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Chapter 27: Problem 10

Assign an \(R\) or \(S\) configuration to the chiral center in each amino acid. (a) L-Phenylalanine (b) L-Glutamic acid (c) L-Methionine

Short Answer

Expert verified
Answer: The chiral center configurations for each amino acid are L-Phenylalanine (S), L-Glutamic acid (S), and L-Methionine (S).

Step by step solution

01

Determine the chiral centers

In each amino acid, the chiral center is the α-carbon, which is the carbon atom attached to the amino group (NH2), carboxyl group (COOH), and the side chain (R group).
02

Assign priorities to the groups around the chiral center

Using the Cahn-Ingold-Prelog priority rules, assign priorities to the groups attached to the chiral center. Number the atoms in decreasing order of priority (1 for the highest priority, 4 for the lowest priority). The priority is usually determined by atomic number, with higher atomic numbers having higher priority.
03

Arrange the lowest priority group away from the observer

Position the molecule in space so that the lowest-priority group (4) is pointing away from the observer.
04

Determine the orientation of the three remaining groups

Observe the orientation of the remaining three groups around the chiral center. If the order of priority from 1 to 3 is clockwise, the configuration is R (rectus). If the order of priority from 1 to 3 is counterclockwise, the configuration is S (sinister).
05

Assign configuration to each amino acid

(a) L-Phenylalanine: 1. Chiral center: α-carbon 2. Priorities: COOH (1) > NH2 (2) > Phenyl group (3) > H (4) 3. Arrange H away from the observer 4. Orientation: counterclockwise (sinister) Configuration: S (b) L-Glutamic acid: 1. Chiral center: α-carbon 2. Priorities: COOH (1) > NH2 (2) > CH2-COOH (3) > H (4) 3. Arrange H away from the observer 4. Orientation: counterclockwise (sinister) Configuration: S (c) L-Methionine: 1. Chiral center: α-carbon 2. Priorities: COOH (1) > NH2 (2) > CH2-CH2-S-CH3 (3) > H (4) 3. Arrange H away from the observer 4. Orientation: counterclockwise (sinister) Configuration: S In conclusion, the chiral center configurations for each amino acid are L-Phenylalanine (S), L-Glutamic acid (S), and L-Methionine (S).

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Cahn-Ingold-Prelog priority rules
The Cahn-Ingold-Prelog (CIP) priority rules are a set of guidelines used for determining the priority of substituents around a chiral center. These rules play a critical role in stereochemistry, helping us assign the correct configuration to molecules. Here's how these rules work:
  • Atomic Number: The first criterion is the atomic number. Atoms with higher atomic numbers receive higher priority. For instance, iodine would receive a higher priority than chlorine due to its higher atomic number.
  • Immediate Substituents: If two atoms attached to the chiral center have the same atomic number, look at the atoms they are bonded to. Compare their atomic numbers to establish priority.
  • Double and Triple Bonds: Double or triple bonds require special consideration. A double bond is treated as two single bonds to the same atom, while a triple bond as three.
  • Lowest Priority in the Back: When analyzing orientation, remember to position the lowest priority group facing away from you. It helps in correctly assigning R or S configuration.
By following these rules, you can systematically determine the priority of attached groups, which is essential for determining the stereochemical configuration of chiral centers in molecules.
Chiral center
A chiral center, often referred to as a stereocenter, is a carbon atom bonded to four distinct groups. This unique arrangement allows for two non-superimposable mirror images, or enantiomers, often referred to as "left-handed" and "right-handed" configurations.
  • Importance of Chiral Centers: Chiral centers are crucial in biology and chemistry because they impart distinct three-dimensional configurations that can drastically affect a molecule's behavior and interactions.
  • Determining Chiral Centers: To find a chiral center, look for carbons attached to four different atoms or groups. In amino acids, the α-carbon usually acts as the chiral center because it’s bonded to an amino group (NH2), a carboxyl group (COOH), a hydrogen atom, and a variable R group.
  • Chirality and Properties: The presence of a chiral center can impact physical properties, reactivity, and biological activity. For example, the difference in the arrangement of atoms at the chiral center can lead to molecules having different smells or tastes.
Understanding chiral centers helps in predicting the stereochemistry and potential reactivity of amino acids and other organic molecules.
Amino acid configuration
The configuration of an amino acid at its chiral center is significant as it influences the molecule's properties and its interaction within biological systems. In the step-by-step solution, amino acids like L-phenylalanine, L-glutamic acid, and L-methionine were analyzed, revealing their S configurations.
  • Alpha Carbon Configuration: Each amino acid's configuration is determined at the α-carbon, which is the central point connecting an amino group, a carboxyl group, hydrogen, and a distinct side chain (R group).
  • Assigning R or S Configuration: Using the Cahn-Ingold-Prelog priority rules, you assign priorities to four substituents, placing the lowest priority group backward. Then, determine if the sequence from highest to third-highest priority is clockwise (R) or counterclockwise (S).
  • Biological Significance: Amino acids naturally exist as L-isomers, encompassing both R and S configurations due to nature’s preference. Incorrect configuration can alter protein structure and function, emphasizing the importance of precise stereochemical configuration.
Understanding amino acid configuration is crucial for studying protein function and the molecular mechanisms of life, enabling deeper insight into biochemical processes and drug design.

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Most popular questions from this chapter

From which amino acid are serotonin and melatonin synthesized, and what types of reactions are involved in their biosynthesis? a. b.

The isoelectric point of histidine is \(7.64\). Toward which electrode does histidine migrate on paper electrophoresis at pH 7.0?

2,4-Dinitrofluorobenzene, very often known as Sanger's reagent after the English chemist Frederick Sanger who popularized its use, reacts selectively with the \(N\)-terminal amino group of a polypeptide chain. Sanger was awarded the 1958 Nobel Prize for chemistry for his work in determining the primary structure of bovine insulin. One of the few persons to be awarded two Nobel Prizes, he also shared the 1980 award in chemistry with American chemists, Paul Berg and Walter Gilbert, for the development of chemical and biological analyses of DNA. Following reaction with 2,4-dinitrofluorobenzene, all amide bonds of the polypeptide chain are hydrolyzed, and the amino acid labeled with a 2,4-dinitrophenyl group is separated by either paper or column chromatography and identified. (a) Write a structural formula for the product formed by treatment of the \(N\)-terminal amino group with Sanger's reagent and propose a mechanism for its formation. (b) When bovine insulin is treated with Sanger's reagent followed by hydrolysis of all peptide bonds, two labeled amino acids are detected: glycine and phenylalanine. What conclusions can be drawn from this information about the primary structure of bovine insulin? (c) Compare and contrast the structural information that can be obtained from use of Sanger's reagent with that from use of the Edman degradation.

A tetradecapeptide (14 amino acid residues) gives the following peptide fragments on partial hydrolysis. From this information, deduce the primary structure of this polypeptide. Fragments are grouped according to size. $$ \begin{array}{ll} \hline \text { Pentapeptide Fragments } & \text { Tetrapeptide Fragments } \\ \hline \text { Phe-Val-Asn-Gln-His } & \text { Gln-His-Leu-Gys } \\ \text { His-Leu-Cys-Gly-Ser } & \text { His-Leu-Val-Glu } \\ \text { Gly-Ser-His-Leu-Val } & \text { Leu-Val-Glu-Ala } \\ \hline \end{array} $$

Draw a structural formula for the form of each amino acid most prevalent at pH \(1.0\). (a) Threonine (b) Arginine (c) Methionine (d) Tyrosine
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