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RESEARCH PRODUCT
Biophysics of high density nanometer regions extracted from super-resolution single particle trajectories: application to voltage-gated calcium channels and phospholipids.
Martin HeineJennifer HeckDavid HolcmanDavid HolcmanPierre Paruttosubject
0301 basic medicineField (physics)1.1 Normal biological development and functioningHigh densityBoundary (topology)lcsh:Medicine32 Biomedical and Clinical SciencesLocal field potentialArticleQuantitative Biology::Cell BehaviorQuantitative Biology::Subcellular ProcessesComputational biophysics03 medical and health sciences0302 clinical medicineSingle-molecule biophysics1 Underpinning researchlcsh:SciencePhysicsMultidisciplinary3208 Medical PhysiologyVoltage-dependent calcium channelFOS: Clinical medicinelcsh:RNeurosciencesScientific data030104 developmental biologyParticleNanometrelcsh:QBiological systemBiological physics51 Physical Sciences030217 neurology & neurosurgeryEnergy (signal processing)description
AbstractThe cellular membrane is very heterogenous and enriched with high-density regions forming microdomains, as revealed by single particle tracking experiments. However the organization of these regions remain unexplained. We determine here the biophysical properties of these regions, when described as a basin of attraction. We develop two methods to recover the dynamics and local potential wells (field of force and boundary). The first method is based on the local density of points distribution of trajectories, which differs inside and outside the wells. The second method focuses on recovering the drift field that is convergent inside wells and uses the transient field to determine the boundary. Finally, we apply these two methods to the distribution of trajectories recorded from voltage gated calcium channels and phospholipid anchored GFP in the cell membrane of hippocampal neurons and obtain the size and energy of high-density regions with a nanometer precision.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2019-12-01 |