Textbook Question
Define and compare the four levels of protein organization.
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Ch. 14 - Translation and Proteins
Klug12th EditionConcepts of Genetics ISBN: 9780135564776
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Table of contents
- Ch. 1 - Introduction to Genetics17
- Ch. 2 - Mitosis and Meiosis36
- Ch. 3 - Mendelian Genetics51
- Ch. 4 - Extensions of Mendelian Genetics74
- Ch. 5 - Chromosome Mapping in Eukaryotes51
- Ch. 6 - Genetic Analysis and Mapping in Bacteria and Bacteriophages46
- Ch. 7 - Sex Determination and Sex Chromosomes33
- Ch. 8 - Chromosome Mutations: Variation in Number and Arrangement40
- Ch. 9 - Extranuclear Inheritance31
- Ch. 10 - DNA Structure and Analysis43
- Ch. 11 - DNA Replication and Recombination44
- Ch. 12 - DNA Organization in Chromosomes30
- Ch. 13 - The Genetic Code and Transcription54
- Ch. 14 - Translation and Proteins47
- Ch. 15 - Gene Mutation, DNA Repair, and Transposition41
- Ch. 16 - Regulation of Gene Expression in Bacteria29
- Ch. 17 - Transcriptional Regulation in Eukaryotes41
- Ch. 18 - Post-transcriptional Regulation in Eukaryotes33
- Ch. 19 - Epigenetics33
- Ch. 20 - Recombinant DNA Technology44
- Ch. 21 - Genomic Analysis36
- Ch. 22 - Applications of Genetic Engineering and Biotechnology36
- Ch. 23 - Developmental Genetics37
- Ch. 24 - Cancer Genetics34
- Ch. 25 - Quantitative Genetics and Multifactorial Traits54
- Ch. 26 - Population and Evolutionary Genetics45
Chapter 14, Problem 26
How do covalent disulfide bonds, hydrogen bonds with water, and hydrophobic interactions all contribute to a protein's tertiary structure?
Verified step by step guidance1
Identify the role of covalent disulfide bonds: These are strong bonds formed between the sulfur atoms of two cysteine amino acids, stabilizing the protein's structure by creating loops or links between different parts of the polypeptide chain.
Examine hydrogen bonds with water: These occur between polar side chains of amino acids and water molecules, helping to stabilize the protein's structure by maintaining its solubility and proper folding in an aqueous environment.
Consider hydrophobic interactions: Nonpolar side chains of amino acids tend to cluster together away from water, driving the folding of the protein into a compact structure by minimizing exposure of hydrophobic regions to the aqueous environment.
Understand the interplay of these interactions: The combination of disulfide bonds, hydrogen bonds, and hydrophobic interactions work together to stabilize the protein's tertiary structure, ensuring it maintains its functional three-dimensional shape.
Reflect on the importance of tertiary structure: The specific folding and interactions within a protein's tertiary structure are crucial for its biological function, as they determine the protein's active sites and interaction capabilities with other molecules.
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Key Concepts
Here are the essential concepts you must grasp in order to answer the question correctly.
Covalent Disulfide Bonds
Covalent disulfide bonds are strong linkages formed between the sulfur atoms of cysteine residues in proteins. These bonds stabilize the protein's tertiary structure by creating cross-links that help maintain the overall shape and integrity of the protein, especially in extracellular environments where conditions can be more variable.
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Hydrogen Bonds with Water
Hydrogen bonds occur when a hydrogen atom covalently bonded to an electronegative atom, like oxygen in water, interacts with another electronegative atom. In proteins, these bonds can form between polar side chains and water molecules, influencing the folding and stability of the tertiary structure by promoting interactions that help maintain the protein's conformation in an aqueous environment.
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Hydrophobic Interactions
Hydrophobic interactions arise when nonpolar side chains of amino acids aggregate to avoid contact with water, leading to a more stable protein structure. This phenomenon drives the folding of proteins, as hydrophobic regions tend to cluster inward, away from the aqueous environment, while polar regions remain on the surface, contributing to the overall stability and functionality of the protein.
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Related Practice
Textbook Question
Several amino acid substitutions in the α and β chains of human hemoglobin are shown in the following table.
Using the code table, determine how many of them can occur as a result of a single-nucleotide change.
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Textbook Question
Why are misfolded proteins a potential problem for the eukaryotic cell, and how do cells combat the accumulation of misfolded proteins?
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Textbook Question
List three different types of posttranslational modifications that may happen to a protein and the significance of each in the context of protein function.
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Textbook Question
What are the two common types of protein secondary structure, and how do they differ?
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Textbook Question
List as many different categories of protein functions as you can. Wherever possible, give an example of each category.
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