lecture 5/6- Molecular Mechanisms of Epithelial Ion and Fluid Transport Flashcards
movement of sodium outside to inside
entry through sodium channels down an electrochemical gradient (facilitated passive diffusion)
sodium removed by Na/K ATPase which requires ATP
sodium is moved from luminal side into the blood
movement of chloride from outside to inside
chloride move between the cells (paracellular diffusion) through tight junctions
movement of cl maintains electroneutrality
now we have sodium chloride moved across
water follow the NaCl by
osmosis through aquaporins or tight junctions
NKCC1 transports on basolateral membrane
1 sodium 1 potassium and 2 chloride into the cell
secondary active transporter as it uses the gradient set up by
Na/K ATPase
on apical membrane the Cl channels we have are
CFTR and calcium activated Cl- channel (CaCC)
In CF, CFTR is defective, so salt and fluid secretion is inhibited
R domain is the part of CFTR that is phosphorylated by
protein kinase A and this phosphorylation causes the channel to open
CFTR activity is regulated by
PKA and ATP
phosphorylation induces ATP binding of the
NBDs (nucleotide binding domains)
conformational change in NBDs transmitted to
membrane spanning domains causing the pore to open
ATP is hydrolysed and the pore closes
dephosphorylation of the R domain by protein phosphatases closes the channel even in the presence of ATP
patch clamp technique allows
you to make electrical measurements of ions moving through ion channels
shows that ATP alone has no response
calcium activated chloride channels (CaCC) are activated by
a rise in calcium. calcium binds to CaCC and you get chloride release
examples of CaCCs are
TMEM16A and B
TMEM16A
10 transmembrane domains
calcium ions bind to glutamate residues in one of the alpha helices of intracellular loop 3
alpha helices move apart opening the pore enabling chloride transport
