1.3 Membrane Proteins

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Regions of hydrophobic R groups allow strong hydrophobic interactions that hold integral membrane proteins within the phospholipid bilayer
Integral membrane proteins interact extensively with the hydrophobic region of membrane phospholipids.
Some integral membrane proteins are transmembrane proteins
Peripheral membrane proteins have hydrophilic R groups on their surface and are bound to the surface of membranes, mainly by ionic and hydrogen bond interactions
Many peripheral membrane proteins interact with the surfaces of integral membrane proteins
The phospholipid bilayer is a barrier to ions and most uncharged polar molecules
Some small molecules, such as oxygen and carbon dioxide, pass through the bilayer by simple diffusion
Facilitated diffusion is the passive transport of substances across the membrane through specific transmembrane proteins
To perform specialised functions, different cell types have different channel and transporter proteins
Most channel proteins in animal and plant cells are highly selective.
Channels are multi-subunit proteins with the subunits arranged to form water-filled pores that extend across the membrane.
Ligand-gated channels are controlled by the binding of signal molecules, and voltage-gated channels are controlled by changes in ion concentration
Transporter proteins bind to the specific substance to be transported and undergo a conformational change to transfer the solute across the membrane.
Transporters alternate between two conformations so that the binding site for a solute is sequentially exposed on one side of the bilayer, then the other.
Active transport uses pump proteins that transfer substances across the membrane against their concentration gradient.
Pumps that mediate active transport are transporter proteins coupled to an energy source.
Some active transport proteins hydrolyse ATP directly to provide the energy for the conformational change required to move substances across the membrane
ATPases hydrolyse ATP.
For a solute carrying a net charge, the concentration gradient and the electrical potential difference combine to form the electrochemical gradient that determines the transport of the solute
A membrane potential (an electrical potential difference) is created when there is a difference in electrical charge on the two sides of the membrane.
Ion pumps, such as the sodium-potassium pump, use energy from the hydrolysis of ATP to establish and maintain ion gradients
The sodium-potassium pump transports ions against a steep concentration gradient using energy directly from ATP hydrolysis It actively transports sodium ions out of the cell and potassium ions into the cell
The pump has high affinity for sodium ions inside the cell. Binding occurs. Phosphorylation by ATP, conformation changes, affinity for sodium ions decreases, sodium ions released outside of the cell. Potassium ions bind outside the cell. dephosphorylation, conformation changes, potassium ions taken into cell, affinity returns to start
(sp pump) For each ATP hydrolysed, three sodium ions are transported out of the cell and two potassium ions are transported into the cell. This establishes both concentration gradients and an electrical gradient.
The sodium-potassium pump is found in most animal cells, accounting for a high proportion of the basal metabolic rate in many organisms
In the small intestine, the sodium gradient created by the sodium-potassium pump drives the active transport of glucose
The glucose transporter responsible for this glucose symport transports sodium ions and glucose at the same time and in the same direction
Sodium ions enter the cell down their concentration gradient; the simultaneous transport of glucose pumps glucose into the cell against its concentration gradient.