Abstract
Cyanobacteria are constructors of biological soil crusts (BSCs); their motility is thought to be crucial for surviving burial and BSC expansion. In this study, X-ray computed microtomography in combination with machine-learning-based image processing was employed to investigate cyanobacteria-dominated BSCs. The structural changes in these BSCs, as well as the behaviors of the dominant cyanobacterium Microcoleus vaginatus therein, in response to changes in water availability and particle burial were visualized and quantitatively analyzed. Hygroscopic swelling of cyanobacteria biomaterials increased pore-network complexity and reduced the porosity and hydraulic radius. Trichomes of M. vaginatus inside BSCs were connected to the surface by tunnel-like structures made of extracellular polymeric substances (EPSs), through which the trichomes migrated to and from the surface in bundles. Despite the generally negative effects of EPSs on hydraulic conductivity, EPS tunnels have the potential to enhance water transfer to the trichomes. Extensive hydration and particle burial led to the spreading migration of individual trichomes, forming net-like structures inside the newly deposited layer. The results highlight the significance of the structural organization of EPSs within BSCs and the importance of cyanobacterial migration in BSC expansion.