Forces acting across membranes 1 Flashcards
1.1/1.2
Describe the basic structure of membranes.
Membranes are very thin double layers of sheets of lipids. (the lipid bilayer). The structure of membranes is sometimes referred to as the ‘fluid mosaic model’.
They are fluid in that they are flexible. This is due to fatty acids that can stretch.
They are mosaic in that they are composed of lots of different parts.
They are embedded with proteins.
Describe the function of the cell membrane.
The cell membrane is a selective barrier, with varying permeability.
It is dynamic as it constantly remodelling itself to suit the cells needs.
The cell membrane allows the passive transport of water and some other molecules however the passage of ions and other uncharged polar molecules require other mechanisms when crossing the cell membrane.
Define electrochemical gradients.
The electrochemical gradient is the result of the net effect of the concentration and electrical gradients of a cell membrane. Created by the differences in concentration and charge on both sides of the membrane.
** the electrochemical gradient drives the passive movement of substances into or out of the cell.
Give a brief description of both kinds of membrane proteins and their functions.
Integral proteins span the hydrophobic core of the lipid bilayer.
Peripheral proteins are associated with only the phosphate head of the lipid bilayer.
Describe receptor membrane proteins.
Receptor proteins are integral. They allow the communication of an extracellular signal from extracellular signalling molecules for example, neurotransmitters or hormones. This signal is received by the receptor and it initiates a response within the cell.
Describe transporter (carrier mediated transport proteins) membrane proteins.
The transporter proteins are never fully open and must change conformation to open either to the extracellular or intracellular region of the cell.
Describe channel membrane proteins.
Channel proteins create a water-filled pore, some are always open when some are gated.
Either voltage or ligand-gated.
Voltage-gated channel proteins open due to a change in electrochemical gradient.
Ligand-gated channel proteins open due to the binding of a ligand.
Describe the enzyme membrane proteins.
Membrane enzymes catalyse chemical reactions on the cell membrane.
The enzymatic part may be on the external side e.g. those found in small intestine which break down nutrients into smaller parts, or on the internal side such as those associated with converting signals from a receptor into an intracellular response.
Describe how structural membrane proteins maintain cell structure.
These structural proteins anchor the cell membrane to the intracellular cytoskeleton, to the extracellular matrix and/or to other cells. If there is any disfunction or loss of these cells this would lead to serious debility.
Describe how membrane proteins are involved in communication.
This can be communication between or within cells.
An example could be glycoproteins*, which act as markers that tell the immune system whether a cell is our own or foreign.
Other types of these proteins are involved with communicating extracellular messages to the intracellular environment. e.g. receptor/enzyme proteins or G-proteins.
Describe G-proteins.
G-proteins are peripheral proteins that relay a signal across the cell membrane from an integral receptor protein to an integral enzyme protein.
Describe 3 different types of membrane and the importance of their protein content.
Myelin is a specialised type of membrane that serves as an insulator around myelinated nerve fibres. Myelin has a low protein content and its main component is lipid.
Plasma membranes have a 50% protein content and have a much greater activity than the above.
The membrane of mitochondria are composed of 75% protein and are very active.
*** the more function requires of the membrane the more protein in it.
What is meant by ‘endo/exocytosis’.
Movement of macromolecules across membranes without disruption.
Describe the process of endocytosis.
Endocytosis involves invagination of the cell membrane to form a vesicle.
The vesicle then disintegrates on the cytoplasmic surface of the membrane.
The contents of the vesicle are then released.
The contents then migrate within the cell to their destination.
**this is a common mechanism for terminating signals from extracellular ligands.
Describe the process of endocytosis.
This is the reverse process of exocytosis.
Where molecules are assembled within the cell and packaged into vesicles that then fuse with the cell membrane, releasing them out of the cell.
Many proteins manufactured in the cell are released from cells by exocytosis.
