Distinct responses of lung macrophages and airway epithelial cells to Hawai'i-derived volcanic ash and nontuberculous mycobacteria
University Of Texas Hlth Ctr At Tyler, Tyler TX
Investigators
Abstract
PROJECT SUMMARY/ABSTRACT Nontuberculous mycobacteria (NTM) cause an emerging, chronic, and challenging to treat pulmonary disease (PD) whose numbers now undeniably surpass tuberculosis cases in the United States (U.S.) and other geographic regions globally. NTM infections are notoriously difficult and expensive to eradicate, prone to relapse and reinfection, and refractory to current anti-mycobacterial therapies. The environmental niches of NTM also remain largely ill-defined. This lack of knowledge contributes to the on-going frustration to understand where these pulmonary infections are acquired. In the U.S., Hawaiâi is a geographic hot spot for NTM PD. Our work in Hawaiâi revealed an abundance of respiratory important NTM including Mycobacterium abscessus subsp. abscessus, Mycobacterium avium, and Mycobacterium chimaera in household and non-household water biofilms and soil. A unique environmental factor that may impact NTM PD in Hawaiâi is exposure to aerosol pollutants from the KÄ«lauea volcano, one of the most actively erupting volcanoes on Earth. Fine volcanic ash particles can be breathed deep into the lungs causing irritation and cough. But, is it possible for volcanic ash to also carry infectious NTM? Through our data, we show microbiological culture of viable M. abscessus, M. avium, and M. chimaera from ash recovered during the 2018 eruption of KÄ«lauea and also from the KÄ«lauea environment, supporting the possibility of volcanic ash as a newly described fomite for NTM. We demonstrate KÄ«lauea ash is not directly toxic to KÄ«lauea-derived NTM and that ash exposure reduces NTM control by human macrophages. Our projectâs broad, long-term objective is to elucidate the innate immunological mechanisms used by human lung cells in response to NTM infection and aerosol pollutants such as volcanic ash, providing implications that extend beyond Hawaiâi with millions of people worldwide living within kilometers of actively erupting volcanoes. Herein, we leverage our unique collection of volcanic ash and NTM isolates recovered from KÄ«lauea ash, the KÄ«lauea environment, and other Hawaiâi and non-Hawaiâi samples to test the hypothesis that KÄ«lauea ash exacerbates control of NTM infection by healthy lung cells through antagonizing NLRP3 inflammasome-mediated pyroptosis defenses. In this proposal, we will: (i) Investigate the biological consequences of KÄ«lauea ash exposures on KÄ«lauea NTM fitness in the absence of host cells and (ii) Determine the effect of KÄ«lauea ash on NLRP3 inflammasome-mediated pyroptosis in clearance of NTM using primary human alveolar macrophages and airway epithelial cells cultured at the air-liquid interface from healthy donors, but also introduce a new 3D apical out airway epithelial organoid culture system to study innate immune responses to KÄ«lauea NTM and KÄ«lauea ash. The studyâs broad application will be a reduction in the biological uncertainties surrounding how exposure to specific environmental respiratory pollutants of global significance such as volcanic ash influences NTM survival inside and outside of healthy human lung cells, while simultaneously informing risk assessments and therapeutic interventions in response to respiratory infections and volcanic ash exposures.
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