exam 2: lecture 5 Flashcards
ion channel diffusion
allow ions( small charged molecules) to diffuse across the membrane
-there are electrochemical gradients across membranes
-gramicidin: channel
an antibiotic that is used to break down the ion gradients in bacteria and kill them (with hydrophilic interior & hydrophobic exterior)
(Na+, K+, Cl-)
permeable to everything: no selectivity
valinomycin: carrier
mechanism of action of a channel-forming ionophore
hydrophilic portion is made up of aa (spiral in shape)
needs 2 channels to transport ions across (homodimer)
-serves as a conduit for ions-> making membrane leaky + discharging ion gradients
what does gramicidin do to electric currents?
the antibiotic increases electric currents (ion flow across membrane)
what is an example of an ion channel?
CFTR
Cl- moves up duct to from sweat-> Na+ follows along the electrochemical gradient (making sweat less salty)
facilitated carrier diffusion 1
ion carriers-facilitate diffusion
1. valinomycin ( membrane protein) faces the outside of the cell with its binding site
2. an ion from outside binds
3. protein-ion complex diffuses across the membrane
4. ion is released into the interior of the cell
facilitated carrier diffusion type ii
Glut-1- glucose diffusion
1. glut-1 faces the outside with its binding site
2. glucose binds to glut-1 from outside
3. a conformational change occur (close one hole- open the other), transporting glucose to the interior
4. then, glucose is released
what is active transport? and the types of active transport?
Using energy to transport molecules AGAINST an electrochemical gradient
1. active transport protein carriers
2. endocytosis (phagocytosis) & pinocyotsis
What is cotransport? and what are the two types of cotransport?
*can be passive/ active depending on the molecules & pumps
involves the obligatory coupled transport of 2 different solutes with the help of a carrier protein
symport: both solutes move in the same direction
antiport: solutes in opposite directions
Na+/ Glucose symporter
PASSIVE + symport
initial state: pump is open to outside
1. a sodium ion is bound
- glucose is then bind to the pump due to Na+ stimulation->causing a conformational change
3.pump is open to inside
- Na+ is released inside (but is continuously forced outside by Na/K pump
- Loss of Na+ causes glucose to release to inside
- release of glucose stimulates return to initial state
Sodium/potassium pump
an example of active transport antiporter (ACTIVE + antiporter)
3 Na+ out/ 2 K+ in
initial state: pump open to inside
1. 3 Na+ are taken from inside
- ATP phosphorylates alpha subunits (atp-> adp+pi)
- A conformational change expels 3Na+ to outside
-pump open to outside, ready to start second half of cycle
- 2 K+ accepted from outside
- Dephosphorylation triggers another conformational change
- 2 K+ expelled to insides-> pukp return to initial state
How do direct & indirect active transport work
direct: active transport of protons from inside (low) to out (high) with ATP (ADP+Pi)
indirect: transport of solute molecules from outside (low) to outside (high)
endocytosis
food/water
*receptor-mediated: bind to proteins on the surface to bring inside
pinocytosis
water
phagocytosis
immune sys.
-phagocytes (macrophages)
