A conserved pressure-driven mechanism for regulating cytosolic osmolarity.
Katrina B VelleRikki M GarnerTatihana K BeckfordMakaela WeedaChunzi LiuAndrew S KennardMarc EdwardsLillian K Fritz-LaylinPublished in: bioRxiv : the preprint server for biology (2023)
Controlling intracellular osmolarity is essential to all cellular life. Cells that live in hypo-osmotic environments like freshwater must constantly battle water influx to avoid swelling until they burst. Many eukaryotic cells use contractile vacuoles to collect excess water from the cytosol and pump it out of the cell. Although contractile vacuoles are essential to many species, including important pathogens, the mechanisms that control their dynamics remain unclear. To identify basic principles governing contractile vacuole function, we here investigate the molecular mechanisms of two species with distinct vacuolar morphologies from different eukaryotic lineagesâ€"the discoban Naegleria gruberi , and the amoebozoan slime mold Dictyostelium discoideum . Using quantitative cell biology we find that, although these species respond differently to osmotic challenges, they both use actin for osmoregulation, as well as vacuolar-type proton pumps for filling contractile vacuoles. We also use analytical modeling to show that cytoplasmic pressure is sufficient to drive water out of contractile vacuoles in these species, similar to findings from the alveolate Paramecium multimicronucleatum . Because these three lineages diverged well over a billion years ago, we propose that this represents an ancient eukaryotic mechanism of osmoregulation.
Keyphrases
- skeletal muscle
- induced apoptosis
- smooth muscle
- cell cycle arrest
- cell therapy
- genetic diversity
- endoplasmic reticulum stress
- oxidative stress
- high resolution
- signaling pathway
- gram negative
- high frequency
- cell proliferation
- cell death
- multidrug resistant
- bone marrow
- mesenchymal stem cells
- reactive oxygen species
- antimicrobial resistance
- mass spectrometry
- pi k akt