MOVEMENT ACROSS MEMBRANES
Transcription
MOVEMENT ACROSS MEMBRANES
MOVEMENT ACROSS MEMBRANES Role of plasma membrane • Maintains the cell’s internal environment by: – Keeping some substances in and other substances out – Allowing the controlled passage of specific substances from one side of the cell membrane to the other – Receiving signals – Assisting with cell to cell communication. Movement across membranes • The plasma membrane regulates the movement of molecules into and out of the cell. • This movement depends on the composition of the membrane and the surface area available for exchange. Composition of the membrane • One of the most important properties of membranes in their lipid nature. • This makes them impermeable to: – most water-soluble molecules – ions – polar molecules • These substances require specific channels (made from protein molecules) to pass through the plasma membrane . The plasma membrane is differentially permeable • This means that some substances can pass through the plasma membrane but others cannot. • We say that the membrane is it is differentially permeable or selectively permeable or semipermeable. Moving across membranes • In general, substances pass in and out of cells by the following processes: – Simple diffusion – Osmosis – Facilitated diffusion – Active transport – Endocytosis and exocytosis Simple Diffusion • Defined as the movement of particles (molecules or ions) from a region where they are at a relatively high concentration to a region where they are at a lower concentration. • The difference in concentration between the two regions is called the concentration gradient or diffusion gradient. • Diffusion always takes place wherever such a gradient exists and continues until the particles are uniformly distributed throughout the system. • When that happens, equilibrium is said to be reached. • Diffusion is passive process. It does not require additional energy and it takes place equally readily in non-living and living systems Factors influencing rate of simple diffusion • In general, the diffusion rate is higher when: – – – – the concentration gradient is greater when heat is applied when molecules are smaller when movement occurs through a gaseous medium. • Chemical properties also influence the rate of simple diffusion. – The hydrophobic nature of the interior of a plasma membrane means only small relatively non polar molecules such as O2 and CO2 can quickly permeate the membrane by simple diffusion. – H2O is a polar molecule but gets away with simple diffusion because of its very small size, however, water molecules diffuse at 10,000 times slower than they would without a membrane being present. – Ethanol and glycerol are much larger than water but can still use simple diffusion to cross the lipid bilayer at reasonable rates because they are non-polar. Osmosis • Special type of simple diffusion. • Requires no input of energy. • Osmosis is defined as the net movement of a solvent, usually water, across a differentially permeable membrane from a weak or dilute solution (high water concentration, low solute concentration) to a strong solution (low water concentration, high solute concentration). • More simply, osmosis is the net movement of free water molecules from a dilute solution through a partially permeable membrane to a concentrated solution. Osmosis • The differentially permeable membrane allows the small water molecules to move through but not the larger sucrose molecules. • Because there are more free water molecules in the less concentrated solution, there will be a net movement of water from the dilute to the concentrated solution. • This is osmosis – the diffusion of water along its own concentration gradient. Osmosis and cells • The plasma membrane of a cell is differentially permeable to water, and therefore, the amount of water in the external environment will affect the concentration of the solution within the cell. • The external environment may be isotonic, hypertonic or hypotonic compared to the cellular environment. – Isotonic solutions • Solute concentration the same as intracellular fluid. – Hypertonic solutions • Solute concentration higher than intracellular fluid, therefore lower osmotic pressure. – Hypotonic solutions • Solute concentration lower than intracellular fluid, therefore higher osmotic pressure. Osmosis and cells Facilitated Diffusion • Charged particles (ions) and relatively large molecules, such as glucose, do not readily pass through the plasma membrane because of their size or polar nature. • In the plasma membrane certain proteins assist such particles to diffuse in or out of the cell. • This process is called facilitated diffusion. • Transport protein molecules span the membrane from one side to the other. • There are two types of transport proteins: – channel proteins – carrier proteins. Channel Proteins • Channel proteins are particularly involved with transporting ions in and out of cells. • They form a water-filled pore in the membrane. • The lining of the channel is hydrophilic and so water-soluble substances such as ions pass through it relatively easily. • The channels are selective, allowing certain ions to pass through but not others. • Channel proteins speed up the rate at which ions diffuse across the plasma membrane. • Movement is passive and doesn’t involve the transfer of energy. • Can can only take place down a concentration gradient (from high to low concentration). More about channel proteins • Some of the channels can open and close rather like gates. • These gated channels open only when they receive an appropriate signal. • The signal may be: – mechanical disturbance of the membrane – a change in the voltage across the membrane – binding of another molecule or ion with the protein. Carrier Proteins • Combine with the diffusing molecule or ion, which is then carried across the membrane and deposited on the other side. • This requires changes in the conformation of the protein. • Carrier proteins bind their solutes in such a way as to shield the polar or charged groups from the non polar interior of the membrane. • Relationship between the carrier protein and the transported molecule is specific. Active Transport • Involves movement of molecules or ions against a concentration gradient, from a region of low concentration to a region of higher concentration. • Only takes place with an input of energy, generally derived from the ATP molecules. • Allows cells to take up nutrients even when their concentration outside the cell is very low. • Allows cells to get rid of unwanted substances even when their concentration is much greater outside the cell. • Cells that are actively pumping in substances against the concentration gradient are found to contain many mitochondria. Endocytosis and exocytosis • In addition to solutes transported by diffusion and active transport, the cell also has to transport very large molecules and aggregates of macromolecules across the cell membrane. • Substances such as these enter the cell by endocytosis or leave the cell by exocytosis. • Both these processes require energy. Endocytosis • Unique to eukaryotic cells. • Three forms of endocytosis – names are different but process is essentially the same – Pinocytosis • uptake of fluid and particles < 0.5mm. – Phagocytosis • uptake of large particles and debris > 0.5mm. – Receptor mediated endocytosis • requires specific binding of protein or other ligand to a specific receptor on the surface of the plasma membrane in order to stimulate endocytosis of bound ligand Endocytosis General description of endocytosis • Endocytic vesicles are formed by the plasma membrane ballooning in to form a pocket that contains the material from the exterior of the cell. • The pocket begins to pinch off enclosing the extracellular material and a vesicle is formed. • The vesicle containing extracellular material separates from the cell membrane and moves into the cytoplasm of the cell. • These vesicles may then fuse with other vesicles called endosomes. • Endosomes may mature into lysosomes or fuse with existing lysosomes. Exocytosis • Is the process in which substances produced by the cell are carried in vesicles and released to the exterior of the cell. • Vesicles that store cellular products for export from the cell are called secretory vesicles. • The secretory vesicle moves to the plasma membrane, fuses with the plasma membrane and the contents of the vesicle are discharged to the outside of the cell. • Important substances such as hormones, digestive enzymes and even toxins are secreted from cells in this way. • Exocytosis may be constitutive or regulated (i.e. triggered by a specific signal). • For example exocytosis in neuronal chemical synapses is triggered by Ca2+. Exocytosis