Ion: an atom or molecule that does not have the same number of electrons as it has protons. This gives the atom or molecule a negative or positive charge... more
Molecule: a chemical structure that has two or more atoms held together by a chemical bond. Water is a molecule of two hydrogen atoms and one oxygen atom (H2O)... more
Protein: a type of molecule found in the cells of living things, made up of special building blocks called amino acids.
The body is always busy making and moving things around. It needs to be sure that the right items are moved from place to place. It also has to be sure that cells allow only the right materials and amounts to enter and exit cells. A lot of this is the work of channel proteins.
Channeling your inner biology
There are many different types of channel proteins in your body, and each one will only let specific types of molecules pass through. Just like a house with three doors that go to the back yard- one for your cat, a bigger doggie door for your St. Bernard, and a regular door for people. The dog door is too heavy for the cat to move. The cat flap is too small for people or the dog. The big door needs thumbs to turn the doorknob. Each door works for only the animal that is supposed to be using it.
How do channel proteins select which molecules to let through?
Just like our three door example, size is one way that channels select the right molecules. A lot of these channels only allow small molecules called ions to pass through. Many of these ions are as tiny as one atom. Channels built for these molecules are just too small for other things to fit through.
Another way to allow only some ions through and keep others out is by their charge. Ions have either a positive or negative charge. Ever hear that opposites attract? It's true for molecules as well as people.
Positive charges are attracted to negative charges. Two charges that are the same, positive/ positive or negative/negative, will repel each other. That's how channels use charge to select which molecules go through. The inside of the channel will actually have a charge that is opposite of the molecule that it wants to let through. This allows it to attract the right molecules. Let's check out some examples.
This channel is so specific to water molecules that it only lets them go through in single file and makes them do a flip halfway down the channel. Think of all those water molecules lined up – each waiting their turn to do a flip off the diving board. No flip, no entry to the cell. These channels get their name from what they do - aqua meaning water and porin meaning hole or pore. There are many kinds of "water pores" that are found in plants, bacteria, and animals.
One place aquaporins are found is your kidneys. Channel proteins help your body reclaim water so you don't lose too much fluid in your pee. Go ahead, drink a big glass of water and think about all the little channel proteins making sure you keep just the right amount of that water in your body.
Ion channel attacked by scorpion venom! Molecular bad guy or cure for cancer?
If you played the Venom Game, you helped defend a channel protein that normally lets ions into and out of your cells from a toxin in scorpion venom called chlorotoxin. This toxin blocks channels in muscle cells that let chloride ions go in and out. Chloride ions are chlorine atoms with a negative charge. These ions normally help tell muscle cells when to relax.
If enough of these channels get blocked, all the muscles flex at once and the animal that the scorpion stung won't be able to move. This is pretty handy for the scorpion, as it can now eat its prey at its leisure.
But there's more to the story...scientists have found out that some kinds of brain tumor cells have lots of the kind of ion channels that are affected by scorpion toxin, but the normal cells in the brain don't have many of these channels. This makes deathstalker scorpion toxin a potential treatment for some kinds of cancer. Talk about a molecule with a split personality.
Marcella Martos, Meredith Turnbough. (2013, January 01). Protein Channels. ASU - Ask A Biologist. Retrieved from https://askabiologist.asu.edu/fr/venom/protein-channels
Marcella Martos, Meredith Turnbough. "Protein Channels". ASU - Ask A Biologist. 01 January, 2013. https://askabiologist.asu.edu/fr/venom/protein-channels
Marcella Martos, Meredith Turnbough. "Protein Channels". ASU - Ask A Biologist. 01 Jan 2013. ASU - Ask A Biologist, Web. . https://askabiologist.asu.edu/fr/venom/protein-channels