Transport Flashcards
basic principles of membrane transport
- solute electrochemical potential
- solute electrochemical potential gradient
- active transport
- passive transport
electrochemical potential of a solute
- partial molar free energy of the solute
- potential to do work when a difference in potential exists across a membrane
- function of solute activity, charge, and valence and the electrical potential difference across the membrane (voltage)
difference in electrochemical potential
- reflects magnitude of the difference in transmembrane solute concentration and the difference in trans membrane voltage factored by the charge and valence of the solute
- gradient
thermodynamic equilibrium in absence of gradient and DF
-passive transport mediates unidirectional transport in the forward and reverse direction resulting in no net transport
thermodynamic equilibrium for anions and cations
- occurs when chemical and electrical DF are equal and opposite
- net movement is zero
- unidirectional solute transport equal and opposite still-no net movement
thermodynamic equilibrium for non-electrolytes
- occurs when chemical gradients are equal and opposite
- voltage difference is not a DF like it is for cations and anions
- unidirectional solute transport equal and opposite still-no net movement
non-equilibrium steady state
- equilibrium does not equal steady state
- solute in electrochemical disequilibrium but unidirectional solute transport is equivalent
- intra or extra cellular solute electrochemical potential is constant against the opposite site of the membrane (Na kept high outside, but rate of influx and efflux are equal, still inward Na gradient)
3D concept of gradient
- difference
- direction
- DF
thermodynamic classification of membrane transport
- passive transport
- primary active transport-hydrolysis of ATPase
- secondary active transport- coupled to another transfer of ions and uses that energy- indirectly dependent on ATP hydrolysis, use one gradient energy to make another gradient
molecular mechanisms
A. Ion translocating pump (primary active)
B. Channel (passive) (can also be facilitated diffusion)
C. Carrier
-1. uniporter (passive)- faciliated diffusion
-2. symporter, cotransporter (secondary active
-3. antiporter, countertransporter, exchanger (secondary active)-first solute down gradient, second up
examples of sym and antiport
- ATPase drives Na out to begin with, then influx of Na back in allows for use of the energy
- sym means Na comes back in with it
- anti means Na comes back in and other molecule goes out
non mediated transport
- simple diffusion
- passive
- no protein
channel mediated vs uniporter
- both considered facilitated diffusion
- channel can be gated by something- voltage, ligand can shut
primary active transport
- ion translocating ATPases, use energy of ATP hydrolysis
- Na/K
- Na out serves as gradient for cotransporters because it wants to come back in
- K in makes membrane neg potential (when coupled with Na gradient makes bigger DF for organic and inorganic solutes to go inside)
- 3 Na out, 2 K in
- net pos out
- steady state of Na because it leaks back and K leaks out
functional properties of membrane transporters
- have Km and Vmax (Jmax)
- measures of saturability
- substrate selectivity/specificity
- competitive/ non competitive transport inhibition- does increasing substrate help? if yes- competitive
- stoichiometry
- electrogenicity