Membrane Transport (DP IB Biology)
Revision Note
Simple Diffusion
Simple diffusion is a type of membrane transport that involves particles passing directly between the phospholipids in the plasma membrane
It can be defined as:
The net movement, as a result of the random motion of molecules or ions, of a substance from a region of higher concentration to a region of lower concentration
The random movement is caused by the kinetic energy of the molecules or ions
The molecules or ions are said to move down a concentration gradient
If diffusion takes place for a long enough time period, molecules eventually reach equilibrium, where they are evenly distributed on either side of a membrane
Examples of molecules that move by simple diffusion include
Oxygen
Oxygen diffuses into cells from the surrounding capillaries
Respiration uses up oxygen, resulting in a low concentration inside cells and so generating a concentration gradient
Carbon dioxide
Carbon dioxide diffuses out of cells and into the surrounding capillaries
Respiration produces carbon dioxide as a product, resulting in a high concentration inside cells and so generating a concentration gradient
Simple diffusion diagram
Simple diffusion involves the movement of molecules directly between the phospholipids of a cell membrane
The rate at which a substance diffuses across a membrane depends on several factors:
'Steepness' of the concentration gradient
The greater the difference in concentration across a membrane, the higher the rate of diffusion
Temperature
The higher the temperature the higher the rate of diffusion
The molecules have more kinetic energy at high temperatures, so random movement of molecules is faster
Surface area
The greater the surface area the higher the rate of diffusion
Properties of the molecules or ions
Large molecules diffuse more slowly as they require more energy to move
Uncharged molecules, e.g. oxygen, diffuse faster as they move directly across the phospholipid bilayer
Non-polar molecules diffuse more quickly as they are soluble in the non-polar phospholipid bilayer
Although polar molecules cannot easily pass through the hydrophobic part of the membrane, smaller polar molecules (e.g. urea) can diffuse at low rates
Osmosis
Osmosis can be defined as:
The diffusion of water molecules, from a dilute solution to a solution with a higher solute concentration, across a partially permeable membrane
In doing this, water is moving down its concentration gradient, and so osmosis can be said to be a type of diffusion
A dilute solution has a high concentration of water molecules and a concentrated solution has a low concentration of water molecules
As with facilitated diffusion, osmosis occurs as the result of the random movement of molecules, so is technically the net movement of water
While water can move directly in between the phospholipids, channel proteins called aquaporins allow water to pass through membranes more freely
Water is unusual for a polar molecule in its ability to pass directly across cell membranes
Movement of water molecules diagram
Water molecules can cross partially permeable membranes
Osmosis can also be described as the net movement of water molecules from a region of higher water potential to a region of lower water potential, through a partially permeable membrane
Water potential describes the tendency of water to move; this term is used to avoid confusion between water concentration and solute concentration of a solution
Osmosis diagram
Osmosis is the movement of water molecules from a dilute to a concentrated solution across a partially permeable membrane
Facilitated Diffusion
Some substances cannot diffuse through the phospholipid bilayer of cell membranes, e.g.:
Large molecules
Polar molecules
Ions
These substances can only cross the phospholipid bilayer with the help of transport proteins
This form of diffusion is known as facilitated diffusion
There are two types of proteins that enable facilitated diffusion:
Channel proteins
Carrier proteins
Transport proteins are highly specific, meaning that they only allow one type of molecule or ion to pass through
During facilitated diffusion the net diffusion of molecules or ions into or out of a cell will occur down a concentration gradient
Facilitated diffusion is a passive form of transport; it does not require energy
The direction of movement of molecules through a transport protein depends on their relative concentration on each side of the membrane
Channel proteins
Channel proteins are pores that allow the passage of specific substances across a membrane
They allow charged substances (eg. ions) to diffuse through the cell membrane
Some channel proteins are gated, meaning that part of the channel protein on the inside surface of the membrane can move in order to close or open the pore
This allows the channel protein to control the exchange of ions
Channel protein diagram
Channel proteins are membrane pores; some channel proteins can open and close
Carrier proteins
Unlike channel proteins, which have a fixed shape, carrier proteins can switch between two shapes
The substance to be transported attaches to a binding site, causing a shape change in the carrier protein
Initially the binding site of the carrier protein is open to one side of the membrane
When the carrier protein switches shape it opens to the other side of the membrane
Carrier protein diagram
Carrier proteins change shape to carry substances across cell membranes
Examiner Tips and Tricks
Remember that the movement of molecules from high concentration to low concentration is diffusion; this movement is passive and requires no energy
If this movement requires the aid of a protein then it is facilitated diffusion
If it involves the movement of water across a partially permeable membrane it is osmosis.
Active Transport
Active transport can be defined as:
The movement of molecules and ions across a cell membrane, from a region of lower concentration to a region of higher concentration, using energy from respiration
Active transport occurs against, or up, a concentration gradient
Active transport requires carrier proteins
Carrier proteins in active transport are sometimes known as pumps
Although facilitated diffusion also uses carrier proteins, active transport is different as it requires energy
Energy is required to allow the carrier protein to change shape, allowing it to transfer the molecules or ions across the cell membrane
The energy required is provided by ATP (adenosine triphosphate), produced during respiration.
The ATP is hydrolysed to release energy
Active transport diagram
Active transport is the transport of substances across cell membranes from low to high concentration
Selective Permeability
Facilitated diffusion and active transport are mechanisms that allow cell membranes to be selectively permeable
Selective permeability is the ability of the membrane to differentiate between different types of molecules, only allowing some molecules through while blocking others
Simple diffusion provides less control for cell membranes, as it is dependent only on the size and hydrophobic or hydrophilic nature of the molecules diffusing
Simple diffusion provides no ability for membranes to be selective with regard to small, polar molecules
Small, non-polar molecules can diffuse across the membrane with ease so this is not selective
Simple diffusion does allow for selective permeability with regard to large or polar molecules
Large or polar molecules cannot cross the phospholipid bilayer without transport proteins
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