Signal Transmission (Electrophysiology) Flashcards
Nernst equation
Relates the effective concentrations of cell reaction components to the standard potential
Equilibrium potential/concentrations of ions
K+: Outside 5 mM, inside 100 (1:20) → -80mV
Na+: Outside 150 mM, inside 15 (10:1) → 62mV
Ca2+: Outside 2mM, inside 0.0002 (10.000:1) → 123 mV
Cl-: Outside 150 mM, inside 13 (11.5:1) → -65 mV
Goldmann-Hodgkin-Katz equation
Calculate the membrane potential → Put together the Nernst equation of all the involved ions
Conductance
Sum of all ions passing the neuron at a specific time
Na+/K+ ATPase
ATP dependent transport of 3 Na+ outside & 2 K+ inside
Binding of ATP + 3 Na+ → ATP hydrolization → Phosphorylation at aspartate → Release ADP → Conformational change → Na+ released ec → Binding of 2 K+ → >Induction of dephosphorylation → K+ ic released
Na+/K+-ATPase involvment in diseases
Alpha1: Omnipresent → Involved in hypertension
Alpha2: Muscle & brain → Easier depolarization in FHM
Alpha3: Brain → Involved in AHC, ROP & CAPOS
Ca2+-ATPase
Ca2+ transport independend of other ions
3 types: SERCA, SPCA & AMCA
Ca2+ binding → Mg-ATP binding & bend in TM region → ATP cleavage → Increased Bend → Release of Ca2+ & binding of two protons → Unstable → Bend back, release of proton & Mg
Cl- Transport
NKCC1: Neonatal, Na+ dependent (1Na+ : 1K+ : 2 Cl-) → Lots of Cl- inside = Inhibitory
KCC2: Cl- pumped to the outside (1K+ : 1 Cl- = Na+ independent)
Patch-Clamp
Study ionic currents → Micropipette with electrolyte solution
Cell-attached: Pipette sealed on membrane → Record currents of a few contained ion channels
Whole cell recording: Rupture cell membrane → Means to administer & study drugs
Inside-out-patch: Vescile formation → Single channel analysis
Outside-out-patch: Bulb of membrane blebs out of cell → Single channel analysis
Action Potential
= Short-lasting marked change in the membrane potential → Generated at the axon hillock
Summation of the Action Potential
Temporal summation: Duration of the postsynaptic potential longer than interval between APs → Repeated inputs
Spatial summation: Simultaneous inputs from multiple presynaptic cells
Translation of the Action Potential
Stimulus → Transduction → Receptor potential → Transformation → AP
Ion channels necessary to translate & transmit the AP
Stages of the Action Potential
Initiation: Voltage increase (From -70mV to -50 mV)
Spread: Threshold potential exceeded → Depolarization → Opening of NaV → Na+ influx
Repolarization: At around 62 mV, NaV close, KV open → Efflux of K+ → Back to resting potential
Hyperpolarization: KV close slowly → Membrane potential below resting potential
Propagation of the Action Potential
Nodes of Ranvier: Spaces between myelin on axon with a high concentration of ion channels
Signal jumps from one node to another = Saltatory conduction
Structure of Voltage Gated Sodium Channels
Pore & voltage sensor from alpha subunit & auxillary beta-subunit
Alpha subunit: 24 transmembrane regions (4 domains)
Per domain: 6 Membrane spanning segments (S1-S6)
S5-S6: Pore S1-S4: Voltage sensor (S4 positively charged)
Linker between domain 3&4 for fast inactivation
