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Example Questions
Example Question #71 : Biochemistry
What is the hydrogen bonding pattern within an alpha helix?
Lone pair on C=O of residue i to hydrogen on N-H of residue i+3.
Hydrogen of N-H of residue i to hydrogen on N-H of residue i+4.
Lone pair on C=O of residue i to hydrogen on N-H of residue i+4.
Lone pair on C=O of residue i to hydrogen on N-H of residue i+2.
Hydrogen of N-H of residue i to hydrogen on N-H of residue i+3.
Lone pair on C=O of residue i to hydrogen on N-H of residue i+4.
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."
Example Question #72 : Biochemistry
Which of the following choices correctly describes the relative orientation of side chains within an alpha helix?
The side chains point "out" and "back" relative to the turns of the helix.
None of these
The side chains point "in" and "forward" relative to the turns of the helix.
The side chains point "out" and "forward" relative to the turns of the helix.
The side chains point "in" and "back" relative to the turns of the helix.
The side chains point "out" and "back" relative to the turns of the helix.
The side chains of the amino acid residues within an alpha helix point "out" and "back" relative to the turns of the helix. Despite differing polarity's of side chains, this pattern holds true. This first reason this pattern is important is in order to minimize steric hindrance. Finally, this pattern allows for a maximization of hydrogen bonding between the side chains and the backbone amides.
Example Question #73 : Biochemistry
Which of the following best describes how the large and branched side chains are organized within a beta-sheet?
They alternate every other residue.
They organize parallel to each other in consecutive polypeptide chains.
None of these
They are kept far apart from each other.
They are kept near each other.
They are kept far apart from each other.
Large side chains have increased Van der Waals interactions repelling each other, which is unfavorable. To minimize this steric clash, these residues must be kept far apart, and "They are kept far apart from each other." is the correct answer.
Large residues being near each other in a beta sheet would be very unfavorable. If these large residues alternated in a "every other" manner, they would still be relatively close to each other. Finally, if these residues were kept parallel to each other, they would be on different. But these chains would still be in close proximity to each other, and unfavorable interactions would occur.
Example Question #74 : Biochemistry
What is percent composition of alpha helix, beta sheet, and irregular structure within a typical protein?
Alpa helix: 25%
Beta sheet: 50%
Irregular structure: 25%
Alpa helix: 33%
Beta sheet: 33%
Irregular structure: 33%
Alpa helix: 49.5%
Beta sheet: 49.5%
Irregular structure: 1%
Alpa helix: 25%
Beta sheet: 25%
Irregular structure: 50%
Alpa helix: 50%
Beta sheet: 25%
Irregular structure: 25%
Alpa helix: 33%
Beta sheet: 33%
Irregular structure: 33%
The two most common secondary structures within a protein are alpha helixes, and beta-sheets. However, remember that there are multiple types of alpha helixes and beta-sheets, and all have slightly different properties. Overall, alpha helixes and beta sheets are in approximately equal amounts.
Anything not regarded as an alpha helix or a beta sheet is typically referred to as a "irregular structure". This can include random coil, coil structures, Beta-hairpin turns, in addition to a seemingly infinite number of unnamed structures. Overall, there is as much irregular structure as beta sheet and alpha helix within a protein, and the correct answer is 33% for all three.
Example Question #65 : Macromolecule Structures And Functions
Referring to the secondary structure of proteins, proline is necessary for which of the following?
For proper polypeptide chain subunit interactions
For the beta bend of antiparallel beta sheets
For hydrogen bonding interactions in alpha helices
The beta bend needed for parallel beta sheet secondary structures
For the hydrogen bonding, stabilizing antiparallel beta sheet
The beta bend needed for parallel beta sheet secondary structures
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.
Example Question #66 : Macromolecule Structures And Functions
How many amino acids are per turn in an alpha helix secondary structure?
1.8
10.4
7.2
0.4
3.6
3.6
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.
Example Question #81 : Biochemistry
The alpha helix is a type of secondary protein conformation. Which of the following amino acids can interfere the most with the formation of an alpha helix?
Lysine
Threonine
Arginine
Proline
Histidine
Proline
Secondary structures in proteins consist of alpha helices and beta sheets. Proline has an additional amino group that interferes with the formation of an alpha helix. Amino acids such as lysine and arginine can form ionic bonds due to their charges. Other amino acids, like isoleucine, tryptophan, or valine disrupt the helix due to big side chains. However, amongst the amino acid mentioned in the answers, proline has the most disruptive effect.
Example Question #82 : Biochemistry
Which of the following are true of beta bends in protein structures?
I. Beta bends are secondary protein structures.
II. Beta bends consist of sequences of four amino acids.
III. In beta bends amino acids proline and glycine are common.
IV. Hydrogen and ionic bonds stabilize beta bends.
II and III
I, II, and IV
I and IV
I, II, and III
I, II, III, and IV
I, II, III, and IV
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.
Example Question #83 : Biochemistry
Which of the following statements are true about motifs in a protein structure?
I. The most common motif is beta-alpha-beta, when an alpha helix connects two parallel strands of a beta sheet.
II. Motifs are usually composed of more than one form of secondary structure.
III. Motifs are supersecondary structures.
IV. Motifs are combinations of alpha helices and beta sheets.
I, II, III, and IV
III and IV
I and II
III only
I, II, and III
I, II, III, and IV
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.
Example Question #21 : Secondary Structure
Which of the following are true of beta sheet structures in a protein?
I. Beta sheets are formed by one or multiple polypeptide chains.
II. Beta sheets are secondary structures in proteins.
III. In a beta sheet, polypeptide strands can be parallel or antiparallel.
IV. In beta sheets hydrogen bonds connect polypeptide chains.
I and II
III and IV
I, II, III, and IV
I, II, and III
II and III
I, II, III, and IV
A beta sheet (a secondary structure) has parallel strands when the N-terminal and C-terminal are in the same orientation for all the strands. When the orientation alternates between beta strands they are considered to be anti-parallel. Hydrogen bonds stabilize the structure between polypeptide strands.
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