Cytoplasmic convection currents and intracellular temperature gradients

Intracellular thermometry has recently demonstrated temperatures in the nucleus, mitochondria, and centrosome to be significantly higher than those of the cytoplasm and cell membrane. This local thermogenesis and the resulting temperature gradient could facilitate the development of persistent, self...

Full description

Saved in:
Bibliographic Details
Published in:PLoS computational biology 2019-11, Vol.15 (11), p.e1007372-e1007372
Main Authors: Howard, Rachel, Scheiner, Aaron, Cunningham, Jessica, Gatenby, Robert
Format: Article
Language:English
Subjects:
Biology and Life Sciences
Cancer
Cell cycle
Cell membranes
Computer applications
Computer Simulation
Convection
Convection currents
Cytoplasm
Cytoplasm - metabolism
Cytoplasm - physiology
Cytoskeleton
Cytoskeleton - physiology
Cytosol - metabolism
Diffusion
Diffusion effects
Eukaryotes
Flow (Dynamics)
Gene expression
Heat
Hydrodynamics
Intracellular
Intracellular Fluid - metabolism
Localization
Methods
Mitochondria
Models, Theoretical
Oncology
Physical Sciences
Proteins
Signal transduction
Spatial discrimination
Temperature
Temperature gradients
Temperature measurement
Thermogenesis
Velocity
Viscosity
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Intracellular thermometry has recently demonstrated temperatures in the nucleus, mitochondria, and centrosome to be significantly higher than those of the cytoplasm and cell membrane. This local thermogenesis and the resulting temperature gradient could facilitate the development of persistent, self-organizing convection currents in the cytoplasm of large eukaryotes. Using 3-dimensional computational simulations of intracellular fluid motion, we quantify the convective velocities that could result from the temperature differences observed experimentally. Based on these velocities, we identify the conditions necessary for this temperature-driven bulk flow to dominate over random thermal diffusive motion at the scale of a single eukaryotic cell. With temperature gradients of the order 1°C and diffusion coefficients comparable to those described in the literature, Péclet numbers ≥ 1 are feasible and permit comparable or greater effects of convection than diffusion in determining intracellular mass flux. In addition to the temperature gradient, the resulting flow patterns would also depend on the spatial localization of the heat source, the shape of the cell membrane, and the complex intracellular structure including the cytoskeleton. While this intracellular convection would be highly context-dependent, in certain settings, convective motion could provide a previously unrecognized mechanism for directed, bulk transport within eukaryotic cells.
ISSN:1553-7358
1553-734X
1553-7358
DOI:10.1371/journal.pcbi.1007372