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Example Questions
Example Question #1 : Identifying Amino Acids
The conversion of tetrahydrofulate to methylene tetrahydrofulate is coupled to which amino acid conversion?
Serine to glycine
Serine to threonine
Serine to alanine
Glycine to alanine
Glutamate to glutamine
Serine to glycine
The conversion of tetrahydrofulate to methylene tetrahydrofulate is coupled with the amino acid conversion of serine to glycine. Serine converts to form glycine and formaldehyde. The same components are factored in with the conversion of tetrahydrofulate to methylene tetrahydrofulate.
Example Question #1 : Identifying Amino Acids
An unknown amino acid has been isolated from a solution. It has a charge at a pH of 12. It shows 3 equivalent points on its titration curve, and is found to have amphipathic properties. Which amino acid is this?
Glutamic acid
Tryptophan
Threonine
Tyrosine
Histidine
Tyrosine
At a pH of 12, the amino group for all of the amino acids would be deprotonated, resulting in at least a charge from the acid group. Another negative charge comes from the carboxyl group on the backbone. Tyrosine is amphipathic, and the pKa of its sidechain is 10.8, meaning it is a deprotonated at a pH of 12. This gives it a charge at a pH of 12. Tryptophan has no side-chain pKa so 3 equivalence points would not be seen. Threonine would also not have 3 equivalence points. Glutamic acid doesn't have amphipathic properties. Histidine is amphipathic, but it is a basic amino acid.
Example Question #2 : Identifying Biochemical Molecules
Which amino acid is shown above?
Phenylalanine
Leucine
Tyrosine
Valine
Glycine
Glycine
All amino acids have an amino group, a carboxyl group, a hydrogen, and an R-group that is unique to the amino acid. In this structure, the R-group is a hydrogen, which corresponds to the amino acid glycine.
Example Question #2 : Identifying Amino Acids
A protein in aqueous solution is run through a column containing negatively charged beads. A small amount of protein is found to be inside the column after the mobile phase has finished running. Which of the following amino acids is probably found in higher concentration within this small amount of protein?
Glutamic acid
Tyrosine
Lysine
Alanine
Lysine
Since this is an ion-exchange chromatography method, we expect that the protein found in the column has the opposite charge of the beads. Since the beads were negatively charged, we expect the amino acid to be positively charged. Lysine has a basic side chain that can easily pick up a hydrogen from solution and become positively charged.
Example Question #3 : Identifying Amino Acids
Suppose that a mutation occurred in the DNA region coding for a very important amino acid in the active site of an enzyme. If the original amino acid at this site before the mutation was a lysine, which of the following amino acid substitutions would likely be the least detrimental?
Glycine
Tryptophan
Valine
Glutamate
Arginine
Arginine
We're told in the question stem that a mutation is causing a single amino acid substitution. Originally, the amino acid encoded by this region was a lysine residue. To find the amino acid that would cause the least detriment to the organism, we need to recognize which amino acid is the most similar to lysine. Since lysine is a basic amino acid under physiological conditions, it will tend to carry a positive charge most of the time. Therefore, we are looking for an amino acid that is also basic and carries a positive charge under physiological conditions. Arginine is one such amino acid that meets this criteria, and thus it is the correct answer. Glutamate is incorrect because it is acidic under physiological conditions, and thus will carry a negative charge. Glycine, valine, and tryptophan are also all incorrect because each of these amino acids are neutral under physiological conditions.
Example Question #4 : Identifying Amino Acids
Which of the following amino acids have side chains capable of hydrogen bonding interactions?
I. Alanine
II. Aspartate
III. Threonine
IV. Methionine
II only
II, III, and IV
I, II, and III
II and III
III only
II and III
Only aspartate and threonine have side chains capable of hydrogen bonding interactions. Aspartate has a terminal carboxylate which can act as a hydrogen bond acceptor and as a hydrogen bond donor when protonated. Threonine has a terminal hydroxyl group which can also act as a hydrogen bond donor. Alanine has an entirely aliphatic side chain which is unable to participate in hydrogen bonding, and methionine has a sulfhydryl group, that cannot participate in hydrogen bonding.
Example Question #5 : Identifying Monomers And Dimers
Which of the following is true regarding sequencing methods?
Edman degradation allows the sequencing of an unlimited number of amino acids
High performance liquid chromatography (HPLC) can be used to separate peptides
None of these
Agarose gel electrophoresis is used to separate out individual amino acid molecules
High performance liquid chromatography (HPLC) can be used to separate peptides
Agarose gel electrophoresis is typically used for large molecules, not small ones like individual amino acids. Isoelectric focusing separates molecules by isoelectric point. Edman degradation only permits sequencing of about 30 amino acids, not an unlimited amount. High-performance liquid chromatography separates proteins which are peptide sequences.
Example Question #1 : Identifying Monomers And Dimers
Suppose that an amino acid with pI = 10.4 in acidic solution is titrated with a strong base, . What will the net charge of this amino acid be at a pH of 2, 8, and 12?
Positive, positive, neutral
Positive, negative, negative
Positive, neutral, neutral
Positive, neutral, negative
Positive, positive, negative
Positive, positive, negative
We're told in the question that this amino acid has a pI = 10.4. Therefore, we expect this to be a basic amino acid. This means that one carboxyl group, one amino group, and one basic R-group will be present.
At the start of the titration, the solution starts out acidic at a very low pH. At a pH of 2, since so many protons are in solution at this pH, all of the important functional groups under consideration will be protonated. Thus, the amino acid will have a positive charge on each of its basic functional groups, and a neutral charge on its carboxyl group, giving the amino acid a net charge of +2.
Once the pH has climbed to a value of 8, we would expect that only the carboxyl group will be deprotonated. As a result, the carboxyl group will have a negative charge, while each of the other two basic functional groups will still retain their positive charge. Thus, the amino acid at this pH will have a net charge of +1.
And finally, once the pH climbs all the way up to a value of 12, we can expect the two basic functional groups to be deprotonated. Consequently, each of the basic functional groups will be neutral, while the carboxyl group will still be negative. Thus, the overall charge of the amino acid will be negative at this pH.
So overall, the amino acid will be positive, then positive, followed by negative.
Example Question #4 : Identifying Amino Acids
Most naturally occurring amino acids exist as the L-isomer. However, there is one exception to this trend. Which amino acid defies this trend?
Valine
Glycine
Histidine
Glutamate
Tyrosine
Glycine
Most amino acids that exist in living organisms contain an alpha-carbon that is a stereocenter (or chiral center). This means that this central carbon is bonded to four different substituents, thus allowing the amino acid to have two possible isomers. Although practically all amino acids in nature occur as the L-isomer, glycine is an exception. The reason for this is that glycine's alpha-carbon is bonded to two hydrogen atoms. As a result, this alpha-carbon is not a stereocenter, which means that glycine only has one possible conformation with no isomers.
Example Question #3 : Identifying Monomers And Dimers
Which of the following amino acids does not contain a ring structure?
Histidine
Threonine
Tryptophan
Tyrosine
Phenylalanine
Threonine
Tryptophan contains a five membered ring and a six membered ring on its side group. Tyrosine and phenylalanine both contain one six membered ring. Histidine contains a five membered ring on its side chain. Threonine's R-group is , and does not have a ring structure.
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