IFN- $gamma$ by mouse spleen cells (2). This suggested the possibilitythat MY-1-induced IFN- $gamma$ blocked the production of IgE by humanPBMC. We therefore measured the concentration of IFN- $gamma$ in theculture supernatants on Day 7 through ELISA. The level of IFN- $gamma$ in supernatants from PBMC stimulated with IL-4 plus anti-CD40mAb in the presence of MY-1 (50 µg/ml) was higher than that insupernatants from PBMC stimulated in the absence of MY-1 (p <0.01, Table 2).

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TABLE 2

INDUCTION OF INTERFERON- $gamma$ AND INTERLEUKIN-12 BY PERIPHERAL BLOOD MONONUCLEAR CELLS

IL-12 affects the induction of IFN- $gamma$ secretion by NK cells and T cells (14). The enhancement of IFN- $gamma$ production by MY-1led us to speculate that MY-1 also enhances IL-12 production byPBMC. There was no significant difference in the IL-12 concentrationin 36-h or 3-d culture supernatants from PBMC stimulated withIL-4 plus anti-CD40 mAb in the presence of MY-1 and that in thecorresponding supernatants from PBMC stimulated in the absenceof MY-1 (data not shown). The induction of IL-12 in PBMC stimulatedwith IL-4 plus anti-CD40 mAb in the presence of MY-1 for 7 d wasgreater than that in PBMC stimulated in the absence of MY-1 (p< 0.05, Table 2).

Inhibition of IgE Production by MY-1 Is Mediated by IFN- $gamma$ and IL-12

To confirm the involvement of IFN- $gamma$ in the decrease in IgE production caused by MY-1, we added anti-IFN- $gamma$ mAb (1 µg/ ml) tothe culture system. As shown in Figure 2A, the addition of anti-IFN- $gamma$ mAb did not completely block the inhibition of IgE productionby MY-1 in the presence of IL-4 plus anti-CD40 mAb (228 ± 118ng/ml versus 431 ± 133 ng/ml, p < 0.05). Control mouse IgG hadno effect on IgE production (data not shown).

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Figure 2. The addition of antibodies blocked the inhibition by MY-1 of IgE production stimulated with IL-4 plus anti-CD mAb. PBMC from nonatopic healthy donors (n = 5) were cultured with IL-4 (100 U/ml) and anti-CD40 mAb (0.1 µg/ml) for 14 d in the presence or absence of MY-1 and/or (A) anti-IFN- $gamma$ mAb (1 µg/ml), (B) anti-IL-12 mAb (10 µg/ml), (C ) anti-IL-12R mAb (10 µg/ml). (D) Both anti-IFN- $gamma$ mAb (1 µg/ml) and anti-IL-12 mAb (10 µg/ml) were added to the culture system for 14 d. Addition of the two antibodies partly blocked the inhibition of IgE production by MY-1. Representative data from three experiments are expressed (*p < 0.05).

To test whether IL-12 is involved in the mechanism of suppression of IgE production by MY-1, we added 10 µg/ml of anti-IL-12mAb, a concentration that neutralizes the activity of approximately5 ng of recombinant IL-12 to the culture system. The additionof anti-IL-12 mAb also partly blocked the inhibition of IgE productionby MY-1, as did anti-IFN- $gamma$ mAb (144 ± 47 ng/ml versus 446 ± 111ng/ml, p < 0.05) (Figure 2B). In five experiments, IgE productionin the presence of anti- IL-12, MY-1, IL-4, and anti-CD40 mAbranged from 58% to 75% of the IgE production induced by IL-4 plusanti-CD40 mAb. These results suggested that IL-12 participatesin the MY-1-induced inhibition of IgE production byPBMC.

It is known that IL-12 exerts a pleiotropic effect via binding to the IL-12 receptor (9). Therefore, as an additional test,we added anti-IL-12R $beta$ mAb to the culture system. As shown in Figure2C, the addition of anti-IL-12R $beta$ mAb (10 µg/ml) partly blockedthe MY-1-mediated inhibition of IgE production by PBMC, as didanti-IL-12 mAb (260 ± 89 ng/ml versus 423 ± 119 ng/ml, p < 0.05).Thus, both IL-12 and IL-12R are involved in the MY-1-mediatedsuppression of IgE production. Although we analyzed the expressionof a single low-affinity IL-12R subunit (IL-12R $beta$ ) with Westernblotting and flow cytometry, using anti-IL-12R $beta$ , mAb, we foundno marked difference in IL-12R $beta$ expression on PBMC stimulatedwith IL-4 plus anti-CD40 mAb in the presence and in the absenceof MY-1 with either approach (data notshown).

We also evaluated the effect of adding anti-IFN- $gamma$ and anti-IL-12 mAbs to the culture system (Figure 2D). The combined additionof the anti-IFN- $gamma$ and anti-IL-12 antibodies blocked the MY-1-mediatedinhibition of IgE production by PBMC, but not completely. Theseresults suggested that IFN- $gamma$ and IL-12 were involved in the mechanismof suppression of MY-1-mediated inhibition of IgE production byhuman PBMC, but that other factors than IFN- $gamma$ and IL-12 may beinvolved in the inhibition by MY-1 of IgEproduction.

MY-1 Inhibited the Induction of $varepsilon$ Germline Transcripts

Expression of germline transcripts from Ig heavy-chain loci precedes the occurrence of isotype switching, and is thought toplay an important role in Ig class switching (15). We assessedthe presence of $varepsilon$ germline transcripts by using an RT-PCR-basedstrategy. As previously reported, stimulation with IL-4 reproduciblyinduced $varepsilon$ germline transcripts from PBMC (7, 12) (Figure3A). The amplified fragments of these $varepsilon$ germline transcripts werecloned and identified as representing $varepsilon$ germline transcripts byDNA sequence analysis (12). Stimulation with MY-1 suppressedthe expression of $varepsilon$ germline transcripts induced by IL-4 in allfour experiments with independent PBMC preparations. UnstimulatedPBMC showed no expression of $varepsilon$ germline transcripts, as expected.Also, no $varepsilon$ germline transcripts were found in PBMC stimulatedwith MY-1 alone (data not shown). To estimate the sensitivityof our PCR assay for $varepsilon$ germline transcripts, we serially dilutedtotal cellular RNA containing $varepsilon$ germline transcripts as templates,and subjected the products to amplification via RT-PCR (12)(Figure 3B). The sensitivity of the technique was determined tobe 10 pg of total cellular RNA. Semiquantitative analysis by comparisonwith the data shown in Figure 3B demonstrated that the combinationof MY-1 and IL-4 reduced the production of $varepsilon$ germline transcriptsto almost one-tenth of that induced by IL-4 alone. There was nodifference in the brightness of the amplified bands of $beta$ -actinamong the three RT-PCR product groups, as shown in Figure 3A (datanot shown).

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Figure 3. MY-1 inhibited induction of $varepsilon$ germline transcripts by IL-4. (A) Induction of $varepsilon$ germline transcripts from PBMC was assessed by RT-PCR. PBMC were cultured for 7 d with medium, IL-4 (100 U/ ml) alone, or IL-4 (100 U/ml) plus MY-1 (50 µg/ml). Cells stimulated with IL-4 expressed the predicted 615-bp band for $varepsilon$ germline transcripts. (B) Sensitivity of the RT-PCR assay for $varepsilon$ germline transcripts. Total cellular RNA containing $varepsilon$ germline transcripts was diluted and amplified as a template. The volumes of total RNA were 1 pg (lane 1), 10 pg (lane 2), 20 pg (lane 3), 100 pg (lane 4), 200 pg (lane 5), 1 ng (lane 6 ), and 2 ng (lane 7).

MY-1 Inhibited Spontaneous IgE Production by PBMC from Atopic Patients

We studied the effect of MY-1 on spontaneous IgE production by PBMC obtained from atopic patients. Serum IgE levels in atopicpatients were over 1,000 U/ml. Spontaneous IgE production by PBMCfrom five atopic patients was 341 ± 123 ng/ml, whereas that byPBMC from nonatopic volunteers was less than 50 ng/ml. MY-1 inhibitedspontaneous IgE production by PBMC from all atopic patients (p< 0.05 compared with IgE production in the absence of MY-1) (Table3). MY-1 inhibited the spontaneous production of IgE by 53.9± 9.1%. In contrast, no inhibition by MY-1 of spontaneous productionof IgA was found in PBMC from atopic patients (Table 3).

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TABLE 3

SPONTANEOUS IgE AND IgA PRODUCTION BY PERIPHERAL BLOOD MONONUCLEAR CELLS FROM ATOPIC PATIENTS

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

In this study we showed that MY-1 inhibited IgE production in vitro by PBMC stimulated with IL-4 plus anti-CD40 mAb. Also,MY-1 inhibited spontaneous IgE production in vitro by unstimulatedPBMC from atopic patients. Concentrations of both IFN- $gamma$ and IL-12in 7-d-culture supernatants were higher in the presence than inthe absence of MY-1. The addition of anti-IFN- $gamma$ mAb, anti-IL-12mAb, or anti-IL-12R mAb blocked the inhibition by MY-1 of IgEproduction, suggesting that both IFN- $gamma$ and IL-12 play criticalroles in the mechanism of suppression of IgE production by MY-1.

Ig isotype switching is preceded by germline transcription (15). The importance of germline transcription was confirmedby gene-targeting experiments (16). In our study, MY-1 inhibitedthe induction of $varepsilon$ germline transcripts in PBMC stimulated withIL-4. This result is in agreement with the evidence that IFN- $gamma$ suppressed the induction of $varepsilon$ germline transcripts by IL-4 (8).

IL-12 can have multiple effects on the immune response, but its major role is to augment IFN- $gamma$ production (14, 17). IFN- $gamma$ itself has an important role in IL-12 production (18). IL-12may suppress IgE synthesis by: (1) inducing production of IFN- $gamma$ ,a known inhibitor of IgE synthesis; and (2) a novel mechanismthat is IFN- $gamma$ -independent (19). Our finding that the inhibitionby MY-1 of IgE production was not completely blocked by additionof anti-IFN- $gamma$ mAb and anti-IL-12 mAb suggested that MY-1 may inpart inhibit IgE production through a novel activity that is IFN- $gamma$ -independent.Also, IL-8 was reported to antagonize IL-4-induced IgE productionthrough a specific mechanism that does not involve IFN- $gamma$ , IFN- $alpha$ ,or prostaglandin E₂ (20). In fact, a high level of IL-8 wasin some cases detected in the supernatant of PBMC stimulated withMY-1, although no significant difference was detected in IL-8concentration in the supernatant from PBMC in the presence andabsence of MY-1 (data notshown).

It has long been known that Mycobacterium tuberculosis and its related products (e.g., BCG) inhibit IgE responses (21).Preadministration of dinitrophenol (DNP)-coupled M. tuberculosisinhibited the production of anti-DNP IgE antibody induced by DNP-ovalbuminin mice in vivo and in vitro (22). Delayed hypersensitivitiesto M. tuberculosis are closely associated with the incidence ofasthma, serum IgE levels, and cytokine profiles biased towardthe T-helper 1 (Th1) type (23). Erb and colleagues clearly showedthat intranasal BCG infection of the lung suppressed the developmentof ovalbumin- induced airway eosinophilia (24).

Although the potential utility of recombinant IFN- $gamma$ (rIFN- $gamma$ ) and rIL-12 in allergic disease have been suggested on the basisof a number of human and animal studies, systemic administrationof rIFN- $gamma$ did not alter IgE production in patients with allergicrhinitis (25). Administration of rIL-12 has been associatedwith severe adverse effects (26). Local administration of rIFN- $gamma$ or rIL-12 by ultrasonic nebulization was shown to prevent allergicinflammation and secondarily increased titers of antigen-specificIgE without any adverse effects (27, 28). We showed that repeatedintranasal allergen challenge and exposure to diesel exhaust particlesinduced local in vivo $varepsilon$ isotype switching and IgE production (29).IgE values in nasal lavage fluid were associated with clinicaloutcome in the treatment of nasal allergy (30). These findingssuggested that local administration of MY-1 may be a reasonabletherapeutic approach for respiratory allergicdiseases.

Gene vaccination is a powerful candidate method as an effective strategy for treating allergy in the 21st century. A plasmidbackbone that delivers adjuvant and mitogenic activity via immunostimulatorysequences is a major unit in gene vaccination (2, 31). Yamamotoand colleagues demonstrated for the first time that MY-1 activatedNK cells and enhanced IFN- $gamma$ production in mice (3). Additionally,they determined several sequences of 30-mer oligonucleotides thatmost potently augment the secretion of IFN- $gamma$ and NK activity (31).Most of these oligonucleotides included a CpG motif within a palindromichexamer as an immunologically active sequence (31, 34). TheCpG motif in MY-1 was crucial for the effect of MY-1 in inhibitingIgE production (S. Fujieda, unpublished data). Raz and coworkersshowed that for clinical application, intradermal injection ofplasmid DNA containing short immunostimulatory DNA sequences decreasedantigen-specific IgE antibody production and induced Th1 immuneresponses in mice (32, 33).

MY-1 itself activates cell-mediated immunity and induces production of agents that suppress IgE production. Also, the coadministrationof MY-1 with a conventional vaccine or vaccine-encoding expressionvector has the possibility of augmenting antibody production andregulating allergic reactions in conventional immunotherapy (35).These results suggest that MY-1 may be an effective novel methodof inducing protection against IgE-related allergicdisorders.

	Footnotes

Correspondence and requests for reprints should be addressed to Shigeharu Fujieda, M.D., Department of Otorhinolaryngology, Fukui Medical University, Shimoaizuki, Matsuoka, Yoshida, Fukui, 910-1193, Japan. E-mail: sfujieda{at}fmsrsa.fukui-med.ac.jp

(Received in original form March 1, 1999 and in revised form June 7, 1999).

Acknowledgments: The authors thank Dr. E. A. Clark of the University of Washington for the gift of mAb G28-5 directed against CD40, Dr. A.Saxon of the University of California, Los Angeles, for the giftof anti-IgE mAbs, and Dr. J. Gollob of the Dana-Farber CancerInstitute for the gift of anti-IL-12R mAb. They also thank OnoPharmaceutical Co. Ltd. (Tokyo, Japan) for the gift of IL-4, andMs. I. Funatsu of the Fukui Medical University for her excellenttechnicalassistance.

Supported in part by grant-in-aid for scientific research (C) 11671675 (1999) (S.F.) from the Ministry of Education, Science,Sports and Culture,Japan.

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