On Linear and Non-Linear Mechanics of Cyanobacterial Colonies

TL;DR

This study investigates the biomechanical properties of cyanobacterial colonies, revealing their high resistance to environmental stresses and how nutrient levels influence their structural strength.

Contribution

It introduces mechanical testing methods to analyze cyanobacterial colonies, linking biomechanical properties to environmental conditions like nutrient availability.

Findings

Cyanobacterial colonies have tensile strength comparable to bacterial biofilms.

Colonies are highly resistant to natural hydrodynamic stresses.

Low phosphorus levels lead to stronger, more resilient colonies.

Abstract

Toxic cyanobacterial blooms are a growing environmental concern that affects freshwater ecosystems, drinking water supplies, and public health. The cyanobacterium Microcystis is among the most important bloom forming species. It often grows in large colonies, which enhances its flotation, reduces grazing, and improves nutrient regulation. Microcystis cells are held together by a matrix of extracellular polymeric substances (EPS), making colony mechanics crucial for bloom formation. However, an analysis of the biomechanical properties of cyanobacterial colonies, and how these properties relate to environmental conditions like nutrient availability, remains largely missing. Here, we use micropipette force sensors to quantify the linear and non-linear mechanical properties of individual colonies at single-cell resolution. Bulk shear rheology complements these measurements by probing macroscopic properties. The measured tensile strength and yield stress are broadly comparable to those of bacterial biofilms and are far greater than the hydrodynamic stresses typically found in wind-mixed lakes. This implies that cyanobacterial colonies are highly resistant to fragmentation by natural mixing processes. We also show that low nutrient availability, particularly low phosphorus, produced stronger colonies, suggesting structural changes in the EPS. Overall, our results establish mechanical testing as a tool for a more complete and physically grounded understanding of cyanobacterial colony formation.