A humanized mouse model to study asthmatic airway inflammation via the human IL-33/IL-13 axis
Ryoji Ito, Shuichiro Maruoka, Kaori Soda, Ikumi Katano, Kenji Kawai, Mika Yagoto, Asami Hanazawa, Takeshi Takahashi, Tomoyuki Ogura, Motohito Goto, Riichi Takahashi, Shota Toyoshima, Yoshimichi Okayama, Kenji Izuhara, Yasuhiro Gon, Shu Hashimoto, Mamoru Ito, Satoshi Nunomura
Ryoji Ito, Shuichiro Maruoka, Kaori Soda, Ikumi Katano, Kenji Kawai, Mika Yagoto, Asami Hanazawa, Takeshi Takahashi, Tomoyuki Ogura, Motohito Goto, Riichi Takahashi, Shota Toyoshima, Yoshimichi Okayama, Kenji Izuhara, Yasuhiro Gon, Shu Hashimoto, Mamoru Ito, Satoshi Nunomura
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Resource and Technical Advance Immunology Inflammation

A humanized mouse model to study asthmatic airway inflammation via the human IL-33/IL-13 axis

Abstract

Asthma is one of the most common immunological diseases and is characterized by airway hyperresponsiveness (AHR), mucus overproduction, and airway eosinophilia. Although mouse models have provided insight into the mechanisms by which type-2 cytokines induce asthmatic airway inflammation, differences between the rodent and human immune systems hamper efforts to improve understanding of human allergic diseases. In this study, we aim to establish a preclinical animal model of asthmatic airway inflammation using humanized IL-3/GM-CSF or IL-3/GM-CSF/IL-5 Tg NOD/Shi-scid-IL2rγnull (NOG) mice and investigate the roles of human type-2 immune responses in the asthmatic mice. Several important characteristics of asthma — such as AHR, goblet cell hyperplasia, T cell infiltration, IL-13 production, and periostin secretion — were induced in IL-3/GM-CSF Tg mice by intratracheally administered human IL-33. In addition to these characteristics, human eosinophilic inflammation was observed in IL-3/GM-CSF/IL-5 Tg mice. The asthmatic mechanisms of the humanized mice were driven by activation of human Th2 and mast cells by IL-33 stimulation. Furthermore, treatment of the humanized mice with an anti–human IL-13 antibody significantly suppressed these characteristics. Therefore, the humanized mice may enhance our understanding of the pathophysiology of allergic disorders and facilitate the preclinical development of new therapeutics for IL-33–mediated type-2 inflammation in asthma.

Authors

Ryoji Ito, Shuichiro Maruoka, Kaori Soda, Ikumi Katano, Kenji Kawai, Mika Yagoto, Asami Hanazawa, Takeshi Takahashi, Tomoyuki Ogura, Motohito Goto, Riichi Takahashi, Shota Toyoshima, Yoshimichi Okayama, Kenji Izuhara, Yasuhiro Gon, Shu Hashimoto, Mamoru Ito, Satoshi Nunomura

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Figure 6

Eosinophilic inflammation in hu–IL-3/GM-CSF/IL-5 Tg mice.

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Eosinophilic inflammation in hu–IL-3/GM-CSF/IL-5 Tg mice. (A) Periodic a...
(A) Periodic acid-Schiff (PAS) staining of the lungs of hu–IL-3/GM/IL-5 Tg mice treated with or without IL-33. (B) Quantification of goblet cells in bronchus lesions. (C) IL-13 level in the BALF of hu–IL-3/GM/IL-5 Tg mice treated with or without IL-33. (D) Mice received increasing doses of methacholine as indicated. Airway resistance (R) after human IL-33 or saline treatment was measured using the FinePointe airway resistance analysis system. Data are represented each 9 mice/group. (E) Flow cytometry of CD45+CD66b+ eosinophils in the BALF of hu–non-Tg, –IL-3/GM Tg, and –IL-3/GM/IL-5 Tg mice treated with or without IL-33. (F) Quantification of total cells and human and murine eosinophils in BALF. (G and H) Human and murine eotaxin-1 and -2 (G) and human eosinophil-derived neurotoxin (EDN) levels (H) in the BALF of hu–non-Tg, –IL-3/GM Tg, and –IL-3/GM/IL-5 Tg mice treated with or without IL-33. Data are represented each 5 or 6 mice in F and G; 3 or 4 hu–non-Tg, 6 hu–IL-3/GM Tg, and 14 or 15 hu–IL-3/GM/IL-5 Tg mice were used in H. Original magnification, ×40. Scale bar: 10 μm. Statistical significance was calculated using Student’s t test (BD) and 1-way ANOVA (FH). *P < 0.05, **P < 0.005, and ***P < 0.0005.