Microfluidic-based transcriptomics reveal force-independent bacterial rheosensing.
Joseph E SanfilippoAlexander LorestaniMatthias D KochBenjamin P BrattonAlbert SiryapornHoward A StoneZemer GitaiPublished in: Nature microbiology (2019)
Multiple cell types sense fluid flow as an environmental cue. Flow can exert shear force (or stress) on cells, and the prevailing model is that biological flow sensing involves the measurement of shear force1,2. Here, we provide evidence for force-independent flow sensing in the bacterium Pseudomonas aeruginosa. A microfluidic-based transcriptomic approach enabled us to discover an operon of P. aeruginosa that is rapidly and robustly upregulated in response to flow. Using a single-cell reporter of this operon, which we name the flow-regulated operon (fro), we establish that P. aeruginosa dynamically tunes gene expression to flow intensity through a process we call rheosensing (as rheo- is Greek for flow). We further show that rheosensing occurs in multicellular biofilms, involves signalling through the alternative sigma factor FroR, and does not require known surface sensors. To directly test whether rheosensing measures force, we independently altered the two parameters that contribute to shear stress: shear rate and solution viscosity. Surprisingly, we discovered that rheosensing is sensitive to shear rate but not viscosity, indicating that rheosensing is a kinematic (force-independent) form of mechanosensing. Thus, our findings challenge the dominant belief that biological mechanosensing requires the measurement of forces.
Keyphrases
- single cell
- single molecule
- gene expression
- rna seq
- pseudomonas aeruginosa
- high throughput
- stem cells
- cystic fibrosis
- induced apoptosis
- staphylococcus aureus
- risk assessment
- drug resistant
- oxidative stress
- signaling pathway
- circulating tumor cells
- biofilm formation
- low cost
- human health
- acinetobacter baumannii
- endoplasmic reticulum stress
- solid state