StudySmarter: Study help & AI tools
4.5 • +22k Ratings
More than 22 Million Downloads
Free
Proteins are biological molecules with complex structures built of amino acids. Based on the sequence of these amino acids and the complexity of the structures, we can differentiate four protein structures: primary, secondary, tertiary, and quaternary.
Explore our app and discover over 50 million learning materials for free.
Lerne mit deinen Freunden und bleibe auf dem richtigen Kurs mit deinen persönlichen Lernstatistiken
Jetzt kostenlos anmeldenNie wieder prokastinieren mit unseren Lernerinnerungen.
Jetzt kostenlos anmeldenProteins are biological molecules with complex structures built of amino acids. Based on the sequence of these amino acids and the complexity of the structures, we can differentiate four protein structures: primary, secondary, tertiary, and quaternary.
In the article Proteins, we have already introduced amino acids, these vital biological molecules. However, why not repeat what we already know to better understand the four structures of proteins? It is, after all, said that repetition is the mother of all learning.
Amino acids are organic compounds that are composed of the central carbon atom, or the α-carbon (alpha-carbon), an amino group (), a carboxyl group (-COOH), a hydrogen atom (-H) and an R side group, unique to each amino acid.
Amino acids are linked with peptide bonds during a chemical reaction called condensation, forming peptide chains. With more than 50 amino acids joined together, a long chain called a polypeptide chain (or a polypeptide) is formed. Have a look at the figure below and notice the structure of amino acids.
With our knowledge refreshed, let’s see what the four structures are all about.
The primary protein structure is the sequence of amino acids in a polypeptide chain. This sequence is determined by the DNA, more precisely by specific genes. This sequence is essential because it affects both the shape and the function of proteins. If only one amino acid in the sequence is changed, the shape of the protein changes. Moreover, if you remember that the shape of biological molecules affects their functions, you can conclude that the shape of proteins also changes their function. You can read more about the importance of DNA in creating a specific sequence of amino acids in our article on protein synthesis.
The secondary protein structure refers to the polypeptide chain from the primary structure twisting and folding in a certain way. The degree of the fold is specific to each protein.
The chain, or parts of the chain, can form two different shapes:
Proteins may have only an alpha-helix, only a beta-pleated sheet, or a mix of both. These folds in the chain will happen when hydrogen bonds form between amino acids. These bonds provide stability. They form between a positively charged hydrogen atom (H) of the amino group -NH2 of one amino acid and a negatively charged oxygen (O) of the carboxyl group (-COOH) of another amino acid.
Suppose you have gone through our article on biological molecules, covering different bonds in biological molecules. In that case, you will remember that hydrogen bonds are weak on their own, but provide strength to molecules when in large quantities. Still, they are easily broken.
In the secondary structure, we have seen that parts of the polypeptide chain twist and fold. If the chain twists and folds even further, the whole molecule gets a specific globular shape. Imagine you took the folded secondary structure and twisted it further so that it starts folding into a ball. This is the tertiary protein structure.
The tertiary structure is the overall three-dimensional structure of proteins. It is another level of complexity. You can say that the protein structure has “levelled up” in complexity.
In the tertiary structure (and in the quaternary, as we will see later), a non-protein group (prosthetic group) called a haem group or haem can be connected to the chains. You might come across the alternative spelling of heme, which is US English. The haem group serves as a “helper molecule” in chemical reactions.
As the tertiary structure is formed, bonds other than peptide bonds form between amino acids. These bonds determine the shape and stability of the tertiary protein structure.
Quaternary protein structure refers to an even more complex structure consisting of more than one polypeptide chain. Each chain has its own primary, secondary, and tertiary structures and is referred to as a subunit in the quaternary structure. Hydrogen, ionic, and disulfide bonds are present here as well, holding the chains together. You can learn more about the difference between tertiary and quaternary structures by looking at haemoglobin, which we will explain below.
Let’s look at the structure of haemoglobin, one of the essential proteins in our bodies. Haemoglobin is a globular protein that transfers oxygen from the lungs to cells, giving the blood its red colour.
Its quaternary structure has four polypeptide chains interlinked with the chemical bonds mentioned. The chains are called alpha and beta subunits. Alpha chains are identical to one another, and so are the beta chains (but are different from alpha chains). Connected to these four chains is the haem group that contains the iron ion to which oxygen binds. Take a look at the figures below for a better understanding.
Don’t confuse alpha and beta units with the secondary structure’s alpha-helix and beta sheets. Alpha and beta units are the tertiary structure, which is the secondary structure folded into a 3-D shape. This means that alpha and beta units contain parts of the chains folded in the shapes of alpha-helix and beta sheets.
When asked about the importance of protein structure, remember that the three-dimensional shape affects protein function. It gives each protein a specific outline, which is important because proteins need to recognise and be recognised by, other molecules to interact.
Remember fibrous, globular, and membrane proteins? Carrier proteins, one type of membrane protein, usually carry only one type of molecule, which bind to their “binding site”. For instance, glucose transporter 1 (GLUT1) carries glucose through the plasma membrane (the cell surface membrane). If its native structure were to change, its effectiveness to bind glucose would decrease or be lost entirely.
Moreover, even though the 3-D structure does indeed determine the function of proteins, the 3-D structure itself is determined by the sequence of amino acids (the primary structure of proteins).
You might ask yourself: why does a seemingly simple structure play such a vital role in the shape and function of some rather complex ones? If you remember reading about the primary structure (scroll back up in case you’ve missed it), you know that the protein’s whole structure and function would change should only one amino acid be omitted or swapped for another. This is because all proteins are “coded”, meaning they will function properly only if their constituents (or units) are all present and all fitting or that their “code” is correct. The 3-D structure is, after all, many amino acids joined together.
Imagine you are building a train, and you need specific parts so that your carriages link to a perfect sequence. If you use the wrong type or do not use enough parts, the carriages would not link up correctly, and the train would work less effectively or derail altogether. If that example is way out of your expertise, as you might not be building a train at the moment, think of using hashtags on social media. You know you need to put the # first, followed by a set of letters, with no space between the # and the letters. For instance, #lovebiology or #proteinstructure. Miss one letter, and the hashtag wouldn’t work exactly how you want it to.
The four types of protein structure are primary, secondary, tertiary and quaternary.
The primary structure of a protein is the sequence of amino acids in a polypeptide chain.
The difference is that the primary protein structure is the sequence of amino acids in a polypeptide chain, while the secondary structure is this chain twisted and folded in a certain way. Parts of the chains can form two shapes: α-helix or β-pleated sheet.
There are peptide bonds between amino acids in the primary protein structure, while in the secondary structure, there is another type of bond: hydrogen bonds. These form between positively charged hydrogen atoms (H) and negatively charged oxygen atoms (O) of different amino acids. They provide stability.
Quaternary protein structure refers to a complex structure consisting of more than one polypeptide chain. Each chain has its own primary, secondary, and tertiary structures and is referred to as a subunit in the quaternary structure.
The secondary and tertiary structures of proteins are determined by the sequence of amino acids (the primary structure of proteins). This is because the protein's whole structure and function would change should only one amino acid be omitted or swapped in the primary structure.
The first learning app that truly has everything you need to ace your exams in one place
Sign up to highlight and take notes. It’s 100% free.
Save explanations to your personalised space and access them anytime, anywhere!
Sign up with Email Sign up with AppleBy signing up, you agree to the Terms and Conditions and the Privacy Policy of StudySmarter.
Already have an account? Log in