Abstract
BACKGROUND: Fine particulate matter (PM(2.5)) is a well-known air pollutant and has been suggested as a potential vector for airborne viruses, raising public health concerns. This study employed metaviromic sequencing to systematically analyze the composition, temporal-spatial distribution, and environmental influencing factors of viral communities in PM(2.5) samples collected from Fuzhou, China, to identify potential high-risk viruses and the key factors influencing their presence. METHODS: Three outdoor PM(2.5) sampling sites were established in the city center, rural-urban fringe, and rural areas of Fuzhou. Samples were collected from December 2022 to August 2023. The collected PM(2.5) samples underwent high-throughput sequencing and viral annotation, and statistical analysis along with multivariate regression analyses were used to investigate the characteristics of viral distribution and its influencing factors. RESULTS: A total of 117 PM(2.5) samples were collected. The viral community diversity in PM(2.5) exhibited significant seasonal variation (p < 0.05), with the highest number of viral species detected in winter at both the genus and species levels. In terms of regional distribution, the highest number of viruses was found in city center and the lowest in rural areas, while there were slight differences in viral composition among regions, these were not statistically significant. Additionally, analysis of environmental factors revealed that sulfur dioxide (SO(2)) in the air quality factor and wind speed in the meteorological factor influenced the relative abundance of viruses. DISCUSSION: Urbanization and human activities may affect regional viral patterns, but the overall improved air quality in Fuzhou could have reduced regional disparities. Environmental factors such as SO(2) and wind speed may influence viral survival and dispersion, suggesting that non-traditional pollutants warrant closer attention in the context of airborne virus transmission.