User:Michael Roberts/Open-Day Demo

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Interactive visualisation of 3D protein structures

Understanding the 3-dimensional structures of proteins is key to understanding their functions. Identifying the positions of all the different atoms that make up an individual protein (there are usually several thousand atoms in a single protein) is a big job, but once achieved, we can use a range of tools to visualise protein structures. Here, we'll have a look at some different ways of representing molecular structures of proteins, and in so doing, start to see the key structural elements that characterise protein structure.

Representing protein structures

Spacefill model

The view on the right shows a model of chymotrypsin, an enzyme that digests proteins in the gut. This is a so-called view, in which each atom is shown as a sphere. Different atoms are coloured individually: grey = carbon, red = oxygen, blue = nitrogen, etc.

In spacefill view, we can see the overall shape of the protein, but not much else. We cant see what's going on inside, for example.

Ball-and-stick molecular model

This view shows chymotrypsin in the familiar representation. Atoms are indicated by small spheres, with the sticks that link them together representing covalent bonds.

Now we can see all the atoms in the protein, but again, it's difficult to get a feel for how it is organised. It's very difficult to follow the chain of amino acids that makes up the protein, for example.

Amino acid trace

Here's a much more simplified view that of the amino acids that make up the protein. Now we can see much more clearly the start and end of each chain (there are 3 chains in chymotrypsin, each coloured differently in this view), and how they are interwoven in the 3D structure. But this is now simplified too much to understand the details of the structure!

One question this view does raise, is how the three separate chains are held together in the right way? The answer is the that link the chains together to form the correct overall structure.

What we really need to do next is to have a basic introduction to protein structure. The section that follows is based on the Introduction to Protein Structure Proteopedia page.

Levels of Protein Structure

Primary structure

Proteins are polymers of amino acids joined together in linear chains. There are four recognised levels of structural organisation for proteins.

The first, referred to as the , is simply the amino acid sequence, from the N terminus (start) to the C terminus (end) of the protein.

Secondary Structure

The is the local structure over short distances. This level of structure is stabilized by along the amino acid backbone. There are only two main forms of secondary structure seen in proteins: alpha helix, which forms coiled cylinders of amino acids, as shown here, and beta strands, a planar (flat) arrangement of amino acids which often line up together to from so-called beta sheets.

Tertiary Structure

These secondary structures to form the overall form of the entire peptide chain, called the .

Quaternary Structure

Some proteins, such as the hemoglobin molecule displayed here, have more than one polypeptide chain that associate to form the functional unit of the protein; this is called .

Secondary Structure in chymotrypsin

Now that we know something about the structural organisation of proteins, let's go back to our chymotrypsin molecule and have another look.

This time, we'll display a indicating the main secondary structural elements. We can see that the main structural form in chymotrypsin is the beta strand, with only a small amount of α-helix.

Colour key:

Alpha Helices, Beta Strands .

We can also see that the protein is organised into two structurally-similar domains. Each domain contains a group of beta strands arranged as anti-parallel sheets forming a circular structure known as a beta barrel. You can rotate the molecule so that you can see down through each of the two beta barrels in turn.

Finally, here's chymotrypsin with a molecule of bound in its active site. Note how the substrate fits into a pocket on the surface of the enzyme.

Proteopedia Page Contributors and Editors (what is this?)

Michael Roberts

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@@ Line 4: / Line 4: @@
-<StructureSection load='1afq' size='600' side='right' caption='Structure of bovine chymotrypsin (PDB entry [[1afq]])' scene='70/703491/Basic_representations/1'>
+<StructureSection load='1afq' size='600' side='right' caption=' ' scene='70/703491/Basic_representations/1'>
 ==Representing protein structures==
 '''Spacefill model'''
-The view on the right shows a model of chymotrypsin, an enzyme that digests proteins in the gut. This is a so-called 'spacefill' view, in which each atom is shown as a sphere. Different atoms are coloured individually: grey = carbon, red = oxygen, blue = nitrogen, ''etc''.
+The view on the right shows a model of chymotrypsin, an enzyme that digests proteins in the gut. This is a so-called <scene name='70/703491/Basic_representations/1'>'spacefill'</scene> view, in which each atom is shown as a sphere. Different atoms are coloured individually: grey = carbon, red = oxygen, blue = nitrogen, ''etc''.
 In spacefill view, we can see the overall shape of the protein, but not much else. We cant see what's going on inside, for example.
@@ Line 22: / Line 22: @@
 '''Amino acid trace'''
-Here's a much more simplified view that <scene name='70/703491/Basic_representations/3'>traces the chains</scene> of amino acids that make up the protein. Now we can see much more clearly the start and end of each chain (there are 3 chains in chymotrypsin, each coloured differently in this view), and how they are interwoven in the 3D structure. But this is now simplified too much to understand the details of the structure!
+Here's a much more simplified view that <scene name='70/703491/Basic_representations/4'>shows a trace of the backbone</scene> of the amino acids that make up the protein. Now we can see much more clearly the start and end of each chain (there are 3 chains in chymotrypsin, each coloured differently in this view), and how they are interwoven in the 3D structure. But this is now simplified too much to understand the details of the structure!
+One question this view does raise, is how the three separate chains are held together in the right way? The answer is the <scene name='70/703491/Basic_representations/5'>presence of disulphide bridges</scene> that link the chains together to form the correct overall structure.
@@ Line 52: / Line 54: @@
 == Secondary Structure in chymotrypsin ==
 Now that we know something about the structural organisation of proteins, let's go back to our chymotrypsin molecule and have another look.
 This time, we'll display a <scene name='User:Michael_Roberts/BIOL115_Chymo/2ndry_structure/1'>cartoon representation</scene> indicating the main secondary structural elements. We can see that the main structural form in chymotrypsin is the beta strand, with only a small amount of α-helix.
@@ Line 57: / Line 60: @@
 {{Template:ColorKey_Helix}},
 {{Template:ColorKey_Strand}}.
 We can also see that the protein is organised into two structurally-similar domains. Each domain contains a group of beta strands arranged as anti-parallel sheets forming a circular structure known as a beta barrel. You can rotate the molecule so that you can see down through each of the two beta barrels in turn.
+Finally, here's chymotrypsin with a molecule of <scene name='70/703491/Substrate/3'>substrate</scene> bound in its active site. Note how the substrate fits into a pocket on the surface of the enzyme.
 </StructureSection>

User:Michael Roberts/Open-Day Demo

From Proteopedia

Current revision

Interactive visualisation of 3D protein structures

Representing protein structures

Levels of Protein Structure

Secondary Structure in chymotrypsin

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