Zymogens - Online Tutor, Practice Problems & Exam Prep

In this video, we're going to introduce zymogens. So zymogens are also sometimes referred to as proenzymes. And so zymogens or proenzymes are just inactive enzyme precursors that have the potential and can be converted into active enzymes. But, again, zymogens or proenzymes are inactive enzyme precursors themselves, and so they are not active enzymes but can be converted into active enzymes. Now activation of a zymogen usually occurs via cleavage of peptide bonds. And so we already know from our previous lesson videos that proteolytic cleavage is a type of post-translational modification that regulates protein activity. And so notice down below in our image on the left-hand side, what we have is the raw protein immediately after translation, and some proteins are zymogens immediately after translation, which means that they are inactive enzyme precursors. And so zymogens can be activated into their active form, usually through proteolytic cleavage, which is why we have these scissors right here. And notice that activation will result in the active form of our protein, and of course, the inactive forms are going to be cleaved off.

Now, it's important to know that zymogens usually begin with the prefix pro or they end in the suffix o gen. And so over here on the right, what we have is a table with some examples of zymogens, which are again inactive enzyme precursors themselves. And we also have the site of synthesis. And so notice that a lot of digestive enzymes that are synthesized in either the stomach or the pancreas are going to have zymogens. And so notice that, pepsinogen, chymotrypsinogen, and trypsinogen all end in the suffix o gen, and so that indicates that these are the zymogens, the inactive enzyme precursors, of pepsin, chymotrypsin, and trypsin, peptidases that we know are active enzymes from our previous lesson videos. And also notice that procarboxypeptidase and proelastase begin with the prefix pro, which indicates that these are also zymogens, inactive enzyme precursors for the active form of the enzymes carboxypeptidase and elastase, which are also peptidases themselves. And so in our next lesson video, we're going to talk about exactly why it is that these zymogens are so important for life and important for regulating protein activity. So I'll see you guys in our next video.

So from way back in our previous lesson videos, we already know that both trypsin and chymotrypsin are peptidases that act as digestive enzymes. And so what we learned in our last lesson video is that both trypsin and chymotrypsin are digestive enzymes with classic examples of zymogens. And so notice down below in our image on the left-hand side towards the top in red, we have a structure that represents the inactive zymogen called trypsinogen. And we know that it is a zymogen because it ends in the suffix "ogen". And so we know that inactive zymogens are typically activated through proteolytic cleavage, which requires a peptidase to cleave off a small portion of the trypsinogen molecule. But in the process, it generates this green molecule right here that we know as the active trypsin peptidase.

And so notice down below on the bottom half of our image we have a similar representation where this red structure right here represents the inactive zymogen known as chymotrypsinogen, which again ends with the suffix "ogen", so we know it is a zymogen. And so we again know that inactive zymogens are typically activated through proteolytic cleavage, which involves a peptidase that will cleave off small portions of the chymotrypsinogen molecule, but in the process, it generates this green molecule right here that we know as the active chymotrypsin peptidase. And so notice that the chymotrypsinogen molecule has these disulfide bonds here in blue. Even through proteolytic cleavage, these disulfide bonds are not altered.

Now the question arises as to why these zymogens are so important for cells? Well, it turns out that it's actually super critical for cells to store these hydrolytic enzymes, such as trypsin and chymotrypsin, as inactive zymogens because otherwise, they could potentially kill the cell. And so notice that, up above in this image right here, what we have is this green circle here that represents our eukaryotic cell and within the eukaryotic cell we have this purple circle that represents a vesicle or a granule and within this granule, notice that we have the same exact trypsinogen molecule that we had on the left.

Inside of the cell, notice that the protein is going to be stored in its zymogen form where it is inactive. And that's a good thing because otherwise, if it were in the active trypsin form, then the trypsin could potentially be cleaving the proteins within the cell and that could potentially kill the cell. And so within the cell, it's stored as the inactive trypsinogen or inactive zymogen. And then the protein, the inactive zymogen can be secreted to the outside of the cell, essentially into the stomach, through the process of exocytosis. And, once the inactive zymogen is in the stomach, then notice that it can be activated into its active trypsin form where it can begin to break down the proteins that we've eaten inside of our stomachs.

And so again, this is all showing how by storing enzymes as zymogens, cells are able to regulate the enzymes' activity and make sure that the enzymes are not going to kill or destroy their own proteins. And so again, by storing these enzymes as zymogens, this is really a form of regulating the enzymes' activity. Which is again why we're talking about the zymogens right now. And so, this here concludes our lesson on zymogens and we'll be able to get some practice utilizing the concepts that we've learned in our next couple of videos. So I'll see you guys there.