Transporters & Ion Channels 1 Flashcards
Lipid Membrane Permeability for polar molecules
Impermeable to most polar molecules
- Requires transporters (many drugs have similar structure to nutrients so still use transporters - e.g. Bestatin using peptide transporters)
- Some drugs diffuse using their hydrophobicity
Thermodynamics of transport
diffusion vs active transport
Diffusion
- No ATP hydrolysis or co-transport
- Relies on concentration difference, transmembrane potential, osmotic pressure
Active Transport
- ATP driven against normal diffusion direction
3 main Transmembrane transporters
1) Channels (ion channels, aquaporins, pores)
2) Transporters (Uni, sym or anti- porters)
3) ATP-powered pumps
Exceptions to the classification of 3 transporters
1) Cystic Fibrosis Transmembrane conductance Regulator (CFTR)
- ion channel belonging the the ABC transporter family of ATP-powered pumps
2) Chloride Channles (ClC)
- Often uniporters, other times antiporters (engaging protons)
- A uniporter transporting ions = ion channel?!
4 mechanisms of Transmembrane Transport
1) Simple Diffusion
- Diffuse across membrane/pores
- e.g. O2, steroid hormones, lipophilic drugs
2) Facilitated Diffusion
- Diffusion via a specific protein
- e.g. Glucose and amino acids through uniporters
3) Active Transport (primary)
- Solute transported against gradient using ATP hydrolysis
- Requires specific protein, no co-transport
- E.g. ions and small hydrophilic molecules
4) Co-transport (secondary active transport)
- Driven by movement of a co-transported ion downs its gradient, not coupled to ATP hydrolysis
- e.g. sucrose through antiporters
Beta barrel proteins
- Beta barrel pores
- Beta barrel transmembrane (TM) proteins
- Adhesion molecules (e.g. OmpX)
Transmembrane Beta-barrel structure
- 8-22 Beta-strands per monomer/barrel
- Hydrophobic external residues, hydrophilic internal residues
OmpF Beta-barrel pores
Dominate outer membrane porins in E.coli
- Passive diffusion channels normally found in trimer form
- Offer rapid, low-selectivity diffusion
- Ionic environment determines pore size
Low-level specificity Beta Barrel pores
PhoE transports phosphate
- Very similar structure to OmpF but with a change in the constricting loop
- Has 2 extra positively charged amino acids, somewhat increasing its specificity for negatively charged molecules
Medium-level specificity Beta Barrel pores
LamB transports maltose and maltodextrins
- 3 loops with 6 aromatic residues are somewhat hydrophobic
- Allows for ‘guided diffusion’
Fully-specific beta Barrel pores
FepA & FhuA uptake Siderophores (small iron-binding molecules)
- Very specific active uptake due to ‘plug domain’ coupled to TomB
Gap Junctions/Connexins (pores) structure
Monomers = 4 TM alpha helices
Typically 6 monomers per bilayer spanning domain (2 hexamers connect)
Gap Junction function and control
Found spanning 2 membranes in muticellular organisms
- used for communication as well as flow of nutrients and ions
Opening/closing controlled by phosphorylation
- pore size regulated by different connexin mixtures
Pore diffusion kinetics
A (out) <=====> A (in)
Facilitated diffusion: GLUT1 transporter
Transports glucose into RBC and across BBB
- mutation can cause De Vivo disease
- Uniporters belonging to the Major Facilitator Superfamily (MFS), the largest uniport/cotransporter family (typically 12 TM alpha helices)
