Hostname: page-component-7c8c6479df-27gpq Total loading time: 0 Render date: 2024-03-29T07:41:35.992Z Has data issue: false hasContentIssue false

Effects of Enterococcus sp. isolated from deep seawater on inhibition of allergic responses in mice

Published online by Cambridge University Press:  16 December 2008

Masatoshi Kondoh
Affiliation:
Central Research Laboratories, Nichinichi Pharmaceutical Corporation Ltd, 518-1417Mie, Japan
Atsushi Hayashi
Affiliation:
Central Research Laboratories, Nichinichi Pharmaceutical Corporation Ltd, 518-1417Mie, Japan
Mariko Okamori
Affiliation:
Central Research Laboratories, Nichinichi Pharmaceutical Corporation Ltd, 518-1417Mie, Japan
Chie Motonaga
Affiliation:
Central Research Laboratories, Nichinichi Pharmaceutical Corporation Ltd, 518-1417Mie, Japan
Tadao Enomoto
Affiliation:
NPO Japan Health Promotion Supporting Network, 640-8269Wakayama, Japan
Lei Cheng
Affiliation:
International Centre for Allergy Research, Nanjing Medical University, Nanjing, China & Sendai, Japan
Takashi Shimada*
Affiliation:
Central Research Laboratories, Nichinichi Pharmaceutical Corporation Ltd, 518-1417Mie, Japan International Centre for Allergy Research, Nanjing Medical University, Nanjing, China & Sendai, Japan
*
*Corresponding author: Dr Takashi Shimada, fax +81 595 48 0209, email labo@nichinichi-phar.co.jp
Rights & Permissions [Opens in a new window]

Abstract

The objective of the present study was to assess the effects of Enterococcus sp. strain TN-3 isolated from deep seawater on inhibition of eosinophil accumulation, IgE production and active cutaneous anaphylaxis (ACA). We investigated the effects of viable and non-viable TN-3 on allergen-induced peritoneal eosinophil accumulation in mice. Viable (5·4 × 1010 colony-forming units per 60 mg) or non-viable TN-3 (60 mg) was orally administered to BALB/c mice that had been sensitised with the cedar pollen (Cryptomeria japonica) allergen. Oral administration of non-viable TN-3 was effective in suppressing eosinophil accumulation while viable TN-3 was ineffective. We also examined the dose–response relationship for non-viable TN-3 in regard to eosinophil accumulation, IgE production and ACA in allergen-primed mice. Non-viable TN-3 was orally administered at doses of 15 mg (low dose), 30 mg (medium dose) and 60 mg (high dose) to BALB/c mice that had been sensitised with cedar pollen allergen. The anti-allergic effects expressed as inhibition of eosinophil accumulation, IgE production and ACA were found at the low and high doses, but not at the medium dose. These results suggest that non-viable TN-3 exhibited anti-allergic effects at doses of 15 and 60 mg.

Type
Short Communication
Copyright
Copyright © The Authors 2008

Most allergic diseases reflect an imbalance in lymphocyte-governed immunity, with immune responses to allergic molecules becoming overly biased toward T helper type 2 (Th2) cells. Secretion of cytokines such as IL-4, IL-5 and IL-13 by allergen-sensitised Th2 cells recruits granular effector cells such as eosinophils, basophils and mast cells to the site of allergic inflammation(Reference Djukanović, Wilson and Britten1Reference Leung3). These effector cells, alone or in combination with cytophilic/reaginic IgE class antibodies, promote the clinical manifestations of allergy and atopy(Reference Durham4, Reference Wills-Karp5). In addition, IL-4 and IL-13 promote B lymphocyte immunoglobulin isotype switching to IgE(Reference Punnonen, Aversa and Cocks6), and serve to increase circulating levels of total and allergen-specific IgE(Reference Pene, Rousset and Briere7Reference Brown and Hural10). Significantly, it has been well documented that lactic acid bacteria (LAB) have the potential to modulate and regulate the immune response.

Most probiotic micro-organisms are classified as LAB, for example, Lactobacillus sp., Bifidobacterium sp. and Enterococcus sp.(Reference Klein, Pack and Bonaparte11). We have focused on Enterococcus faecalis strain FK-23. Heat-treated FK-23 possessed functionality expressed as anti-tumour and anti-microbial activities(Reference Abe, Ohashi and Uchida12), immunomodulatory effects(Reference Hasegawa, Ogura and Inomata13, Reference Satonaka, Ohashi and Nohmi14) and anti-hypertensive activity(Reference Shimada, Kadowaki and Ohmiya15). In addition, FK-23 processed by bacteriolytic enzyme- and heat-treatment exhibited anti-allergic activities(Reference Shimada, Cheng and Ide16Reference Shimada, Cheng and Enomoto18).

We isolated Enterococcus sp. strain TN-3 from deep seawater in Toyama bay(Reference Hayashi, Shimada and Onaka19). Physiological characterisation of TN-3 showed it to cause liquefaction of gelatin, fermentation-congelation of litmus milk and to possess β-galactosidase activity. TN-3 was identified as E. faecium using the API20strep kit (bioMérieux, Craponne, France), but had high homology to E. durans in respect of 16S rDNA nucleotide sequences. In the present study, we examined the anti-allergic effect of viable and non-viable TN-3 on allergen-induced peritoneal eosinophil accumulation in mice. Moreover, dose–response relationships were evaluated regarding the effect of non-viable TN-3 on eosinophil accumulation, active cutaneous anaphylaxis (ACA) and serum IgE production in allergen-primed mice.

Materials and methods

Preparation of viable and non-viable TN-3

TN-3 was cultured for 18 h at 30°C in a broth medium containing 2·46 % (w/v) glucose, 1·4 % (w/v) yeast extract, 0·77 % (w/v) peptone and 4·39 % (w/v) K2HPO4. After cultivation, the cells were collected by centrifugation, washed with distilled water and then lyophilised (viable TN-3). The number of live cells in this viable TN-3 powder was 9·0 × 1011 colony-forming units/g. On the other hand, after washing, TN-3 was treated by autoclave for 10 min at 110°C and then lyophilised (non-viable TN-3).

Experimental animals

Female BALB/c mice were purchased from Charles River Japan Inc. (Yokohama, Japan). The mice, aged 5 weeks, used for experiments were fed on a pellet diet (CE-2; Clea Japan Inc., Tokyo, Japan) and received tap water that had been filtered through a PF filer (Organo Co., Tokyo, Japan). All animals were housed in cages with a 12 h light–dark cycle. The temperature and humidity were controlled at 25·0 ± 1·0°C and 55·0 ± 5·0 %, respectively. The animal experimentation guidelines of our institute were followed. The experiments were performed in accordance with the guidelines for the care and use of experimental animals established by the Japanese Association for Laboratory Animals Science in 1987.

Administration of TN-3

Two main experiments were conducted. The first experiment was designed to determine the effects of TN-3 viability on anti-allergic properties. On day 0, the mice were divided into control (n 14), viable TN-3 (n 8) and non-viable TN-3 (n 8) groups. The mice of the control, viable TN-3 and non-viable TN-3 groups were administered saline (0·5 ml), viable TN-3 (5·4 × 1010 colony-forming units/60 mg per 0·5 ml) and non-viable TN-3 (60 mg per 0·5 ml) per mouse for 21 d, respectively.

The second experiment was designed to determine the dose–response effect of non-viable TN-3 on anti-allergic properties. On day 0, the mice were divided into control (n 7), low-dose (n 7), medium-dose (n 7) and high-dose (n 7) groups. The mice of the low-dose, medium-dose and high-dose groups were administered doses of 15 mg, 30 mg and 60 mg non-viable TN-3 per mouse for 21 d, respectively. The mice of the control group were administered 0·5 ml saline per mouse per d for the same duration.

Sensitisation of allergen

The animal model was prepared according to the procedure of Shimada et al. (Reference Shimada, Cheng and Ide16). The mice were sensitised with the purified allergen extract (0·6 mg/ml) from Japanese cedar (Cryptomeria japonica) pollen(Reference Yasueda, Yui and Shimizu20). For sensitisation, the allergen extract of 0·1 ml was injected subcutaneously on days 0 and 1, and then 0·2 ml was injected subcutaneously on days 6, 8 and 14.

Eosinophil accumulation

For challenge, the allergen extract (0·6 mg/ml) of 0·2 ml was injected intraperitoneally on day 20. After 24 h, mice were killed by carbon dioxide, and then peritoneal cells were collected with 4 ml PBS containing 1 % fetal calf serum and heparin (5 U/ml). The number of total leucocytes was counted with a haemocytometer under a microscope. A differential cell (eosinophils, neutrophils, monocytes and lymphocytes) count was carried out under a microscope after fixation and staining with May-Grunwald Giemsa dye. From these results, the proportion of eosinophils to total leucocytes was calculated.

Measurement of serum IgE

Following intraperitoneal challenge by the allergen extract (0·6 mg/ml) on day 20, blood samples of mice were collected 24 h after challenge. Total IgE and allergen-specific IgE in sera were measured by a sandwich ELISA according to the method of Shimada et al. (Reference Shimada, Cheng and Yamasaki17). For measurement of total IgE, ninety-six-well plates for ELISA were coated with each isotype-specific anti-mouse immunoglobulin antibody (PharMingen, San Diego, CA, USA) by incubation overnight at 4°C, and then further treated with 10 % (v/v) fetal calf serum added in PBS for 4 h at room temperature to block any non-specific binding. Subsequently, the serial dilutions of mouse serum samples were incubated in the well for 1 h at room temperature. Purified mouse IgE (PharMingen) antibody was used as the standard. After being washed three times in PBS containing 0·05 % (v/v) Tween 20, biotin-conjugated rat anti-mouse IgE (PharMingen) antibody was added to the well, followed by the addition of streptavidin-peroxidase (Zymed Laboratories, San Francisco, CA, USA) for 1 h at room temperature. After washing six times, the plates were developed using a tetramethylbenzidine substrate solution. The reactions were terminated by the addition of 0·33 m-phosphoric acid. The plates were read in a microplate reader (MTP-300; Corona Inc., Ibaragi, Japan) at 450 nm and the concentration of IgE was calculated according to the standard curve.

For determination of the serum levels of allergen-specific IgE, samples with the 2− 2 and 2− 4 dilutions were placed on ELISA plates coated previously with cedar pollen allergen. The experimental procedure then proceeded with the methods as described above, and the antibody levels were expressed as the absorbance at 450 nm.

Active cutaneous anaphylaxis

Following an intravenous injection of 0·05 ml Evans Blue (1 % (w/v); Sigma Chemical), ACA was elicited in the skin of the belly by the subcutaneous injection of 0·05 ml of cedar pollen allergen on day 21. At 30 min after the allergen challenge, mice were killed by carbon dioxide, and then a piece of skin shaved from each mouse was placed in 4·5 ml of mixture solution (1·5 ml sodium sulfate anhydrous (0·05 %, w/v) and 3·0 ml acetone). After vigorous shaking overnight, the absorbance of extravasated dye was measured colorimetrically at 620 nm.

Statistical analysis

The data are presented as the mean values and standard deviations. Statistical significance of the results was evaluated by Fisher's protected least significant difference (comparison between three groups) or the Bonferroni–Dunn test (comparison between four groups) using StatView software (SAS Institute, Inc., Cary, NC, USA). A value of P < 0·05 was considered significant.

Results

Effects of TN-3 viability on eosinophil accumulation

We first examined the anti-allergic effect with regard to the viability of TN-3 isolated from deep seawater on eosinophil accumulation. The total number of accumulated cells in the control, viable TN-3 and non-viable TN-3 groups was 1·15 × 106, 1·06 × 106 and 0·64 × 106 cells/ml, respectively. The number of cells was significantly lower in the non-viable TN-3 group than in the control group (P < 0·01). As shown in Fig. 1, the proportion of eosinophils to total leucocytes in the control, viable TN-3 and non-viable TN-3 groups was 21·5, 22·5 and 11·3 %, respectively. Non-viable TN-3 was found to significantly suppress the eosinophil accumulation in allergen-primed mice (P < 0·01). No significant difference was observed between the control and viable TN-3 groups.

Fig. 1 Effect of oral administration of viable or non-viable TN-3 on eosinophil accumulation in allergen-primed BALB/c mice. The mice were divided into control, viable TN-3 and non-viable TN-3 groups. The mice of the control, viable TN-3 and non-viable TN-3 groups were administered saline, viable TN-3 or non-viable TN-3 for 21 d, respectively. The mice were sensitised and challenged with the purified allergen extract from Japanese cedar (Cryptomeria japonica) pollen. Peritoneal cells were collected 24 h after challenge. The number of total leucocytes and differential cells (eosinophils, neutrophils, monocytes and lymphocytes) was counted, and from these results, the proportion of eosinophils to total leucocytes was calculated. Values are means, with standard deviations represented by vertical bars. **Mean value was significantly different from that of the control group (P < 0·01).

Dose–response effect of non-viable TN-3 on eosinophil accumulation, IgE production and active cutaneous anaphylaxis

Table 1 shows the dose–response effect as to anti-allergic properties of non-viable TN-3 on eosinophil accumulation, IgE production and ACA. No signification difference was observed among all groups on the total number of accumulated cells. Mice that had been administered low (15 mg per mouse) and high (60 mg per mouse) doses of non-viable TN-3 had significantly suppressed eosinophil accumulation compared with control mice (P < 0·05). However, there were no effects for eosinophil accumulation in the mice that had been administered the medium dose (30 mg per mouse).

Table 1 Dose–response effect of non-viable TN-3 on eosinophil accumulation, IgE production and active cutaneous anaphylaxis (ACA)

(Mean values and standard deviations)

Mean value was significantly different from that of the control group: * P < 0·05, ** P < 0·01.

Administration of non-viable TN-3 at low and high doses was found to significantly reduce the total IgE levels (P < 0·01). In contrast, total IgE in the medium-dose group had the same levels as the control group. No significant difference in the production of allergen-specific IgE was found between the three TN-3-administered groups and the control group.

Mice that had been administered low and high doses of non-viable TN-3 tended to have suppressed ACA compared with control mice (P = 0·107 and P = 0·055, respectively). On the other hand, no difference was observed in ACA between the medium-dose and control mice.

Discussion

In the present study, we demonstrated that non-viable TN-3, rather than the viable form, was effective in suppressing eosinophil accumulation in allergen-primed mice. Studies of the immunomodulatory properties of dietary LAB have drawn the general conclusion that live bacteria are more effective at modulating immunity than their non-viable counterparts(Reference De Simone, Salvadori and Negri21). However, the pro-Th1 immunomodulatory Lactobacillus casei and L. plantarum have been shown to down-regulate allergic molecules in antigen-primed mice either by oral delivery in the viable form or systemic delivery in the heat-killed form(Reference Matsuzaki and Chin22Reference Shida, Makino and Morishita26). Differences in immunomodulatory properties as a function of LAB viability may depend on species and strains.

The health effects of non-viable probiotics have been summarised by Ouwehand & Salminen(Reference Ouwehand and Salminen27). Thus it is clear that non-viable probiotics also have documented health effects. Some studies have also shown that effects on human health and well-being do not necessarily involve changes in the intestinal microflora or viability of the probiotic(Reference Ouwehand and Salminen27Reference Saavedra29). These studies have indicated that viability is not necessary for all probiotic effects, but further studies comparing viable strains and products with non-viable strains are urgently needed. In addition, studies involving not only heat-killed or otherwise inactivated microbes have shown that even the cell wall components of some probiotic microbes may have significant effects on the health and well-being of host animals when incorporated into the diet(Reference Salminen and von Wright30).

The use of non-viable instead of viable micro-organisms would have economic advantages in terms of longer shelf-life and reduced requirements for refrigerated storage. Non-viable micro-organisms expand the potential use of probiotics to areas where strict handling conditions cannot be met, for example, in developing countries. Safety is an important requirement for probiotics and it is worth noting that non-viable or inactivated microbial preparations have very few, if any, adverse effects. While there is a possibility of adverse reactions to the protein components of such preparations, adverse reactions have not been reported for currently used probiotics (viable, non-viable or cell wall components)(Reference Salminen and von Wright30). Even though current probiotics are considered safe for food use(Reference Ouwehand and Salminen27, Reference Salminen, Ouwehand and Benno31), non-viable probiotics and microbial cell wall components are the least likely to cause safety concerns.

In the present study, non-viable TN-3 did not have the potential to inhibit eosinophil accumulation, IgE production and ACA in a dose-dependent manner at doses of 15, 30 and 60 mg. Interestingly, all three models of allergy gave the same results at the low and high doses, but not at the medium dose. Similarly, it has been reported that the effect of orally administered L. casei strain Shirota on total IgE production is not dose dependent(Reference Matsuzaki, Yamazaki and Hashimoto32). It has been suggested that the amount of non-viable TN-3 used in the present study might constitute the optimal dosage for maximal inhibition of allergic responses. Further research is needed to elucidate the detailed mechanisms whereby orally delivered TN-3 exerts its anti-allergic effects, including evaluation of the optimal dosage.

Acknowledgements

We would like to thank Dr Tamotsu Furumai of Toyama Prefectural University for the isolation of Enterococcus sp. strain TN-3. M. K., M. O., C. M. and T. S. carried out the animal experiments for this study. A. H. prepared the LAB used in the present study. T. E. and L. C. advised the expert approach in the present study.

There are no conflicts of interest.

References

1Djukanović, R, Wilson, JW, Britten, KM, et al. (1990) Quantitation of mast cells and eosinophils in the bronchial mucosa of symptomatic atopic asthmatics and healthy control subjects using immunohistochemistry. Am Rev Respir Dis 142, 863871.Google Scholar
2Hamelmann, E & Gelfand, EW (1999) Role of IL-5 in the development of allergen-induced airway hyperresponsiveness. Int Arch Allergy Immunol 120, 816.Google Scholar
3Leung, DY (1995) Atopic dermatitis: the skin as a window into the pathogenesis of chronic allergic diseases. J Allergy Clin Immunol 96, 302318.Google Scholar
4Durham, SR (1998) Mechanisms of mucosal inflammation in the nose and lungs. Clin Exp Allergy 28, Suppl. 2, 1116.Google Scholar
5Wills-Karp, M (1999) Immunologic basis of antigen-induced airway hyperresponsiveness. Annu Rev Immunol 17, 255281.Google Scholar
6Punnonen, J, Aversa, G, Cocks, BG, et al. (1994) Role of interleukin-4 and interleukin-13 in synthesis of IgE and expression of CD23 by human B cells. Allergy 49, 576586.Google Scholar
7Pene, J, Rousset, F, Briere, F, et al. (1988) IgE production by normal human lymphocytes is induced by interleukin 4 and suppressed by interferons γ and α and prostaglandin E2. Proc Natl Acad Sci U S A 85, 68806884.Google Scholar
8Bochner, BS, Undem, BJ & Lichtenstein, LM (1994) Immunological aspects of allergic asthma. Annu Rev Immunol 12, 295335.Google Scholar
9Gajewski, TF & Fitch, FW (1988) Anti-proliferative effect of IFN-γ in immune regulation. I. IFN-γ inhibits the proliferation of Th2 but not Th1 murine helper T lymphocyte clones. J Immunol 140, 42454252.Google Scholar
10Brown, MA & Hural, J (1997) Functions of IL-4 and control of its expression. Crit Rev Immunol 17, 132.Google Scholar
11Klein, G, Pack, A, Bonaparte, C, et al. (1998) Taxonomy and physiology of probiotic lactic acid bacteria. Int J Food Microbiol 41, 103125.Google Scholar
12Abe, S, Ohashi, K, Uchida, K, et al. (1993) Antitumor and antimicrobial activities of enterococcal preparation orally administered to mice. Ann N Y Acad Sci 685, 372374.Google Scholar
13Hasegawa, T, Ogura, Y, Inomata, T, et al. (1994) Effect of orally administered heat-killed Enterococcus faecalis FK-23 preparation on leukopenia in mice treated with cyclophosphamide. J Vet Med Sci 56, 12031206.Google Scholar
14Satonaka, K, Ohashi, K, Nohmi, T, et al. (1996) Prophylactic effect of Enterococcus faecalis FK-23 preparation on experimental candidiasis in mice. Microbiol Immunol 40, 217222.Google Scholar
15Shimada, T, Kadowaki, Y, Ohmiya, K, et al. (1996) Identification of an RNA fraction from Enterococcus faecalis FK-23 cells as the antihypertensive compound. J Ferment Bioeng 82, 109112.Google Scholar
16Shimada, T, Cheng, L, Ide, M, et al. (2003) Effect of lysed Enterococcus faecalis FK-23 (LFK) on allergen-induced peritoneal accumulation of eosinophils in mice. Clin Exp Allergy 33, 684687.Google Scholar
17Shimada, T, Cheng, L, Yamasaki, A, et al. (2004) Effects of lysed Enterococcus faecalis FK-23 on allergen-induced serum antibody responses and active cutaneous anaphylaxis in mice. Clin Exp Allergy 34, 17841788.Google Scholar
18Shimada, T, Cheng, L, Enomoto, T, et al. (2004) Lysed Enterococcus faecalis FK-23 oral administration reveals inverse association between tuberculin responses and clinical manifestations in perennial allergic rhinitis: a pilot study. J Investig Allergol Clin Immunol 14, 187192.Google Scholar
19Hayashi, A, Shimada, T, Onaka, H, et al. (2007) Isolation and phenotypic characterization of enterococci from the deep-seawater samples collected in Toyama bay (article in Japanese with an English summary). Jpn J Lactic Acid Bact 18, 5864.Google Scholar
20Yasueda, H, Yui, Y, Shimizu, T, et al. (1983) Isolation and partial characterization of the major allergen from Japanese cedar (Cryptomeria japonica) pollen. J Allergy Clin Immunol 71, 7786.Google Scholar
21De Simone, C, Salvadori, BB, Negri, R, et al. (1986) The adjuvant effect of yogurt on production of γ-interferon by Con A-stimulated human peripheral blood lymphocytes. Nutr Rep Int 33, 419433.Google Scholar
22Matsuzaki, T & Chin, J (2000) Modulating immune responses with probiotic bacteria. Immunol Cell Biol 78, 6773.Google Scholar
23Kato, I, Tanaka, K & Yokokura, T (1999) Lactic acid bacterium potently induces the production of interleukin-12 and interferon-γ by mouse splenocytes. Int J Immunopharmacol 21, 121131.Google Scholar
24Tejada-Simon, MV, Ustunol, Z & Pestka, JJ (1999) Ex vivo effects of lactobacilli, streptococci, and bifidobacteria ingestion on cytokine and nitric oxide production in a murine model. J Food Prot 62, 162169.Google Scholar
25Murosaki, S, Yamamoto, Y, Ito, K, et al. (1998) Heat-killed Lactobacillus plantarum L-137 suppresses naturally fed antigen-specific IgE production by stimulation of IL-12 production in mice. J Allergy Clin Immunol 102, 5764.Google Scholar
26Shida, K, Makino, K, Morishita, A, et al. (1998) Lactobacillus casei inhibits antigen-induced IgE secretion through regulation of cytokine production in murine splenocyte cultures. Int Arch Allergy Immunol 115, 278287.Google Scholar
27Ouwehand, A & Salminen, S (1998) The health effects of cultured milk products with viable and non-viable bacteria. Int Dairy J 8, 749758.Google Scholar
28Salminen, S, von Wright, A, Morelli, L, et al. (1998) Demonstration of safety of probiotics – a review. Int J Food Microbiol 44, 93106.Google Scholar
29Saavedra, JM (1995) Microbes to fight microbes: a not so novel approach to controlling diarrheal disease. J Pediatr Gastroenterol Nutr 21, 125129.Google Scholar
30Salminen, S & von Wright, A (1998) Current human probiotics – safety assured? Microbial Ecol Health Dis 10, 6877.Google Scholar
31Salminen, S, Ouwehand, A, Benno, Y, et al. (1999) Probiotics: how should they be defined? Trends Food Sci Tech 10, 107110.Google Scholar
32Matsuzaki, T, Yamazaki, R, Hashimoto, S, et al. (1998) The effect of oral feeding of Lactobacillus casei strain Shirota on immunoglobulin E production in mice. J Dairy Sci 81, 4853.Google Scholar
Figure 0

Fig. 1 Effect of oral administration of viable or non-viable TN-3 on eosinophil accumulation in allergen-primed BALB/c mice. The mice were divided into control, viable TN-3 and non-viable TN-3 groups. The mice of the control, viable TN-3 and non-viable TN-3 groups were administered saline, viable TN-3 or non-viable TN-3 for 21 d, respectively. The mice were sensitised and challenged with the purified allergen extract from Japanese cedar (Cryptomeria japonica) pollen. Peritoneal cells were collected 24 h after challenge. The number of total leucocytes and differential cells (eosinophils, neutrophils, monocytes and lymphocytes) was counted, and from these results, the proportion of eosinophils to total leucocytes was calculated. Values are means, with standard deviations represented by vertical bars. **Mean value was significantly different from that of the control group (P < 0·01).

Figure 1

Table 1 Dose–response effect of non-viable TN-3 on eosinophil accumulation, IgE production and active cutaneous anaphylaxis (ACA)(Mean values and standard deviations)