Low-dose oral cadmium increases airway reactivity and lung neuronal gene expression in mice.

Joshua D Chandler,Dana Boyd Barr,David C Neujahr,Sophia A Banton,Cherry Wongtrakool,Shuzhao Li,Dean P Jones,Young-Mi Go,Michael L Orr,Roy L Sutliff

doi:10.14814/phy2.12821

Joshua D Chandler, Dana Boyd Barr + Show 8 more

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https://doi.org/10.14814/phy2.12821

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Abstract

Inhalation of cadmium (Cd) is associated with lung diseases, but less is known concerning pulmonary effects of Cd found in the diet. Cd has a decades‐long half‐life in humans and significant bioaccumulation occurs with chronic dietary intake. We exposed mice to low‐dose CdCl2 (10 mg/L in drinking water) for 20 weeks, which increased lung Cd to a level similar to that of nonoccupationally exposed adult humans. Cd‐treated mice had increased airway hyperresponsiveness to methacholine challenge, and gene expression array showed that Cd altered the abundance of 443 mRNA transcripts in mouse lung. In contrast to higher doses, low‐dose Cd did not elicit increased metallothionein transcripts in lung. To identify pathways most affected by Cd, gene set enrichment of transcripts was analyzed. Results showed that major inducible targets of low‐dose Cd were neuronal receptors represented by enriched olfactory, glutamatergic, cholinergic, and serotonergic gene sets. Olfactory receptors regulate chemosensory function and airway hypersensitivity, and these gene sets were the most enriched. Targeted metabolomics analysis showed that Cd treatment also increased metabolites in pathways of glutamatergic (glutamate), serotonergic (tryptophan), cholinergic (choline), and catecholaminergic (tyrosine) receptors in the lung tissue. Protein abundance measurements showed that the glutamate receptor GRIN2A was increased in mouse lung tissue. Together, these results show that in mice, oral low‐dose Cd increased lung Cd to levels comparable to humans, increased airway hyperresponsiveness and disrupted neuronal pathways regulating bronchial tone. Therefore, dietary Cd may promote or worsen airway hyperresponsiveness in multiple lung diseases including asthma.

Highlights

Cadmium (Cd) is a toxic environmental metal with both natural and anthropogenic sources (Satarug et al 2003; Satarug and Moore 2004)
The results (0.54 Æ 0.20 ng Cd/mg protein; Fig. 1) showed that human tissue had a similar mean value to that of the mouse model, consistent with prior data (Mari et al 2014). These results show that low-dose Cd in drinking water for 20 weeks increased Cd in mouse lung tissue to levels comparable to human lungs
Circulating Cd is predictive of airway obstruction and loss of lung function in healthy adults (Oh et al 2014; Yoon et al 2014) suggesting that once absorbed, Cd is a strong determinant of lung disease

Summary

Introduction

Cadmium (Cd) is a toxic environmental metal with both natural and anthropogenic sources (Satarug et al 2003; Satarug and Moore 2004). Despite success in decreasing Cd exposures, ongoing dispersion of Cd occurs into air, water, and soil, and remains a significant global concern due to Cd accumulation in foodstuffs (Satarug et al 2003; Riederer et al 2013). About 10% of ingested Cd is absorbed via divalent metal transporter-1, and higher absorption occurs in menstruating women due to increased activity of intestinal iron transporters, which transport Cd (Olsson et al 2002). The absorbed fraction is poorly eliminated with excretion of only ~0.001% of body Cd per day and a half-life >10 years (Waalkes 2003; Satarug and Moore 2004; Suwazono et al 2009). Blood levels of Cd significantly increase throughout adulthood (Lee and Kim 2016)

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