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molecules composed of more than 10–20 residues are often called polypeptides. Consequently, a protein molecule is often called a polypeptide also.

      Proteins are large molecules, composed of ~50–2000 amino acid residues, but the peptide illustrated in Figure 2.18b, composed of five residues, shows the key features of the primary bonds in the chain backbone and examples of side groups attached to the chain backbone. The sequence of the amino acid residues in the chain backbone is called the primary structure of the protein. This primary structure dictates the higher‐order structure of proteins.

      2.6.2 Secondary Structure

      The term secondary structure describes the geometry of the long‐chain backbone of the individual protein macromolecule. This geometry can consist of randomly coiled chain along with regions composed of a regular repeating pattern. It is strongly influenced by two key factors

       The stereochemistry of the amide bond

       Hydrogen bonding between the oxygen atom of the carbonyl (C=O) group and the hydrogen atom of the amino (N–H) group in the chain backbone.

      Stereochemistry of the Amide Bond

Schematic illustration of the stereochemistry of the amide bond. (a) Resonance of the carbonyl (C=O) double bond, resulting in partial double bond character of the amine (N–H) bond. (b) Planar geometry of amide bond.

      Hydrogen Bonding

      Due to electronegativity differences between the atoms (Section 2.4), the carbonyl C=O and amino N–H bonds are polarized. Thus, the O and H atoms in these bonds have a partial negative ( δ ) and positive charge ( δ +), respectively. As the O atom also has lone pair electrons, this leads to hydrogen bonding between the O and H atoms of different amide groups that can occur within a chain (intrachain bonding) and between neighboring chains (interchain bonding). Hydrogen bonding is an important feature of both the secondary and higher order structures of proteins but the way it occurs within the chain controls the secondary structure.

      While the overall conformation of a protein is complex and unique, a feature of the chains themselves is that they often contain regions with two regular repeating patterns called the α‐helix and the β‐sheet. These two structures result from hydrogen bonding between the O atoms of the C=O group and the H atoms of the N–H group of the amide bond in the chain backbone, without involving the side chains.

Schematic illustration of (a) alpha -helix structure generated by intrachain hydrogen bonding in polypeptides, and (b) geometrical parameters of alpha -helix. The side groups point outward from the chain. Schematic illustration of beta -sheet structure generated by layering of polypeptide chains and hydrogen bonding between the chains: (a) parallel beta -sheet, (b) antiparallel beta -sheet, and (c) beta -turn in antiparallel beta -sheet.

      In forming an antiparallel β‐sheet, the chain backbone of the protein changes its direction, turning back and forth upon itself, making what is described as a β‐turn. This is an important feature of protein folding, which gives a more compact shape. A hydrogen bond between the first and third peptide residues of the β‐turn and the amino acid proline are frequently found at bends in the chain backbone (Figure 2.21c). Of the 20 α‐amino acids (Figure 2.17), proline is the only one in which the side chain is connected to the chain backbone twice, forming a five‐membered nitrogen‐containing ring. Because ring structures typically have limited flexibility, proline is unable to occupy many of the main‐chain conformations easily adopted by other amino acids. Proline is also nonpolar and, thus, cannot take part in hydrogen bonding. Together, these factors make proline a useful residue for occupying tight turns in a protein structure such as the β‐turn.

      2.6.3 Tertiary Structure

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