Stabilizing interactions

The unique three-dimensional structure of each polypeptide is determined by its amino acid sequence. Interactions between the amino acid side chains guide the folding of the polypeptide to form a compact structure. The following four types of interactions cooperate in stabilizing the tertiary structures of globular proteins.
1. Disulfide bonds: A disulfide bond (–S–S–) is a covalent linkage formed from the sulfhydryl group (−SH) of each of two cysteine residues to produce a cystine residue (Fig. 1). The two cysteines may be separated from each other by many amino acids in the primary sequence of a polypeptide or may even be located on two different polypeptides. The folding of the polypeptide(s) brings the cysteine residues into proximity and permits covalent bonding of their side chains. A disulfide bond contributes to the stability of the three-dimensional shape of the protein molecule and prevents it from becoming denatured in the extracellular environment. For example, many disulfide bonds are found in proteins such as immunoglobulins that are secreted by cells. [Note: Protein disulfide isomerase breaks and reforms disulfide bonds during folding.]

Figure 1:  Formation of a disulfide bond by the oxidation of two cysteine residues, producing one cystine residue. O₂ = oxygen.

2. Hydrophobic interactions: Amino acids with nonpolar side chains tend to be located in the interior of the polypeptide molecule, where they associate with other hydrophobic amino acids (Fig. 2). In contrast, amino acids with polar or charged side chains tend to be located on the surface of the molecule in contact with the polar solvent. [Note: Recall that proteins located in nonpolar (lipid) environments, such as a membrane, exhibit the reverse arrangement .] In each case, a segregation of R groups occurs that is energetically most favorable.

Figure 2 Hydrophobic interactions between amino acids with nonpolar side chains.

3. Hydrogen bonds: Amino acid side chains containing oxygen- or nitrogen-bound hydrogen, such as in the alcohol groups of serine and threonine, can form hydrogen bonds with electron-rich atoms, such as the oxygen of a carboxyl group or carbonyl group of a peptide bond (Fig. 3 ). Formation of hydrogen bonds between polar groups on the surface of proteins and the aqueous solvent enhances the solubility of the protein.

Figure 3:  Interactions of side chains of amino acids through hydrogen bonds and ionic bonds (salt bridges).

4. Ionic interactions: Negatively charged groups, such as the carboxylate group (−COO−) in the side chain of aspartate or glutamate, can interact with positively charged groups such as the amino group (−NH3+) in the side chain of lysine (see Fig. 3).

مواضيع ذات صلة

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Platelet Plug Formation: Adhesion

Limiting Clotting : Fibrinolysis

Limiting Clotting : Inactivating proteins

Fibrin Meshwork Formation : Pathways

Fibrin Meshwork Formation : Formation of γ-carboxyglutamate residues

Fibrin Meshwork Formation :Role of phosphatidylserine and calcium

Fibrin Meshwork Formation: Proteolytic cascade

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