Denaturation - Online Tutor, Practice Problems & Exam Prep

So at this point, we've covered from primary protein structure all the way up through tertiary protein structure. Now, before we get to quaternary protein structure, there are a few topics that we need to talk about, and one of those topics is denaturation. So we'll talk about that now. Denaturation is just the process of disrupting a protein's structure and specifically, we're talking about disrupting the protein's secondary or tertiary structure just enough to cause a loss of protein function. So, a denatured protein will not be able to perform its job. And one thing that's not affected by denaturation is the primary protein structure. The primary protein structure, or the composition and sequence of the amino acids, is not affected by denaturation. Now, denaturation can result from several different factors, from radiation to changes in temperature or even changes in pH. And it can even result from the addition of reagents that affect structure, and we'll talk about some of those reagents in our next lesson video. Now, renaturation is actually the reverse process of denaturation. This is the process where we can take a denatured protein and regain the protein's original structure and shape. And so in our example below, we're going to distinguish between denaturation and renaturation. What we have on the left over here is a normal protein shape, and our normal protein shape has normal biological activity. That means that it does its job. A denatured protein is a denatured protein shape. And notice that it's lost a lot of its structure. The alpha helices that were present over here and some of the beta sheets and all of these turns and stuff like that, a lot of that structure has been lost. So mostly secondary and tertiary structure. But again, the primary protein structure is still intact, so we still have our N-terminal and our C-terminal, and the order, sequence, and composition of amino acids are all still fine when a protein is denatured. But our denatured protein has now lost all of its biological activity, which means that it cannot perform its function anymore. Now, if we take our denatured protein and we go through a process of renaturation, that would be the reverse process of denaturation. So that's taking our denatured protein and regaining its original shape and function. So that would be the process of going from this denatured protein over to the original protein. And so, this distinguishes between denaturation and renaturation, and we'll be able to get some practice in our next practice video. So I'll see you guys there.

So in our last lesson video, we talked about how protein denaturation can be caused by several different factors, including the addition of specific reagents. In this video, we're going to talk about 2 specific reagents that can be used to denature a protein, namely urea and beta mercaptoethanol. Urea is known as a chaotropic agent, which means it disrupts the noncovalent interactions. This disruption affects the tertiary structure and denatures the protein. Although scientists do not fully agree on the mechanism chaotropic agents use, they do know that these molecules disrupt the hydrogen bonding network of water molecules, which, in biological systems, is the solvent for all proteins. Disrupting this network leads to altered protein stability by affecting noncovalent interactions.

Beta mercaptoethanol, on the other hand, specifically cleaves the disulfide bonds, which are covalent R-group interactions, through a redox reaction. Below, we discuss the effects of urea and beta mercaptoethanol on protein structure. On the left, our native protein in its normal structure includes alpha helices, beta sheets, and disulfide bonds, indicated in red. Adding urea, a chaotropic agent, disrupts noncovalent interactions, leading to a denatured protein without secondary structures but retaining intact disulfide bonds. Interestingly, removing urea may sometimes allow the protein to renature, regaining its native structure and function, as we'll see in upcoming videos on the Anfinsen experiment.

To completely denature the protein, both noncovalent and covalent R-group interactions, including disulfide bonds, must be disrupted. Beta mercaptoethanol plays a crucial role here. With its addition, a disulfide bridge is cleaved, leading to the formation of two separate cysteine molecules each with a sulfhydryl group (SH). These are no longer linked by the disulfide bridge. Under specific conditions, removing beta mercaptoethanol allows the reoxidation and reformation of this disulfide bridge. We will explore further examples of this in the Anfinsen experiment in our next few videos. So, in our next lesson, we'll get some practical experience with these concepts. See you in that video.