AI Article Synopsis
- The study investigates the motility differences between filamentous and comma-shaped forms of the cholera bacterium O1 strain under different viscosity levels.
- Filamentous cells show improved motility in viscous environments, aiding their survival, particularly in the human gut.
- The findings suggest that these filamentous forms have a better ability to navigate through mucus layers, which could enhance their role in causing infections and inform new approaches to cholera management.
Article Abstract
Unlabelled: the causative agent of cholera, displays remarkable adaptability to diverse environmental conditions through morphological changes that enhance its pathogenicity and influence the global epidemiology of the disease. This study examines the motility differences between filamentous and comma-shaped forms of the O1 strain under various viscosity conditions. Utilizing the El Tor strain, we induced filamentous transformation and conducted a comparative analysis with the canonical comma-shaped morphology. Our methodology involved assessing motility patterns, swimming speeds, rotation rates, kinematics, and reversal frequencies using dark-field microscopy and high-speed imaging techniques. The results show that filamentous cells retain enhanced motility in viscous environments, indicating an evolutionary adaptation for survival in varied habitats, particularly the human gastrointestinal tract. Filamentous forms exhibited increased reversal behavior at mucin interfaces, suggesting an advantage in penetrating the mucus layer. Furthermore, the presence of filamentous cells in bile-supplemented medium underscores their relevance in natural infection scenarios.
Importance: This study highlights the enhanced motility of filamentous in viscous environments, an adaptation that may provide a survival advantage in the human gastrointestinal tract. By demonstrating increased reversal behavior at mucin interfaces, filamentous cells exhibit a superior ability to penetrate the mucus layer, which is crucial for effective colonization and infection. Filamentous cells in bile-supplemented media further underscores their potential role in disease pathogenesis. These findings offer critical insights into the morphological flexibility of and its potential implications for infection dynamics, paving the way for more effective strategies in managing and preventing cholera outbreaks.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11708025 | PMC |
| http://dx.doi.org/10.1128/mbio.02469-24 | DOI Listing |
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