Mechanical morphotype switching as an adaptive response in mycobacteria
Invading microbes face a myriad of cidal mechanisms of phagocytes that inflict physical damage to microbial structures. How intracellular bacterial pathogens adapt to these stresses is not fully understood. Here, we report the discovery of a virulence mechanism by which changes to the mechanical stiffness of the mycobacterial cell surface confer refraction to killing during infection. Long-term time-lapse atomic force microscopy was used to reveal a process of "mechanical morphotype switching" in mycobacteria exposed to host intracellular stress. A "soft" mechanical morphotype switch enhances tolerance to intracellular macrophage stress, including cathelicidin. Both pharmacologic treatment, with bedaquiline, and a genetic mutant lacking uvrA modified the basal mechanical state of mycobacteria into a soft mechanical morphotype, enhancing survival in macrophages. Our study proposes microbial cell mechanical adaptation as a critical axis for surviving host-mediated stressors.
WOS:001135659900010
2024-01-05
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Funder | Grant Number |
NIH TB RAMP | R25Ai47375 |
EMBO LTF, altF fellowships (AltF) | 191- 2014 |
B.J. laboratory | |
Cystic Fibrosis Pilot | |
Feasibility Award at UCSF | 002510i221 |
UCSF TB RAP Mentored Scientist award | R25Ai47375 |
Office of Science, Office of Basic Energy Sciences, of the US department of Energy | DE-Ac02- 05ch11231 |
European Union | 665667 |
Swiss national Science Foundation | FP7/2007- 2013/ERC |
Cystic Fibrosis Foundation | 310030B_176397 |
NIH/National institute of Allergy and infectious diseases grant | 207717 |
Incell | |
Vertex Research innovation Award | |
Wellcome trust | 207487/c/17/Z |
ERC- 2017- coG | |
773091 | |