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  • Let's talk about conformational stability

  • and how this relates to protein folding and denaturation.

  • So first, let's review a couple of terms

  • just to make sure we're all on the same page.

  • And first we'll start out with the term conformation.

  • And the term "conformation" just refers

  • to a protein's folded 3D structure, or, in other words,

  • the active form of a protein.

  • And next, we can review what the term "denatured" means

  • when you're talking about proteins.

  • And denatured proteins just refer

  • to proteins that have become unfolded or inactive.

  • So all conformational stability is really talking about

  • are the various forces that help to keep

  • a protein folded in the right way.

  • And these various forces are the four different levels

  • of protein structure, and we can review those

  • briefly right here.

  • So recall that the primary structure of a protein

  • just refers to that actual sequence

  • of amino acids in that protein.

  • And this is determined by a protein's peptide bonds.

  • And then next, you have secondary structure,

  • which just refers to the local substructures in a protein,

  • and they are determined by backbone interactions held

  • together by hydrogen bonds.

  • Then you have tertiary structure,

  • which just talks about the overall 3D

  • structure of a single protein molecule.

  • And this is described by distant interactions between groups

  • within a single protein.

  • And these interactions are stabilized by Van der Waals

  • interactions, hydrophobic packing, and disulfide bonding

  • in addition to the same hydrogen bonding that

  • helps to determine secondary structure.

  • And then quaternary structure just

  • describes the different interactions

  • between individual protein subunits.

  • So you have the folded-up proteins

  • that then come together to assemble the completed

  • overall protein.

  • And the interaction of these different protein subunits

  • are stabilized by the same kinds of bonds

  • that help to determine tertiary structure.

  • So all of these levels of protein structure

  • help to stabilize the folded-up, active conformation

  • of a protein.

  • So why is it so important to know

  • about the different levels of protein structure

  • and how they contribute to conformational stability?

  • Well, like I said, a protein is only functional

  • when they are in their proper conformation

  • and their proper 3D form.

  • And an improperly folded-- or degraded, denatured-- protein

  • is inactive.

  • So in addition to the four levels of protein structure

  • that I just reviewed, there is also

  • another force that helps to stabilize a protein's

  • conformation, and that force is called the solvation shell.

  • Now, the solvation shell is just a fancy way

  • of describing the layer of solvent that

  • is surrounding a protein.

  • So say I have a protein who has all these exterior

  • residues that are overall positively charged.

  • And picture this protein in the watery environment

  • of the interior one of our cells.

  • Then the solvation shell is going to be the layer of water

  • right next to this protein molecule.

  • And remember that water is a polar molecule.

  • So you have the electronegative oxygen atom

  • with a predominantly negative charge leaving

  • a positive charge over next to the hydrogen atoms.

  • The same is true for each of these water molecules.

  • So now as you can see, the electronegative oxygen atoms

  • are stabilizing all of the positively charged amino acid

  • residues on the exterior of this protein.

  • So, as you can see, the conformational stability

  • of a protein depends not only on all

  • of these interactions that contribute

  • to primary, secondary, tertiary, and quaternary structure,

  • but also what sort of environment that protein is in.

  • And all of these interactions are

  • very crucial for keeping a protein folded properly

  • so that it can do its job.

  • Now, what happens when things go wrong?

  • How does a protein become unfolded and thus inactive?

  • Well, remember that this is called denaturation.

  • And this can be done by changing a lot of different parameters

  • within a protein's environment, including

  • changing the temperature, the pH,

  • adding chemical denaturants, or even adding enzymes.

  • So let's start with what happens if you alter

  • the temperature around a protein.

  • And we can use the example of an egg

  • when we put it into a pot of boiling water,

  • because an egg, especially the white part, is full of protein.

  • And this pot of boiling water is representing heat.

  • And remember that heat is really just a form of energy.

  • So when you heat an egg, the proteins

  • gain energy and literally shake apart

  • the bonds between the parts of the amino acid chains,

  • and this causes the proteins to unfold.

  • So increased temperature destroys

  • the secondary, tertiary, and quaternary structure

  • of a protein.

  • But the primary structure is still preserved.

  • So the takeaway point is that when

  • you change the temperature of a protein by heating it up,

  • you destroy all of the different levels of protein structure

  • except for the primary structure.

  • So now let's say you were to take an egg and then add

  • vinegar, which is really just an acid.

  • The acid in the vinegar will break all the ionic bonds

  • that contribute to tertiary and quaternary structure.

  • So the takeaway point when you change the pH surrounding

  • a protein is that you have disruption of ionic bonds.

  • And if we think about this a little bit more deeply,

  • it makes sense, because ionic bonds

  • are dependent upon the interaction

  • of positive and negative charges.

  • So when you add either acid or base, which

  • in the case of an acid is just like adding

  • a bunch of positive charges, you disrupt the balance

  • between all of these interactions

  • between the positive and negative charges

  • within the protein.

  • So now let's look at how chemicals denature proteins.

  • Chemical denaturants often disrupt the hydrogen bonding

  • within a protein.

  • And remember that hydrogen bonds contribute

  • to secondary, tertiary, all the way up to quaternary structure.

  • So all of these levels of protein structure

  • will be disrupted if you add a chemical denaturant.

  • So let's take our same example of a protein with an egg,

  • and say if you were 21 years older,

  • you got your hands on some alcohol,

  • and you added this to the egg, then all the hydrogen bonds

  • would be broken up, leaving you with just linear polypeptide

  • chains.

  • And then finally, let's take our hard boiled egg

  • from the temperature example and lets eat it.

  • So here's my beautiful drawing of a person,

  • representing you, eating this hard-boiled egg.

  • Once the egg enters our digestive tract,

  • we have enzymes that break down the already denatured proteins

  • in the egg even further.

  • They take the linear polypeptide chain, whose primary structure

  • is still intact, and they break the bonds

  • between the individual amino acids, the peptide bonds,

  • so that we can absorb these amino acids from our intestines

  • into our bloodstream, and then we can use them

  • as building blocks for our own protein synthesis.

  • And that's how enzymes can alter a protein's primary structure

  • and thus the protein's overall conformational stability.

  • So what did we learn?

  • Well, we learned that the conformational stability

  • refers to all the forces that keep a protein properly

  • folded in its active form.

  • And this includes all of the different levels of protein

  • structure as well as the solvation shell.

  • And we also learned that a protein

  • can be denatured into its inactive form

  • by changing a variety of factors in its environment,

  • including changing the temperature, the pH,

  • adding chemicals or enzymes.

Let's talk about conformational stability

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