Arginine metabolic control of airway inflammation
Kewal Asosingh, Chris D. Lauruschkat, Mario Alemagno, Matthew Frimel, Nicholas Wanner, Kelly Weiss, Sean Kessler, Deborah A. Meyers, Carole Bennett, Weiling Xu, Serpil Erzurum
Kewal Asosingh, Chris D. Lauruschkat, Mario Alemagno, Matthew Frimel, Nicholas Wanner, Kelly Weiss, Sean Kessler, Deborah A. Meyers, Carole Bennett, Weiling Xu, Serpil Erzurum
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Research Article Inflammation Metabolism

Arginine metabolic control of airway inflammation

Abstract

Inducible nitric oxide synthase (iNOS) and arginase-2 (ARG2) share a common substrate, arginine. Higher expression of iNOS and exhaled NO are linked to airway inflammation in patients. iNOS deletion in animal models suggests that eosinophilic inflammation is regulated by arginine metabolism. Moreover, ARG2 is a regulator of Th2 response, as shown by the development of severe eosinophilic inflammation in ARG2–/– mice. However, potential synergistic roles of iNOS and ARG2 in asthma have not been explored. Here, we hypothesized that arginine metabolic fate via iNOS and ARG2 may govern airway inflammation. In an asthma cohort, ARG2 variant genotypes were associated with arginase activity. ARG2 variants with lower arginase activity, combined with levels of exhaled NO, identified a severe asthma phenotype. Airway inflammation was present in WT, ARG2–/–, iNOS–/–, and ARG2–/–/iNOS–/– mice but was greatest in ARG2–/–. Eosinophilic and neutrophilic infiltration in the ARG2–/– mice was abrogated in ARG2–/–/iNOS–/– animals. Similarly, angiogenic airway remodeling was greatest in ARG2–/– mice. Cytokines driving inflammation and remodeling were highest in lungs of asthmatic ARG2–/– mice and lowest in the iNOS–/–. ARG2 metabolism of arginine suppresses inflammation, while iNOS metabolism promotes airway inflammation, supporting a central role for arginine metabolic control of inflammation.

Authors

Kewal Asosingh, Chris D. Lauruschkat, Mario Alemagno, Matthew Frimel, Nicholas Wanner, Kelly Weiss, Sean Kessler, Deborah A. Meyers, Carole Bennett, Weiling Xu, Serpil Erzurum

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Figure 3

Increased angiogenic airway remodeling, inflammatory, and angiogenic cytokines in ARG2–/– mice.

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Increased angiogenic airway remodeling, inflammatory, and angiogenic cyt...
(AD) CD4+ T cell polarization in ARG2–/– mice analyzed using splenic T cells. Splenocytes were isolated and analyzed for effector T cell polarization. (E) vWF staining for blood vessels in paraffin-embedded lung tissue sections. Representative low- and high-power lung images from WT mice exposed to saline or HDME as shown. Original magnification ×200. (F) Quantification of the microvessel density in WT, ARG2–/–, iNOS–/–, and iNOS–/–/ARG2–/– mice exposed to HDME. The number of vessels per 2500 μm2 area is shown. (G) IL-5 levels in BALF. (H) Eotaxin-2 levels in BALF. (IL) IL-17, KC, MIP-2, and LIX levels in lung tissue protein extract. *P < 0.05 between respective genotypes in HDME vs. saline groups. ϕP < 0.05 between WT and ARG2–/–. φP < 0.05 between ARG2–/– and ARG2–/–iNOS–/–. σP < 0.05 between iNOS–/– and ARG2–/–iNOS–/–. #P < 0.05 between iNOS–/– and ARG2–/–. λP < 0.05 between WT and iNOS–/– or WT and ARG2–/–iNOS–/–. Each dot represents data from 1 mouse, and mean ± SEM values are shown. Wilcoxon test was used in AD, and Student’s t test was used in FL for group comparisons.