9.3: Membrane Fluidity

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A Fluid Barrier

The mosaic characteristic of the membrane, described in the fluid mosaic model, helps to illustrate its nature. The proteins and other components that exist in the membrane can move with respect to each other, rather like boats floating on a lake. The membrane is not like a balloon, however, that can expand and contract; rather, it is fairly rigid and can burst if penetrated or if a cell takes in too much water. However, because of its mosaic nature, a very fine needle can easily penetrate a plasma membrane without causing it to burst, and the membrane will flow and self-seal when the needle is extracted.

Temperature

The fluidity of the membrane is affected by temperature. In colder temperatures, the plasma membrane will be more rigid than in warmer temperatures. In fact, to lyse (burst), open cells in the lab, scientists use heat, which will cause the membrane to become too fluid and fall apart. As you might imagine, it's essential for organisms to keep their cell membranes from getting too fluid or too rigid. We'll come back to this idea after learning about how the fatty acids and cholesterol in the membrane affect fluidity.

Structure of Fatty Acids

The structure of the fatty acid tails in each phospholipid can make the membrane more dense and rigid, or less dense and flexible.

The relative fluidity of the membrane is particularly important in a cold environment. A cold environment tends to make membranes less fluid and more susceptible to rupturing. Many organisms (fish are one example) are capable of adapting to cold environments by changing the proportion of different types of fatty acids in their membranes in response to the lowering of the temperature. A plasma membrane that has phospholipids with more saturated fatty acids will be less fluid, compared to one with more unsaturated fatty acids, which will be more fluid.

Cholesterol

Animals have an additional membrane constituent that assists in maintaining fluidity. Cholesterol, which lies alongside the phospholipids in the membrane, tends to dampen the effects of temperature on the membrane. Thus, this lipid functions as a buffer, preventing lower temperatures from inhibiting fluidity and preventing increased temperatures from increasing fluidity too much. Thus, cholesterol extends, in both directions, the range of temperature in which the membrane is appropriately fluid and consequently functional.

Putting it all Together

Review the effect of temperature, fatty acid saturation and cholesterol have on the fluidity of the membrane.

Consider the following:

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