5.10: Facilitated Transport

The chemical and physical properties of plasma membranes cause them to be selectively permeable. Since plasma membranes have both hydrophobic and hydrophilic regions, substances need to be able to transverse both regions. The hydrophobic area of membranes repels substances such as charged ions. Therefore, such substances need special membrane proteins to cross a membrane successfully. In facilitated transport, also known as facilitated diffusion, molecules and ions travel across a membrane via two types of membrane transport proteins: channel proteins and carrier proteins. These membrane transport proteins enable diffusion without requiring additional energy.

Channel Proteins

Channel proteins form a hydrophilic pore through which charged molecules can pass through, thus avoiding the hydrophobic layer of the membrane. Channel proteins are specific for a given substance. For example, aquaporins are channel proteins that specifically facilitate the transport of water through the plasma membrane.

Channel proteins are either always open or gated by some mechanism to control flow. Gated channels remain closed until a particular ion or substance binds to the channel, or some other mechanism occurs. Gated channels are found in the membranes of cells such as muscle cells and nerve cells. Muscle contractions occur when the relative concentrations of ions on the interior and exterior sides of a membrane change due to the controlled closing or opening of channel gates. Without a regulated barrier, muscle contraction would not occur efficiently.

Carrier Proteins

Carrier proteins bind to a specific substance causing a conformational change in the protein. The conformational change enables movement down the substance’s concentration gradient. For this reason, the rate of transport is not dependent on the concentration gradient, but rather on the number of carrier proteins available. Although it is known that proteins change shape when their hydrogen bonds are destabilized, the complete mechanism by which carrier proteins change their conformation is not well understood.

Diffusion Rates

Even though more involved than simple diffusion, facilitated transport enables diffusion to occur at incredible rates. Channel proteins move tens of millions of molecules a second, and carrier proteins move a thousand to a million molecules a second.

Solutes like charged ions are repelled by the hydrophobic layer of the membrane, thereby halting diffusion. During the process of facilitated transport or facilitated diffusion, molecules can travel across the membrane via channels and carrier proteins that enable diffusion without requiring additional energy.

The first type, channel proteins, form a hydrophilic pore through which charged molecules can pass, thus avoiding the hydrophobic layer of the membrane. These channels are either always open or gated by some mechanism to control flow.

The second type, carriers, bind to a specific solute that changes the protein conformation, enabling the movement of solute down the gradient. For this reason, the rate of transport is not dependent on the concentration gradient, but rather on the number of carrier proteins available.

Even though it is more complex than simple diffusion, facilitated transport enables diffusion to occur at incredible rates, with channel proteins moving tens of millions of molecules a second and carrier proteins moving 1,000 to a million molecules a second.