The genus Pantoea is a group of ubiquitous bacteria which has been proven to lead to rot of melon. Swarming of the bacteria is a powerful way to rapidly colonize cells which may be related to biofilm development and increase bacterial survival in the environment. However, previous research mainly focused on the bacterial swarming motility and biofilm formation in plants rather than their impact on fresh-cut fruits. As a result, this study employed Pantoea vagans M17 exhibiting swarming motility and biofilm formation to investigate the impact of these two phenotypes on the quality of fresh-cut melons. The results of transmission electron microscopy and sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) revealed that Pantoea spp. was able to differentiate into swarmer cells on the semisolid medium used in this study. Bacterial motility was promoted at neutral pH (pH 6.5) while biofilm formation was enhanced at higher pH (pH 8.0). Furthermore, Pantoea spp. exhibited stronger swarming effect and biofilm formation at its optimal growth temperature (30℃). When we cultured P. vagans M17 with HPP melon juice as the substrate, not only enabled bacterial cell growth and biofilm formation but also significantly promoted swarming effect. In order to learn more about the impact of melon composition on Pantoea spp., sugars accounting for the most proportion of melon nutrient content were taken to test the swarming motility of P. vagans M17. We discovered that raffinose impacted swarming with concentration-effect relation and sucrose supported swarming effect better than the other sugars. In addition, compared with supplemented sucrose and L-malic acid individually, swarming motility of P. vagans M17 was significantly increased on the medium supplemented both. Lastly, inoculation of P. vagans M17 on fresh-cut melons showed slimy surface and significant changes on the content of organic acids. Future research could better understand the correlation between the phenotypes and quality of fresh-cut melons with the whole genome sequence information of P. vagans M17. Hoping we could take more precise ways to extend the shelf life in the near future.