Skip to main content

Cells and Their Organelles: 2) Junctions and Communication

 Junctions and Communication

Cells are packed very tightly next to each other inside living organisms. If you've ever seen an onion cell under a microscope, you'd see the plant cells all right next to each other. There are practically no gaps between cells. In the images below, each rectangular shape is a cell. The purple color is due to staining (adding color) so it's more visible. 



In order to pass information between cells, as well as things like ions and molecules, cells need a way of communication. This comes in the form of junctions. Junctions can be 'seams' or 'gaps' between cells that either increase or decrease communication and allow for the passage of molecules. 

Plasmodesmata - found only in plant cells. Has a small channel that directly connects the cytoplasm of neighboring plant cells via traversing the cell wall. Its goal is to move water, nutrients, and other molecules between cells. It increases communication because molecules, solutes, and water pass between cells through this type of junction. 

Gap Junction - found only in animal cells. Has a small channel that directly connects the cytoplasm of neighboring animal cells through the cell membrane. Its goal is to move ions, molecules, and water. It increases communication because molecules, solutes, and water pass between cells through this type of junction. 

Tight Junction - found only in animal cells. It forms a tight seal between adjacent cells by linking membrane proteins, creating a barrier. This prevents the leakage of molecules between cells. It decreases communication because it stops the passage of materials between cells. 

Desmosome - adheres cells together. Two adjacent cells are attached. A desmosome is made out of protein plaques in the cell membrane linked by filaments. It supports movement and mechanical stability. 

The following molecules are not junctions but are also used for communication or for the passage of molecules, similar to junctions. 

Membrane Proteins: There are two types, as follows. 

    - Peripheral Proteins: loosely bound to the surface of the membrane. Examples include receptors and markers. 

    - Integral Proteins: transmembrane proteins that penetrate the lipid bilayer, usually across whole membranes. Examples include transport proteins like channels and ion pumps (we'll get into that in an upcoming lesson). 

Membrane Carbohydrates (antigens): they give the cell the ability to distinguish one cell from another. Important in tissue and organ development. These are the basis for rejection of foreign cells by the immune system (this lesson comes up WAY later). 

Now for the joke! How do trees access the internet?
They log in!

(haha)

That's it! Next up: Types of Transport in Cells! 




Comments

  1. Is the gap junction like a tube that can open and close?

    ReplyDelete
  2. Do all organ cells have the same membrane carbohydrates that all tag them as organ cells?

    ReplyDelete
    Replies
    1. Not all cells in a specific organ have the same function (so they have different antigens that distinguish those roles from one another). However, all cells in a specific organ (say, the liver) may share some similar features to one another that all say "Hey, I'm a liver cell!" but small differences in those membrane carbohydrates will say "Hey, I'm a liver cell that does actual liver things" or "Hey, I'm a liver cell that deals with excess fat in the liver!" (just an example). So, they won't have the SAME, but they will have SIMILAR, membrane carbohydrates. Hope that helps!

      Delete
    2. Thanks =)

      Delete
  3. whats the plaque in the desmosome?

    ReplyDelete
    Replies
    1. Hey! The plaque is, essentially, a dense area of proteins that hold filaments (shown on the intercellular space in the pics) and links it with the linker proteins in the extracellular space. It provides structural and mechanical stability :)

      Delete

Post a Comment

Questions about a topic? Write it here! I'll try my best to get back to you asap :)

Popular posts from this blog

Cells and Their Organelles: 4) Tonicity

 Tonicity Tonicity is the ability of a surrounding solution to cause a cell to gain or lose water.  A hypotonic solution refers to a solution that, when surrounding a cell, causes the cell to gain water.  This is because there is more solute inside the cell than outside the cell. In Greek, 'hypo' means less. Since there are more solutes inside the cell than outside, water will move into  the cell. A hypertonic   solution refers to a solution that, when surrounded a cell, causes the cell to lose water.  This is because there is less solute inside the cell than outside the cell. In Greek, "hyper" means more. Since there are more solutes outside the cell than inside, water will move out of the cell. An isotonic   solution refers to a solution that, when surrounding a cell, doesn't induce any change in the water content of the solution or cell. This is because there are equal amounts of solute inside and outside the cell, so there will be no net move...

Cells and Their Organelles: 3) Transport

 Transport There are two types of transport that occur between cells: passive and active transport.  Passive Transport -  Molecules naturally move from an area of high concentration to low concentration. This does not use energy. There are 3 types of passive transport: simple diffusion , facilitated diffusion , and osmosis .      - Simple Diffusion: Small and nonpolar molecules more from an area of high to low concentration. If there is more than one solute, then those solutes will be equally distributed across a membrane. These molecules will be able to easily pass through the membrane, which is why it's called simple diffusion: nothing is needed to help it pass through.       - Facilitated Diffusion: Polar molecules and ions impeded by the bilayer of the membrane are diffused passively with the help of transport proteins spanning the membrane. Diffusion will occur through protein channels. Again, it moves from high concentration to low...

Cells and Their Organelles: 5) Mini Lesson on Thermodynamics and Types of Reactions

 Thermodynamics and Types of Reactions Before we get into learning about the mitochondrion, we need to know a little bit about the laws of thermodynamics. First Law of Thermodynamics: energy cannot be created nor destroyed, only transferred.          - For example, when boiling a pot of water, the chemical or electrical energy is converted into heat. No energy is lost. Second Law of Thermodynamics: entropy increases each time energy is transferred or transformed.          - For example, melting an ice cube will result in the (solid) ice cube turning into (liquid) water, which is a disordered state. An  oxidation reaction  is a reaction with a loss of electrons. This is often found in biology as the loss of a hydrogen atom. Losing an electron (which is negative) means the molecule has become a little bit more positive, so in a reaction like this: the oxidized molecule will typically be denoted with a '+'. In a reduction re...