Polypeptide chains in proteins fold to attain a more compact secondary structure. The two forms of secondary structures are alpha helices and beta sheets. Amino acids that are separated by three or four residues in a polypeptide chain within a secondary alpha helix structure are spatially close and can form hydrogen bonds.

Proline is bound to two alkyl groups thus giving it a planar configuration, giving the nitrogen only the ability to accept hydrogen bonds not donate them. While this is not a problem at the beginning of an alpha helix this can disturb the bonds if place further down the chain. Thus proline is often referred to as the "alpha helix buster."

Beta bends are part of secondary protein structures. They serve as a link between alpha helices and beta sheets. Beta bends are composed of proline and glycine, amino acids that usually are not found in alpha helices.

Covalent bonding is when two nonmetals share electrons in order to form a bond. This type of bonding can be observed in the primary (peptide bonds), tertiary (disulfide bonds), and quaternary (disulfide bonds) levels of protein structure. The secondary structure of proteins only uses hydrogen bonding as the folding force.

Proline is necessary for the beta bend (along with a glycine). This beta bend is needed for the polypeptide to turn 180 degrees and come back to form a parallel beta sheet. Proline disrupts the hydrogen bonding of alpha helices, and is not needed for antiparallel beta sheets, since there is no beta turn required.

Hydrogen bonds stabilize interactions among the amide and carboxyl groups in the main chain of the polypeptide. These interactions may induce the formation of alpha-helices and/or beta-pleated sheets.

Motifs are supersecondary protein structures. Motifs are combinations of secondary structures such as alpha helices and beta sheets.The beta-alpha-beta and the beta hairpin motifs are some of the most common.

Alpha helices and beta sheet, the dominant secondary structural motifs in polypeptides are formed by hydrogen bonds between the carbonyl and amino groups of the amino acid backbone.

Alpha helices and beta pleated sheets are two forms of secondary structure. Alpha helices can be either right handed (counterclockwise) or left handed (clockwise). Beta pleated sheets can be either parallel (amino and carbonyl groups do not line up) or anti parallel (amino and carbonyl groups line up).

Within an alpha helix, the structure is stabilized by hydrogen bonding between the lone pair on a carbonyl oxygen to a hydrogen of an amino backbone group. Remember, hydrogen bonding must occur between a lone pair of an electronegative atom and a hydrogen connected to an electronegative atom. Two of the answer choices suggest that the hydrogen bonding occurs between two hydrogen atoms, which is not possible.

Finally, the alpha helix contains 3.6 residues per turn. As such, the correct answer is "Lone pair on C=O of residue i to hydrogen on N-H of residue i+4."