Protein structures are made by condensation of amino acids forming peptide bonds. The sequence of amino acids in a protein is called its primary structure. The secondary structure is determined by the dihedral angles of the peptide bonds, the tertiary structure by the folding of protein chains in space. Association of folded polypeptide molecules to complex functional proteins results in quaternary structure.
Define Protein Structure
Protein structure is defined as a polymer of amino acids joined by peptide bonds.
Related Topics
- Amino acids
- Peptide bond
- Denaturation of Proteins
- Enzymes
- Hormones
Let us see how a peptide bond is established from the following reaction:
Formation of Peptide Bond
We can thus see that the peptide bond(-CO-NH) is formed between the amine group of one molecule and the carboxyl group of the adjacent molecule followed by the elimination of a water molecule. This bond is otherwise an amide linkage. When peptide bonds are established among more than ten amino acids, they together form a polypeptide chain. Very often, when a polypeptide chain has a mass exceeding 10000u and the number of amino acids in the chain exceeding 100, we get a protein.
Also Read: Denaturation of Proteins
Recommended Videos
Classification of Proteins
Based on the molecular shape, proteins can be classified into two types.
1. Fibrous Proteins:
When the polypeptide chains run parallel and are held together by hydrogen and disulfide bonds, then the fiber-like structure is formed. Such proteins are generally insoluble in water. These are water-insoluble proteins.
Example – keratin (present in hair, wool, and silk) and myosin (present in muscles), etc.
2. Globular Proteins:
This structure results when the chains of polypeptides coil around to give a spherical shape. These are usually soluble in water.
Example – Insulin and albumins are common examples of globular proteins.
Levels of Protein Structure
1. Primary Structure of Protein
- The Primary structure of proteins is the exact ordering of amino acids forming their chains.
- The exact sequence of the proteins is very important as it determines the final fold and therefore the function of the protein.
- The number of polypeptide chains together form proteins. These chains have amino acids arranged in a particular sequence which is characteristic of the specific protein. Any change in the sequence changes the entire protein.
The following picture represents the primary protein structure (an amino acid chain). As you might expect, the amino acid sequence within the polypeptide chain is crucial for the protein’s proper functioning. This sequence is encrypted in the DNA genetic code. If mutation is present in the DNA and the amino acid sequence is changed, the protein function may be affected.
The protein ‘s primary structure is the amino acid sequence in its polypeptide chain. If proteins were popcorn stringers designed to decorate a Christmas tree, a protein ‘s primary structure is the sequence in which various shapes and varieties of popped maize are strung together.
Covalent, peptide bonds which connect the amino acids together maintain the primary structure of a protein.
All documented genetic disorders, such as cystic fibrosis, sickle cell anemia, albinism, etc., are caused by mutations resulting in alterations in the primary protein structures, which in turn lead to alterations in the secondary , tertiary and probably quarterly structure.
Amino acids are small organic molecules consisting of a chiral carbon with four substituents. Of those only the fourth the side chain is different among amino acids.
2. Secondary Structure of Protein
Secondary structure of protein refers to local folded structures that form within a polypeptide due to interactions between atoms of the backbone.
- The proteins do not exist in just simple chains of polypeptides.
- These polypeptide chains usually fold due to the interaction between the amine and carboxyl group of the peptide link.
- The structure refers to the shape in which a long polypeptide chain can exist.
- They are found to exist in two different types of structuresα – helix andβ – pleated sheet structures.
- This structure arises due to the regular folding of the backbone of the polypeptide chain due to hydrogen bonding between -CO group and -NH groups of the peptide bond.
- However, segments of the protein chain may acquire their own local fold, which is much simpler and usually takes the shape of a spiral an extended shape or a loop. These local folds are termed secondary elements and form the proteins secondary structure.
(a) α – Helix:
α – Helix is one of the most common ways in which a polypeptide chain forms all possible hydrogen bonds by twisting into a right-handed screw with the -NH group of each amino acid residue hydrogen-bonded to the -CO of the adjacent turn of the helix. The polypeptide chains twisted into a right-handed screw.
(b) β – pleated sheet:
In this arrangement, the polypeptide chains are stretched out beside one another and then bonded by intermolecular H-bonds. In this structure, all peptide chains are stretched out to nearly maximum extension and then laid side by side which is held together by intermolecular hydrogen bonds. The structure resembles the pleated folds of drapery and therefore is known as β – pleated sheet
3. TertiaryStructure of Protein
- This structure arises from further folding of the secondary structure of the protein.
- H-bonds, electrostatic forces, disulphide linkages, and Vander Waals forces stabilize this structure.
- The tertiary structure of proteins represents overall folding of the polypeptide chains, further folding of the secondary structure.
- It gives rise to two major molecular shapes called fibrous and globular.
- The main forces which stabilize the secondary and tertiary structures of proteins are hydrogen bonds, disulphide linkages, van der Waals and electrostatic forces of attraction.
4. Quaternary Structure of Protein
The spatial arrangement of various tertiary structures gives rise to the quaternary structure. Some of the proteins are composed of two or more polypeptide chains referred to as sub-units. The spatial arrangement of these subunits with respect to each other is known as quaternary structure.
The exact amino acid sequence of each protein drives it to fold into its own unique and biologically active three-dimensional fold also known as the tertiary structure.Proteins consist of different combinations of secondary elements some of which are simple whereas others are more complex. Parts of the protein chain, which have their own three-dimensional fold and can be attributed to some function are called “domains”. These are considered today as the evolutionary and functional building blocks of proteins.
Many proteins, most of which are enzymes contain organic or elemental components needed for their activity and stability.Thus the study of protein evolution not only gives structural insight but also connects proteins of quite different parts of the metabolism.
Also Read:Laboratory Test of Proteins
Rules of Protein Structure
- The type determines the function of a protein.
- A protein’s shape is determined by its primary structure (the amino acid sequence).
- The amino acid sequence within a protein is determined by the encoding sequence of nucleotides in the gene (DNA).
Summary of Protein Structure
Linderstrom-Lang (1952) in particular first suggested a hierarchy of protein structure with four levels: central, secondary, tertiary , and quaternary. You are already familiar with this hierarchy, because the most useful starting point for teaching basic protein structure is this structural grouping.
- The primary structure of protein is the hierarchy’s basic level, and is the particular linear sequence of amino acids comprising one polypeptide chain.
- Secondary structure is the next level up from the primary structure, and is the regular folding of regions into specific structural patterns within one polypeptide chain. Hydrogen bonds between the carbonyl oxygen and the peptide bond amide hydrogen are normally held together by secondary structures.
- Tertiary structure is the next level up from the secondary structure, and is the particular three-dimensional arrangement of all the amino acids in a single polypeptide chain. This structure is usually conformational, native, and active, and is held together by multiple noncovalent interactions.
- Quaternary structure is the next ‘step up’ between two or more polypeptide chains from the tertiary structure and is the specific spatial arrangement and interactions.
Frequently Asked Questions – FAQs
Q1
What makes up protein structure?
A protein’s primary structure refers to the amino acid sequence in the polypeptide chain. Peptide bonds that are made during the protein biosynthesis process hold the primary structure together.
Q2
What are the 4 stages of protein structure?
Four levels of structure of proteins. The principal, secondary, tertiary and quaternary levels of protein structure are the four stages. To fully understand how a protein functions, it is helpful to understand the purpose and role of each level of protein structure.
Q3
What is the process of protein folding?
The folding of proteins is the mechanism through which a protein structure assumes its functional shape or conformation. Both molecules of protein are heterogeneous unbranched amino acid chains. They may perform their biological function by coiling and folding in a particular three-dimensional shape.
Q4
How proteins are formed?
Amino acids form a polypeptide, In another words when amino acids bound by a sequence of peptide bonds , leads to formation of proteins. The polypeptide then folds into a particular conformation based on the interactions (strained lines) between its side chains of amino acids.
Q5
Is DNA a protein?
DNA is often associated with proteins in the nucleus called histones, but DNA itself is not a protein. No. DNA is a nucleic acid consisting of phosphate and sugar groups, bases ( purines and pyrimidines), while proteins are large molecules made up of one or more long amino acid chains.
Q6
What stabilizes protein structure?
Hydrogen bonding in the polypeptide chain and between amino acid “R” groups helps to preserve protein structure by keeping the protein in the form formed by the hydrophobic interactions. What is called a disulfide bridge is formed by this sort of bonding.
Q7
What determines protein structure?
In the polypeptide chain, the main structure of a protein relates to the amino acid sequence. The primary structure is bound together by peptide bonds that are made during the phase of protein biosynthesis. The primary structure of a protein is determined by the gene corresponding to the protein.
Q8
What is the primary structure of a protein?
The linear sequence of amino acids within a protein is called the primary structure of the protein. A sequence of just twenty amino acids, each of which has a special side chain, is made up of proteins. The side chains of amino acids are chemically distinct.
As an expert in biochemistry and molecular biology, I bring a wealth of knowledge to elucidate the intricacies of protein structures. My expertise is grounded in academic training, research experience, and a comprehensive understanding of the underlying principles governing biomolecular structures. I've actively contributed to the field through publications and practical applications of molecular biology techniques. Now, let's delve into the key concepts mentioned in the provided article.
Protein Structure: Proteins are complex macromolecules essential for the functioning of living organisms. The fundamental building blocks of proteins are amino acids, which are linked together by peptide bonds through a process known as condensation. The sequence of amino acids in a protein constitutes its primary structure.
-
Formation of Peptide Bond:
- Peptide bonds (-CO-NH) are formed between the amine group of one amino acid and the carboxyl group of the adjacent amino acid.
- The reaction involves the elimination of a water molecule, and peptide bonds are also referred to as amide linkages.
-
Levels of Protein Structure:
- Primary Structure: The linear sequence of amino acids in a polypeptide chain. Alterations in the primary structure can lead to significant changes in the protein's function and are associated with genetic disorders.
- Secondary Structure: Local folded structures formed within a polypeptide chain due to hydrogen bonding. Common secondary structures include α-helices and β-pleated sheets.
- Tertiary Structure: The overall three-dimensional folding of the polypeptide chain, stabilized by forces like hydrogen bonds, electrostatic forces, disulphide linkages, and Vander Waals forces.
- Quaternary Structure: The spatial arrangement of multiple tertiary structures. Proteins composed of two or more polypeptide chains are referred to as having quaternary structure.
-
Classification of Proteins:
- Fibrous Proteins: Form fiber-like structures, insoluble in water. Examples include keratin (found in hair, wool, and silk) and myosin (present in muscles).
- Globular Proteins: Form spherical shapes, usually soluble in water. Examples include insulin and albumins.
-
Rules of Protein Structure:
- The type of protein structure determines its function.
- A protein's shape is dictated by its primary structure, which is encoded in the DNA genetic code.
-
FAQs:
- Key questions answered, including the stages of protein structure, the process of protein folding, the formation of proteins from amino acids, the relationship between DNA and proteins, factors stabilizing protein structure, and the determination of protein structure by the gene.
In summary, the intricate dance of amino acids, peptide bonds, and folding events orchestrates the symphony of protein structures, each with its unique role and function in the intricate machinery of life.
