Project description:Interactions of lichens and biofilms on terracotta dolia and sculptures

Project description:Discoloration of Leizhou Stone Dog sculptures caused by epilithic biofilms

Project description:Biodeterioration of sculptures of the Leizhou Stone Dog by epilithic biofilms

Project description:sandstone sculptures environment Metagenome

Project description:Arctic lichens Metagenome

Project description:Lichens of Gujarat

Project description:Bacteria associated with lichens

Project description:Ravindra Garde, Bashar Ibrahim & Stefan Schuster. Extending the minimal model of metabolic oscillations in Bacillus subtilis biofilms. Scientific Reports 10, 1 (2020). Biofilms are composed of microorganisms attached to a solid surface or floating on top of a liquid surface. They pose challenges in the field of medicine but can also have useful applications in industry. Regulation of biofilm growth is complex and still largely elusive. Oscillations are thought to be advantageous for biofilms to cope with nutrient starvation and chemical attacks. Recently, a minimal mathematical model has been employed to describe the oscillations in Bacillus subtilis biofilms. In this paper, we investigate four different modifications to that minimal model in order to better understand the oscillations in biofilms. Our first modification is towards making a gradient of metabolites from the center of the biofilm to the periphery. We find that it does not improve the model and is therefore, unnecessary. We then use realistic Michaelis-Menten kinetics to replace the highly simple mass-action kinetics for one of the reactions. Further, we use reversible reactions to mimic the diffusion in biofilms. As the final modification, we check the combined effect of using Michaelis-Menten kinetics and reversible reactions on the model behavior. We find that these two modifications alone or in combination improve the description of the biological scenario.

Project description:Non-target metabolomics of lichens exposed to extreme environmental conditions such as pressure and ultraviolet light

Project description:Biofilms offer an excellent example of ecological interaction among bacteria. Temporal and spatial oscillations in biofilms are an emerging topic. In this paper, we describe the metabolic oscillations in Bacillus subtilis biofilms by applying the smallest theoretical chemical reaction system showing Hopf bifurcation proposed by Wilhelm and Heinrich in 1995. The system involves three differential equations and a single bilinear term. We specifically select parameters that are suitable for the biological scenario of biofilm oscillations. We perform computer simulations and a detailed analysis of the system including bifurcation analysis and quasi-steady-state approximation. We also discuss the feedback structure of the system and the correspondence of the simulations to biological observations. Our theoretical work suggests potential scenarios about the oscillatory behaviour of biofilms and also serves as an application of a previously described chemical oscillator to a biological system.