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The '''cell membrane''' or '''plasma membrane''' is the outer surface of a [[cell (biology)|cell]] and encloses the contents of the cell.  The cell membrane is composed of a [[phospholipid bilayer]] studded with [[protein|proteins]].  The phosphlipid bilayer consists of two [[fatty acid]] chains that link to two of the three [[carbon|carbons]] of a molecule of [[glycerol]].  The third carbon is attached to a [[phosphate group]], which is in turn often attached to an [[alcohol]].  The alcohol makes the phosphate-alcohol group, or head group, [[hydrophilic]].  The fatty acid chains, or tails, are [[hydrophobic]].  This results in the hydrophilic parts pointing towards each other and the hydrophilic parts pointing to the extra and intracellular areas.  The fluid mosaic model of the plasma membrane holds that there are two types of proteins in the phospholipid bilayer.  The first is called an [[integral protein]].  These proteins are generally fixed and cannot be removed without rupturing the cell.  One type of integral protein called the [[transmembrane protein]] spans the membrane, so that its surface is both on the inside and outside of the cell.  A second type of membrane protein is called a [[peripheral protein]] and can easily be removed from the membrane.
The '''cell membrane''' or '''plasma membrane''' comprises the outer surface of a [[cell (biology)|cell]] — a boundary that encloses the contents of the cell.  The cell membrane is composed of a [[phospholipid bilayer]] studded with [[protein|proteins]].  The unit structure of the phospholipid bilayer consists of two [[fatty acid]] chains that link to two of the three [[carbon|carbons]] of a molecule of [[glycerol]].  The third carbon is attached to a [[phosphate group]], which is in turn often attached to an [[alcohol]] or [[amine]].  The alcohol makes the phosphate-alcohol group, or head group, [[hydrophilic]].  The fatty acid chains, or tails, are [[hydrophobic]].  This results in the hydrophilic parts pointing towards each other and the hydrophilic parts pointing to the extra and intracellular areas.  The unit structure repeats in a parallel array that creates a three-dimensional enclosed fluid-filled surface. The fluid mosaic model of the plasma membrane holds that there are two types of proteins in the phospholipid bilayer.  The first is called an [[integral protein]].  These proteins are generally fixed and cannot be removed without rupturing the cell.  One type of integral protein called the [[transmembrane protein]] spans the membrane, so that its surface is both on the inside and outside of the cell.  A second type of membrane protein is called a [[peripheral protein]] and can easily be removed from the membrane.
 
{{Image|Cell_membrane_-1.JPG|left|700px|Public domain, courtesy Mariana Ruiz. The cell membrane, also called the plasma membrane or plasmalemma, is a semipermeable lipid bilayer common to all living cells. It contains a variety of biological molecules, primarily proteins and lipids, which are involved in a vast array of cellular processes. It also serves as the attachment point for both the intracellular cytoskeleton and, if present, the cell wall.}} {{Image|Cell membrane -2.JPG|right|710px|"Cartoon of a typical cell membrane. Proteins are embedded in a matrix of phospholipid molecules. Several other membrane constituents such as glycolipids and cholesterol are also shown."}}<br>
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See also: [http://www.johnkyrk.com/cellmembrane.html Animated essentials of cell membrane structure.]<ref name=kyrk2008>Kyrk J. (2007) [http://www.johnkyrk.com/cellmembrane.html Animated essentials of cell membrane structure.]
*Numerous beautiful and informative animations of cell membrane structure, properties and functions.</ref><br>
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==Membrane Permeability==
==Membrane Permeability==
An essential feature of any plasma membrane is the ability to transport matertials in and out of the cell.
An essential feature of any plasma membrane is the ability to transport materials in and out of the cell.


===Passive Transport===
===Passive Transport===
Semi-permeable or selectively permeable membranes allow certain types of of substances through the membrane and not others.  Some forms of transport require no energy to perform- these mechanisms are called passive transport.  The most common forms of passive transport are [[diffusion]] and [[osmosis]].  '''Diffusion''' occurs when a certain substance, such as an [[ion]], is more concentrated on one side of the membrane.  If the membrane allows this ion through, then ions will move from the more concentrated side to the less concentrated side until reaching [[equilibrium]].
Semi-permeable or selectively permeable membranes allow certain types of substances through the membrane and not others.  Some forms of transport require no energy to perform- these mechanisms are called passive transport.  The most common forms of passive transport are [[diffusion]] and [[osmosis]].  '''Diffusion''' occurs when a certain substance, such as an [[ion]], is more concentrated on one side of the membrane.  If the membrane allows this ion through, then ions will move from the more concentrated side to the less concentrated side until reaching [[equilibrium]].


'''[[Osmosis]]''' is the diffusion specifically of water across a membrane.  A cell's [[tonicity]] indicates in which direction is the net flow of water and is based on the ionic content of the cell.  A cell which is [[isotonic]] has an ionic concentration identical inside the membrane and out.  Since the cell is at equilibrium, there is no [[concentration gradient]] and the flow of water in is equal to the flow of water out.  A cell which is [[hypertonic]] has a higher concentration inside the cell than out.  This causes a concentration gradient across the membrane which results in a net flow of water into the cell.  A cell which is [[hypotonic]] has a lower concentration and therefore water will flow out of the cell.  This tendency of a concentration gradient to cause a net flow of water is referred to as [[osmotic pressure]].
'''[[Osmosis]]''' is the diffusion specifically of water across a membrane.  A cell's [[tonicity]] indicates in which direction is the net flow of water and is based on the ionic content of the cell.  A cell which is [[isotonic]] has an ionic [[concentration]] identical inside the membrane and out.  Since the cell is at equilibrium, there is no [[concentration gradient]] and the flow of water in is equal to the flow of water out.  A cell which is [[hypertonic]] has a higher concentration inside the cell than out.  This causes a concentration gradient across the membrane which results in a net flow of water into the cell.  A cell which is [[hypotonic]] has a lower concentration and therefore water will flow out of the cell.  This tendency of a concentration gradient to cause a net flow of water is referred to as [[osmotic pressure]].


'''[[Facilitated diffusion]]''' is a passive form of transport whereby specific types of molecules are chemically encouraged to cross the membrane, but are not directional.  That is, molecules will only flow down a concentration gradient, which is definitionally passive transport.  This is accomplished by specialized proteins embedded in the surface called [[channels]] and [[carriers]].  Channels are gaps which allow the molecule to flow through them, and are sometimes gated (that is, are only open under certain conditions.) Carriers, or porters, chemically interact with the molecule to induce a [[conformational change]] which moves the molecule to the other side of the membrane.
'''[[Facilitated diffusion]]''' is a passive form of transport whereby specific types of molecules are chemically encouraged to cross the membrane, but are not directional.  That is, molecules will only flow down a concentration gradient, which is definitionally passive transport.  This is accomplished by specialized proteins embedded in the surface called [[channels]] and [[carriers]].  Channels are gaps which allow the molecule to flow through them, and are sometimes gated (that is, are only open under certain conditions.) Carriers, or porters, chemically interact with the molecule to induce a [[conformational change]] which moves the molecule to the other side of the membrane.


===Active Transport===
===Active Transport===


Active transport is the movement of molecules across the cell membrane which costs the cell energy through use of [[ATP]], adenosine triphosphate.  Typically this is because molecules must be moved up the concentration gradient to either remove or obtain the desired concentrations inside the cell.  One such example of this is the [[sodium-potassium pump]], which exchanges [[sodium]] ions for [[potassium]] ions and is essential for certain types of cellular activity, such as recovery from an [[action potential]].  Such a system is called [[coupled transport]] in which the movement of one molecules is linked to the movement of another.  There are several subsets of coupled transport; the [[antiport]], in which each molecule type is unidirectional, and the [[symport]] and [[uniport]] in which both molecules go in the same direction.
Active transport is the movement of molecules across the cell membrane which costs the cell energy through use of [[ATP]], adenosine triphosphate.  Typically this is because molecules must be moved up the concentration gradient to either remove or obtain the desired concentrations inside the cell.  One such example of this is the [[Na,K-ATPase|sodium-potassium pump]], which exchanges [[sodium]] ions for [[potassium]] ions and is essential for certain types of cellular activity, such as recovery from an [[action potential]].  Such a system is called [[coupled transport]] in which the movement of one molecules is linked to the movement of another.  There are several subsets of coupled transport; the [[antiport]], in which each molecule type is unidirectional, and the [[symport]] and [[uniport]] in which both molecules go in the same direction.


==Endocytosis and Exocytosis==
==Endocytosis and Exocytosis==

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The cell membrane or plasma membrane comprises the outer surface of a cell — a boundary that encloses the contents of the cell. The cell membrane is composed of a phospholipid bilayer studded with proteins. The unit structure of the phospholipid bilayer consists of two fatty acid chains that link to two of the three carbons of a molecule of glycerol. The third carbon is attached to a phosphate group, which is in turn often attached to an alcohol or amine. The alcohol makes the phosphate-alcohol group, or head group, hydrophilic. The fatty acid chains, or tails, are hydrophobic. This results in the hydrophilic parts pointing towards each other and the hydrophilic parts pointing to the extra and intracellular areas. The unit structure repeats in a parallel array that creates a three-dimensional enclosed fluid-filled surface. The fluid mosaic model of the plasma membrane holds that there are two types of proteins in the phospholipid bilayer. The first is called an integral protein. These proteins are generally fixed and cannot be removed without rupturing the cell. One type of integral protein called the transmembrane protein spans the membrane, so that its surface is both on the inside and outside of the cell. A second type of membrane protein is called a peripheral protein and can easily be removed from the membrane.

Public domain, courtesy Mariana Ruiz. The cell membrane, also called the plasma membrane or plasmalemma, is a semipermeable lipid bilayer common to all living cells. It contains a variety of biological molecules, primarily proteins and lipids, which are involved in a vast array of cellular processes. It also serves as the attachment point for both the intracellular cytoskeleton and, if present, the cell wall.
(PD) Image: National Institutes of Standards and Technology
"Cartoon of a typical cell membrane. Proteins are embedded in a matrix of phospholipid molecules. Several other membrane constituents such as glycolipids and cholesterol are also shown."





See also: Animated essentials of cell membrane structure.[1]


Membrane Permeability

An essential feature of any plasma membrane is the ability to transport materials in and out of the cell.

Passive Transport

Semi-permeable or selectively permeable membranes allow certain types of substances through the membrane and not others. Some forms of transport require no energy to perform- these mechanisms are called passive transport. The most common forms of passive transport are diffusion and osmosis. Diffusion occurs when a certain substance, such as an ion, is more concentrated on one side of the membrane. If the membrane allows this ion through, then ions will move from the more concentrated side to the less concentrated side until reaching equilibrium.

Osmosis is the diffusion specifically of water across a membrane. A cell's tonicity indicates in which direction is the net flow of water and is based on the ionic content of the cell. A cell which is isotonic has an ionic concentration identical inside the membrane and out. Since the cell is at equilibrium, there is no concentration gradient and the flow of water in is equal to the flow of water out. A cell which is hypertonic has a higher concentration inside the cell than out. This causes a concentration gradient across the membrane which results in a net flow of water into the cell. A cell which is hypotonic has a lower concentration and therefore water will flow out of the cell. This tendency of a concentration gradient to cause a net flow of water is referred to as osmotic pressure.

Facilitated diffusion is a passive form of transport whereby specific types of molecules are chemically encouraged to cross the membrane, but are not directional. That is, molecules will only flow down a concentration gradient, which is definitionally passive transport. This is accomplished by specialized proteins embedded in the surface called channels and carriers. Channels are gaps which allow the molecule to flow through them, and are sometimes gated (that is, are only open under certain conditions.) Carriers, or porters, chemically interact with the molecule to induce a conformational change which moves the molecule to the other side of the membrane.

Active Transport

Active transport is the movement of molecules across the cell membrane which costs the cell energy through use of ATP, adenosine triphosphate. Typically this is because molecules must be moved up the concentration gradient to either remove or obtain the desired concentrations inside the cell. One such example of this is the sodium-potassium pump, which exchanges sodium ions for potassium ions and is essential for certain types of cellular activity, such as recovery from an action potential. Such a system is called coupled transport in which the movement of one molecules is linked to the movement of another. There are several subsets of coupled transport; the antiport, in which each molecule type is unidirectional, and the symport and uniport in which both molecules go in the same direction.

Endocytosis and Exocytosis

Endocytosis is the process by which a cell moves a relatively large substance into the a cell; Exocytosis is the process by which large substances are moved out of a cell. In endocytosis, the membrane surrounds the particle that is outside, invaginates, and is snipped off inside the cell. With exocytosis, the particle is put inside a vesicle, which then fuses with the membrane outside.

Endocytosis can be divided into two types; pinocytosis, which describes the intake of particles or liquids into the cell, and phagocytosis, which occurs with larger material, such as bacteria.

Receptor-mediated endocytosis, which is generally used to move large protein complexes into the cell, relies on protein receptors on the outside of the plasma membrane. These receptors are located in a clathrin-coated pits, small indentations in the membrane coated with the specialized protein clathrin. When the protein complex is fully affixed to the receptors in the pit, the protein changes conformation, invaginating the section of the membrane.

Cellular Adhesion

Cellular adhesions are the points to which other cells attach on the cell membrane. These types of cells are most commonly found in tissue where adhesion is important, such as in epithelial cells. There are three major types of cellular adhesion.

Tight junctions are regions where there is no space in between cells. That is, part of the membrane is in close contact with another part of the membrane. However, no molecules or ions can pass between them from one cell to the next.

Gap junctions are areas of contact between cells through which small molecules and ions can pass from one cell to the next. This is done in the form of a pore, which are composed of 6 molecules arranged in a circle on the surface of the membrane. Changes in confirmation of these molecules opens and closes the pore.

Desmosomes are areas where cells are connected by glycoprotein filaments. This type of junction is the most common one.

  1. Kyrk J. (2007) Animated essentials of cell membrane structure.
    • Numerous beautiful and informative animations of cell membrane structure, properties and functions.