Title: Detection of Upwind Pathogens Using Aircraft and Ground Stations

The first reported investigations of microorganism occurrence in the air can be traced back to early 19th century. Since then the study of bioaerosols have come a long way, however, it remains a poorly understood area(Després et al. 2012). The actual identity, diversity, and abundance of distinct types of bioaerosol particles as well as their temporal and spatial variability are not well characterized. Bioaerosols play a key role in the dispersal of reproductive units from plants and microbes (pollen, spores, etc.), for which the atmosphere enables transport over geographic barriers and long distances(FröhlichNowoisky et al. 2016). The dispersal of plant, animal, and human pathogens and allergens has major implications for agriculture and public health. We hypothesized that airborne microbes can reach the upper atmosphere (i.e., above the boundary layer ~2 km in altitude) and deliver disease into downwind destinations. We utilized a unique set of bioaerosol samples from atmospheric aircraft observatories (NASA) to study the microbial diversity, abundance, and viability of bioaerosols reaching California during the springtime when the jet stream delivers the largest amount of Asian transpacific aerosols to N. America. We collaborated with a NASA Ames with unique access to upper troposphere and lower stratosphere bioaerosol samples on the Pacific Coast of California. We analyzed the aerosol samples using microbiological techniques, shotgun metagenomic sequencing and advanced bioinformatic tools to identify the viable and total microbial species that were detected. A number of bacterial and fungal species were identified. This study provided a deeper understanding of the microbial species that can survive in the upper atmospheric conditions. This study set the foundation for future studies on better understanding of the potential impact of airborne microbes on disease transmission affecting human, animal, or crop health.