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Membrane Proteins

Proteins embedded in the plasma membrane assist other substances in crossing the membrane.

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Membrane Proteins

Can anything or everything move in or out of the cell?

No. It is the semipermeable plasma membrane that determines what can enter and leave the cell. So, if not everything can cross the membrane, how do certain things get across?  Watch this short video showing "osmosis in the kitchen" at http://www.youtube.com/watch?v=H6N1IiJTmnc&feature=related

Answer the following questions -

1) Why is the lettuce changing shape?
2) Where in the lettuce is the change happening?
3) What factor(s) contributes to the shape change?

Membrane Proteins

The plasma membrane contains molecules other than phospholipids, primarily other lipids and proteins. The green molecules in Figure below, for example, are the lipid cholesterol. Molecules of cholesterol help the plasma membrane keep its shape. Many of the proteins in the plasma membrane assist other substances in crossing the membrane.

The plasma membranes also contain certain types of proteins. A membrane protein is a protein molecule that is attached to, or associated with, the membrane of a cell or an organelle. Membrane proteins can be put into two groups based on how the protein is associated with the membrane.

Integral membrane proteins are permanently embedded within the plasma membrane. They have a range of important functions. Such functions include channeling or transporting molecules across the membrane. Other integral proteins act as cell receptors. Integral membrane proteins can be classified according to their relationship with the bilayer:

  • Transmembrane proteins span the entire plasma membrane. Transmembrane proteins are found in all types of biological membranes.
  • Integral monotopic proteins are permanently attached to the membrane from only one side.

Some integral membrane proteins are responsible for cell adhesion (sticking of a cell to another cell or surface). On the outside of cell membranes and attached to some of the proteins are carbohydrate chains that act as labels that identify the cell type. Shown in Figure below are two different types of membrane proteins and associated molecules.

Peripheral membrane proteins are proteins that are only temporarily associated with the membrane. They can be easily removed, which allows them to be involved in cell signaling. Peripheral proteins can also be attached to integral membrane proteins, or they can stick into a small portion of the lipid bilayer by themselves. Peripheral membrane proteins are often associated with ion channels and transmembrane receptors. Most peripheral membrane proteins are hydrophilic.

Some of the membrane proteins make up a major transport system that moves molecules and ions through the polar phospholipid bilayer.

The Fluid Mosaic Model

In 1972 S.J. Singer and G.L. Nicolson proposed the now widely accepted Fluid Mosaic Model of the structure of cell membranes. The model proposes that integral membrane proteins are embedded in the phospholipid bilayer, as seen in Figure above. Some of these proteins extend all the way through the bilayer, and some only partially across it. These membrane proteins act as transport proteins and receptors proteins.

Their model also proposed that the membrane behaves like a fluid, rather than a solid. The proteins and lipids of the membrane move around the membrane, much like buoys in water. Such movement causes a constant change in the "mosaic pattern" of the plasma membrane.

A further description of the Fluid Mosaic Model can be viewed at http://www.youtube.com/watch?v=ULR79TiUj80 (1:27).

Extensions of the Plasma Membrane

The plasma membrane may have extensions, such as whip-like flagella or brush-like cilia. In single-celled organisms, like those shown in Figure below, the membrane extensions may help the organisms move. In multicellular organisms, the extensions have other functions. For example, the cilia on human lung cells sweep foreign particles and mucus toward the mouth and nose.

Flagella and Cilia. Cilia and flagella are extensions of the plasma membrane of many cells.


  • The plasma membrane has many proteins that assist other substances in crossing the membrane.
  • The Fluid Mosaic Model depicts the biological nature of the plasma membrane.
  • Cilia and flagella are extensions of the plasma membrane.


Use these resources to answer the questions that follow.

  1. What is the major role of many membrane proteins?
  2. How much of a cell's genetic material may code for membrane proteins?
  3. What are transmembrane proteins, and what is their main function?
  4. How can a protein "tunnel" form through the membrane?
  5. How can a protein "channel" form through the membrane?
  1. How may water molecules enter the cell?
  2. How may ions enter the cell?
  3. What type(s) of protein(s) identify the cell?
  • http://www.hippocampus.org/Biology \begin{align*}\rightarrow\end{align*} Biology for AP* \begin{align*}\rightarrow\end{align*} Search: Membrane Structure
  1. Why do phospholipid molecules form a double layer in the membrane?
  2. What is the function of cholesterol in the membrane?
  3. What is the difference between integral and peripheral membrane proteins?
  4. Describe the main features of the fluid mosaic model.
  5. What is a transmembrane protein? Explain how are they oriented in the membrane.
  6. How do bacterial α-toxin proteins damage membranes?
  7. What happens when cells can no longer control the movement of materials across their membrane?


1. What are the main differences between the types of proteins associated with the plasma membrane?

2. Discuss the Fluid Mosaic Model.

3. What are flagella and cilia?

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