I'm going to say here that a cell membrane separates the interior of the cell from the external environment. We're going to say they're mainly composed of glycerophospholipids as well as sphingolipids. They have what we call a selectively permeable membrane, so that means it controls what goes into and out of the cell. And we take a look here, we have what is called our lipid bilayer. This represents the exterior of the cell, this represents the interior of our cell. We're going to say that we have our polar heads here, we have the nonpolar tails in the center, and then we have polar heads again. This lipid bilayer will help to control the flow of what goes into and out of our cell.
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Cell Membranes: Study with Video Lessons, Practice Problems & Examples
The cell membrane, primarily composed of glycerophospholipids and sphingolipids, acts as a selectively permeable barrier, regulating the movement of substances in and out of the cell. The fluid mosaic model describes its dynamic structure, featuring a lipid bilayer with polar heads and hydrophobic tails, along with integral and peripheral proteins, carbohydrates, and cholesterol. Cholesterol enhances membrane strength, while carbohydrate side chains facilitate cell recognition. This organization is crucial for processes like active transport and cellular communication, ensuring proper cellular function and homeostasis.
Cell Membranes Concept 1
Video transcript
Cell Membranes Concept 2
Video transcript
Now when it comes to our membrane structure, we follow what's called a fluid mosaic model. Here, this is a model for representing the general structure of a cell membrane. Now, when we say the word fluid, we're going to say the lipid bilayer is not rigid but fluid and dynamic. We're going to say here, phospholipids in the lipid bilayer do not fit closely together due to kinks in the fatty acid chains. So here we have our phospholipid, and we're going to say that we have the polar heads orienting themselves on the externals, and then we have our hydrophobic tails on the interior of forming this lipid bilayer.
Now, Mosaic is basically the lipid bilayer also containing proteins, carbohydrates, and cholesterol molecules. If we take a look here, we're going to say that these two structures at the top represent our carbohydrate side chains. We have here, 4 fused rings together which means it's a steroid and specifically, it would be cholesterol. Next, we have here, this is called an integral protein. And if we're talking about integral proteins, we're going to say they extend through the entire bilayer and appear on both sides. We're going to say next, we have our peripheral proteins, They're associated with our with just one side. Our peripheral protein will be this green blob right here. It doesn't cut all the way through to over here like the integral proteins would.
We have our carbohydrate side chains that we talked about up top. These extend into the extracellular fluid, and they're responsible for cell recognition and communication. Now, we talked about these 4 fused rings here representing a steroid, but specifically cholesterol. So remember, cholesterol here resides within a bilayer and increases membrane strength based on how much cholesterol we have there. And then in terms of this, remember we talked about this being the polar heads, we have our non-polar tails, our hydrophobic tails in the inside, and then we have our polar heads over here. This would give us a good description of what we mean by a fluid mosaic model.
Cell Membranes Example 1
Video transcript
In this example question, it asks which one of the following is not a component of cell membranes? Here, cholesterol. We've talked about cholesterol, which is represented by our 4 fused rings as being a key component of a cell membrane, and it helps with the membrane's strength based on the amount of cholesterol within it. So, this is a part. Sphingomyelins. We talked about our phospholipids helping to create the lipid bilayer. A phospholipid can also be in the form of sphingomyelin. So, sphingomyelins are a type of phospholipid. Proteins. Now, we said that proteins are part of our cell membrane, they can exist as integral proteins which are found on both sides, or they can be peripheral proteins that are only found on one side. The answer here would be waxes. Waxes do not represent a component of a cell membrane. So, here, our final answer would be option d.
Which one of the following components of a cell membrane extends through its entire thickness?
Cholesterol
Peripheral proteins
Integral protein
Sphingomyelin
Keeping in mind that unsaturated fatty acids form kinks in the phospholipid tails, what would happen if all of the unsaturated fatty acids in a lipid bilayer were replaced with saturated fatty acids?
It will become more fluid.
Its fluidity will be significantly reduced.
There will be no effect on its fluidity.
The lipid bilayer will become resistant to oxidation.
Do you want more practice?
Here’s what students ask on this topic:
What is the fluid mosaic model of the cell membrane?
The fluid mosaic model describes the structure of the cell membrane as a dynamic and flexible layer. It consists of a lipid bilayer with polar heads facing outward and hydrophobic tails facing inward. This bilayer is not rigid but fluid, allowing lipids and proteins to move laterally within the layer. The 'mosaic' part of the model refers to the embedded proteins, carbohydrates, and cholesterol molecules that are interspersed throughout the lipid bilayer. Integral proteins span the entire bilayer, while peripheral proteins are associated with only one side. Cholesterol molecules within the bilayer enhance membrane strength and fluidity. Carbohydrate side chains extend into the extracellular fluid, playing roles in cell recognition and communication.
What are the main components of the cell membrane?
The main components of the cell membrane include glycerophospholipids, sphingolipids, proteins, carbohydrates, and cholesterol. Glycerophospholipids and sphingolipids form the lipid bilayer, with polar heads facing outward and hydrophobic tails facing inward. Proteins in the membrane are of two types: integral proteins, which span the entire bilayer, and peripheral proteins, which are associated with one side of the bilayer. Carbohydrates are attached to proteins and lipids on the extracellular side, aiding in cell recognition and communication. Cholesterol molecules are interspersed within the bilayer, enhancing membrane strength and fluidity.
How does cholesterol affect the cell membrane?
Cholesterol plays a crucial role in maintaining the cell membrane's structure and function. It resides within the lipid bilayer, where it interacts with the fatty acid tails of phospholipids. Cholesterol increases membrane strength and stability by preventing the fatty acid chains from packing too closely together, which maintains membrane fluidity. This fluidity is essential for the proper functioning of membrane proteins and for the overall flexibility of the cell membrane. Additionally, cholesterol helps to protect the membrane against temperature fluctuations, ensuring that it remains functional under various conditions.
What is the role of carbohydrate side chains in the cell membrane?
Carbohydrate side chains in the cell membrane are primarily involved in cell recognition and communication. These carbohydrates are attached to proteins (forming glycoproteins) or lipids (forming glycolipids) on the extracellular side of the membrane. They act as molecular 'tags' that can be recognized by other cells and molecules, facilitating processes such as cell-cell adhesion, immune response, and signaling. For example, blood type antigens are carbohydrate structures on the surface of red blood cells. These carbohydrate side chains are crucial for the proper functioning of multicellular organisms, as they enable cells to interact and communicate effectively.
What is the significance of the lipid bilayer in the cell membrane?
The lipid bilayer is a fundamental component of the cell membrane, providing a barrier that separates the cell's interior from its external environment. It is composed of two layers of phospholipids, with hydrophilic (polar) heads facing outward and hydrophobic (non-polar) tails facing inward. This arrangement creates a selectively permeable barrier, allowing the cell to control the movement of substances in and out. The lipid bilayer's fluid nature enables the membrane to be flexible and dynamic, accommodating the movement of proteins and other molecules within it. This fluidity is essential for various cellular processes, including membrane transport, cell signaling, and maintaining homeostasis.
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