N ontuberculous mycobacteria (NTM) are ubiquitous microorganisms found in indoor and outdoor habitats, including water, soil, and dust. NTM can infect susceptible persons, including those with lung diseases such as cystic fi brosis (CF) (1). Previous surveys conducted in the United States have found that Mycobacterium avium complex (MAC) species are clinically relevant and the most frequently isolated NTM (2). MAC consists of 9 slow-growing mycobacterial species (3-6), of which the 2 most frequently observed are M. avium (MAV) and M. intracellulare, including its subspecies intracellulare (MINT) and subspecies chimaera (MCHIM) (4). In the United States, most persons with CF and positive NTM cultures (61%) had MAC species infections (2,7). MAC infections increased by 3% annually during 2010-2014.MAC pulmonary infections are probably acquired by inhalation of aerosols ( 8), but the sources and modes of transmission of MAC remain unclear. Studies using various molecular genotyping methods have shown MAC isolates from human airway samples to have high genetic similarity to isolates from animals (8-10), water (11,12), bathroom faucets (13), showerheads (14,15), pools (16), and soil (17). Other potential MAC infection sources include fomites, zoonotic sources, and contaminated materials (10,18). Despite the clinical relevance of MAC and its prevalence among persons with CF, the genomic relationships of MAC isolates and the potential for person-to-person transmission are poorly understood. Whole-genome sequencing (WGS) to analyze the genetic diversity of MAC is aimed at identifying MAC infections that cluster by high bacterial genomic sequence similarity, particularly in susceptible populations such as persons with CF. Unclustered isolates are unrelated and are therefore not implicated in transmission, but clustering between MAC isolates suggests that they are derived from the same source (i.e., shared water, surfaces, or person-to-person transmission). To this end, we analyzed the WGS of NTM isolates
