Name: Oxidation and Reduction of Organic Molecules
Uploaded: 2022-05-06T13:56:13-04:00
Duration: 1 min 19 s
Description: Energy production within a cell involves many coordinated chemical pathways. Most of these pathways are combinations of oxidation and reduction reactions, which occur at the same time.

Chapter 3: Energy and Catalysis Back To Chapter

3.10: Oxidation and Reduction of Organic Molecules

TABLE OF
CONTENTS

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Chapter 1: Cells, Genomes, and Evolution

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1.1: What are Cells?
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1.2: The Tree of Life - Bacteria, Archaea, and Eukaryotes
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1.3: Prokaryotic Cells
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1.4: Eukaryotic Compartmentalization
30
1.5: Eukaryotic Evolution
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1.6: Animal and Plant Cell Structure
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1.7: Cytoplasm
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1.8: The Nucleus
30
1.9: The DNA Helix
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1.10: The Central Dogma
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1.11: Mutations
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1.12: Genome Size and the Evolution of New Genes
30
1.13: Gene Families
30
1.14: Gene Evolution - Fast or Slow?
30
1.15: Types of Genetic Transfer Between Organisms

Chapter 2: Biochemistry of the Cell

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2.1: The Periodic Table and Organismal Elements
30
2.2: Functional Groups
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2.3: Types of Chemical Bonds
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2.4: Noncovalent Attractions in Biomolecules
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2.5: Polymers
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2.6: What are Lipids?
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2.7: Structure of Lipids
30
2.8: Chemistry of Carbohydrates
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2.9: Nucleic Acids
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2.10: Protein and Protein Structures
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2.11: pH Regulation in Cells
30
2.12: Chemistry of the Cell

Chapter 3: Energy and Catalysis

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3.1: The First Law of Thermodynamics
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3.2: The Second Law of Thermodynamics
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3.3: Enthalpy within the Cell
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3.4: Entropy within the Cell
30
3.5: An Introduction to Free Energy
30
3.6: Endergonic and Exergonic Reactions in the Cell
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3.7: The Equilibrium Binding Constant and Binding Strength
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3.8: Free Energy and Equilibrium
30
3.9: Non-equilibrium in the Cell
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3.10: Oxidation and Reduction of Organic Molecules
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3.11: Introduction to Enzymes
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3.12: Enzymes and Activation Energy
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3.13: Introduction to Enzyme Kinetics
30
3.14: Turnover Number and Catalytic Efficiency
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3.15: Catalytically Perfect Enzymes
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3.16: Introduction to Mechanisms of Enzyme Catalysis
30
3.17: Ligand Binding and Linkage
30
3.18: Cooperative Allosteric Transitions
30
3.19: Ribozymes
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3.20: ATP Energy Storage and Release
30
3.21: ATP and Macromolecule Synthesis
30
3.22: Coupled Reactions

Chapter 4: Introduction to Metabolism

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4.1: Overview of Metabolism
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4.2: Carbohydrate Metabolism
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4.3: Glycolysis: Preparatory Phase
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4.4: Glycolysis: Pay-off Phase
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4.5: Fates of Pyruvate
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4.6: Role of Reduced Coenzymes NADH and FADH₂
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4.7: Overview of Nitrogen Metabolism
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4.8: Overview of Fatty Acid Metabolism
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4.9: Sugars as Energy Storage Molecules
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4.10: Fats as Energy Storage Molecules
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4.11: Regulation of Metabolism
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4.12: Positive and Negative Feedback Loops

Chapter 5: Protein Structure

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5.1: What are Proteins?
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5.2: Protein Organization
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5.3: Protein Folding
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5.4: Protein Families
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5.5: Conservation of Protein Domains
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5.6: Globular and Fibrous Proteins
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5.7: Intrinsically Disordered Proteins
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5.8: Protein Complex Assembly
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5.9: Conjugated Proteins
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5.10: Amyloid Fibrils

Chapter 6: Protein Function

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6.1: Ligand Binding Sites
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6.2: Protein-Protein Interfaces
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6.3: Conserved Binding Sites
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6.4: Cofactors and Coenzymes
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6.5: Cooperative Allosteric Transitions
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6.6: Protein Kinases and Phosphatases
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6.7: GTPases and their Regulation
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6.8: Covalently Linked Protein Regulators
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6.9: Protein Complexes with Interchangeable Parts
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6.10: Mechanical Protein Function
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6.11: Structural Protein Function
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6.12: Protein Networks

Chapter 7: Structure and Organization of DNA

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7.1: DNA as a Genetic Template
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7.2: Structure of a Gene
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7.3: Chromosome Structure
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7.4: The Nucleosome
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7.5: Chromatin Packaging
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7.6: Euchromatin
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7.7: Heterochromatin
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7.8: Histone Modification
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7.9: Lampbrush Chromosomes
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7.10: Polytene Chromosomes

Chapter 8: DNA Replication and Repair

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8.1: Base-pairing and DNA Repair
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8.2: The DNA Replication Fork
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8.3: Lagging Strand Synthesis
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8.4: The Replisome
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8.5: Proofreading
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8.6: Replication in Prokaryotes
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8.7: Replication in Eukaryotes
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8.8: Telomeres and Telomerase
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8.9: Overview of DNA Repair
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8.10: Base Excision Repair
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8.11: Nucleotide Excision Repair
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8.12: Mismatch Repair
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8.13: Fixing Double-strand Breaks
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8.14: Homologous Recombination
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8.15: Gene Conversion
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8.16: DNA Damage Can Stall the Cell Cycle
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8.17: Restarting Stalled Replication Forks

Chapter 9: Transcription: DNA to RNA

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9.1: What is Gene Expression?
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9.2: RNA Structure
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9.3: Types of RNA
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9.4: Transcription
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9.5: Bacterial RNA Polymerase
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9.6: Eukaryotic RNA Polymerases
30
9.7: General Transcription Factors
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9.8: RNA Polymerase II Accessory Proteins
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9.9: Transcription Elongation Factors
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9.10: Pre-mRNA Processing: Modification of pre-mRNA Ends
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9.11: Pre-mRNA Processing: RNA Splicing
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9.12: Chromatin Structure and RNA Splicing
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9.13: Alternative RNA Splicing
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9.14: Nuclear Export of mRNA
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9.15: Transfer RNA Synthesis
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9.16: Ribosomal RNA Synthesis
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9.17: The Nucleolus
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9.18: Additional Subnuclear Structures

Chapter 10: Translation: RNA to Protein

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10.1: Translation
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10.2: Ribosomes
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10.3: tRNA Activation
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10.4: Initiation of Translation
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10.5: Termination of Translation
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10.6: Improving Translational Accuracy
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10.7: Nonsense-mediated mRNA Decay
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10.8: Molecular Chaperones and Protein Folding
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10.9: The Proteasome
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10.10: Regulated Protein Degradation
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10.11: Proteins: From Genes to Degradation

Chapter 11: Control of Gene Expression

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11.1: Cell Specific Gene Expression
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11.2: Regulation of Expression Occurs at Multiple Steps
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11.3: Cis-regulatory Sequences
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11.4: Cooperative Binding of Transcription Regulators
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11.5: Prokaryotic Transcriptional Activators and Repressors
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11.6: The Eukaryotic Promoter Region
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11.7: Co-activators and Co-repressors
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11.8: Master Transcription Regulators
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11.9: Regulated mRNA Transport
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11.10: mRNA Stability and Gene Expression
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11.11: MicroRNAs
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11.12: Small interfering RNAs (siRNA)
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11.13: lncRNA - Long Non-coding RNAs
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11.14: Epigenetic Regulation

Chapter 12: Membrane Structure and Components

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12.1: What are Membranes?
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12.2: Membrane Fluidity
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12.3: Fluid Mosaic Model
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12.4: Membrane Lipids
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12.5: Asymmetric Lipid Bilayer
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12.6: Membrane Asymmetry Regulating Transporters
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12.7: Membrane Carbohydrates
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12.8: Membrane Proteins
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12.9: Lipids as Anchors
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12.10: Single-pass Transmembrane Proteins
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12.11: Multi-pass Transmembrane Proteins and β-barrels
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12.12: Detergent Purification of Membrane Proteins
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12.13: Protein Diffusion in the Membrane
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12.14: Membrane Domains
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12.15: Mechanisms of Membrane Domain Formation
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12.16: Mechanisms of Membrane-bending

Chapter 13: Membrane Transport and Active Transporters

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13.1: The Significance of Membrane Transport
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13.2: Membrane Transporters
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13.3: Facilitated Transport
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13.4: Primary Active Transport
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13.5: ATP Driven Pumps I: An Overview
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13.6: ATP Driven Pumps II: P-type Pumps
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13.7: ATP Driven Pumps III: V-type Pumps
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13.8: ABC Transporters: Exporter
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13.9: ABC Transporters: Importer
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13.10: Glucose Transporters
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13.11: Secondary Active Transport
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13.12: Transcellular Transport of Solutes
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13.13: Glucose Absorption Into the Small Intestine
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13.14: Stomach pH Regulation

Chapter 14: Channels and the Electrical Properties of Membranes

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14.1: Aquaporins
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14.2: Non-gated Ion Channels
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14.3: Ligand-gated Ion Channels
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14.4: Voltage-gated Ion Channels
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14.5: Mechanically-gated Ion Channels
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14.6: Neuron Structure
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14.7: Resting Membrane Potential
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14.8: Resting Potential Decay
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14.9: Action Potential
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14.10: Channel Rhodopsins
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14.11: Patch Clamp
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14.12: Electrical Synapses
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14.13: Chemical Synapses
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14.14: Excitatory and Inhibitory Effects of Neurotransmitters
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14.15: Muscle Contraction
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14.16: The Role of Ion Channels in Neuronal Computation
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14.17: Long-term Potentiation
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14.18: Long-term Depression

Chapter 15: Transmembrane Transport in Endoplasmic Reticulum and Peroxisomes

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15.1: The Endoplasmic Reticulum
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15.2: Smooth Endoplasmic Reticulum
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15.3: Role of ER in the Secretory Pathway
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15.4: Directing Proteins to the Rough Endoplasmic Reticulum
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15.5: Protein Translocation Machinery on the ER Membrane
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15.6: Cotranslational Protein Translocation
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15.7: Post-translational Translocation of Proteins to the RER
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15.8: Insertion of Single-pass Transmembrane Proteins in the RER
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15.9: Insertion of Multi-pass Transmembrane Proteins in the RER
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15.10: Tail-anchoring of Proteins in the ER Membrane
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15.11: GPI Anchoring of Proteins in the ER Membrane
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15.12: Protein Modifications in the RER
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15.13: Protein Folding Quality Check in the RER
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15.14: Export of Misfolded Proteins out of the ER
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15.15: The Unfolded Protein Response
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15.16: Regulation of the Unfolded Protein Response
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15.17: Synthesis of Phosphatidylcholine in the ER Membrane
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15.18: Assembly of the Lipid Bilayer in the ER
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15.19: Peroxisomes
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15.20: Protein Import into the Peroxisomes

Chapter 16: Intracellular Compartments and Protein Sorting

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16.1: Overview of Protein Sorting and Transport
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16.2: Signal Sequences and Sorting Receptors
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16.3: Nuclear Protein Sorting
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16.4: Nuclear Localization Signals and Import
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16.5: Nuclear Export
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16.6: Directionality of Nuclear Transport
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16.7: Regulation of Nuclear Protein Sorting
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16.8: Mitochondrial Protein Sorting
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16.9: Mitochondrial Precursor Proteins
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16.10: Translocation of Proteins into the Mitochondria
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16.11: Energy to Drive Translocation
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16.12: Structure of Porins
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16.13: Porin Insertion in the Outer Mitochondrial Membrane
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16.14: Protein Transport into the Inner Mitochondrial Membrane
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16.15: Protein Transport to the Thylakoids
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16.16: Protein Transport to the Stroma
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16.17: Protein Transport to the Outer Chloroplast Membrane
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16.18: Protein Transport to the Inner Chloroplast Membrane

Chapter 17: Intracellular Membrane Traffic

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17.1: Introduction to Membrane Traffic
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17.2: COP Coated Vesicles
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17.3: Clathrin Coated Vesicles
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17.4: Phosphoinositides and PIPs
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17.5: Coat Assembly and GTPases
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17.6: Pinching-off of Coated Vesicles
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17.7: Rab Proteins
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17.8: Rab Cascades
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17.9: SNAREs and Membrane Fusion
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17.10: Vesicular Tubular Clusters
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17.11: ER Retrieval Pathway
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17.12: Golgi Apparatus
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17.13: Protein Glycosylation
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17.14: Proteoglycans
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17.15: Oligosaccharide Assembly
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17.16: Golgi Matrix Proteins
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17.17: Transport Across the Golgi
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17.18: Lysosomes
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17.19: Delivery Pathways to the Lysosome
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17.20: Autophagy
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17.21: Lysosomal Hydrolases

Chapter 18: Endocytosis and Exocytosis

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18.1: Endocytosis
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18.2: Phagocytosis
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18.3: Pinocytosis
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18.4: Receptor-mediated Endocytosis
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18.5: The Early Endosome: Endocytosis of Transferrin
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18.6: Maturation of Endosomes
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18.7: Intralumenal Vesicles and Multivesicular Bodies
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18.8: Receptor Downregulation in MVBs
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18.9: Overview of Exosomes
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18.10: Recycling Endosomes and Transcytosis
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18.11: Transcytosis of IgG
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18.12: Exocytosis
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18.13: Overview of Secretory Vesicles
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18.14: Insulin Secretory Vesicles
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18.15: Fusion of Secretory Vesicles with the Plasma Membrane
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18.16: Enlargement of the Plasma Membrane
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18.17: Synaptic Signaling

Chapter 19: Mitochondria and Energy Production

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19.1: Mitochondria
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19.2: Mitochondrial Membranes
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19.3: The Inner Mitochondrial Membrane
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19.4: The Citric Acid Cycle: Overview
30
19.5: The Citric Acid Cycle: Output
30
19.6: Electron Transport Chain: Complex I and II
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19.7: Electron Transport Chain: Complex III and IV
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19.8: The Electron Transport Chain
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19.9: The Supercomplexes in the Crista Membrane
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19.10: ATP Synthase: Structure
30
19.11: ATP Synthase: Mechanism
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19.12: The ADP/ATP Carrier Protein

Chapter 20: Chloroplasts and Photosynthesis

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20.1: What is Photosynthesis?
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20.2: The Anatomy of Chloroplasts
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20.3: Photosystems
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20.4: The Photochemical Reaction Center
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20.5: The Antenna Complex
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20.6: The Z-Scheme of Electron Transport in Photosynthesis
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20.7: The Calvin Benson Cycle

Chapter 21: Principles of Cell Signaling

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21.1: Overview of Cell Signaling
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21.2: Types of Signaling Molecules
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21.3: Types of Receptors: Cell Surface Receptors
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21.4: Types of Receptors: Internal Receptors
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21.5: Assembly of Signaling Complexes
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21.6: Interactions Between Signaling Pathways
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21.7: Amplifying Signals via Second Messengers
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21.8: Amplifying Signals via Enzymatic Cascade
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21.9: Diversity in Cell Signaling Responses
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21.10: Cell Signaling Feedback Loops
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21.11: Cell Signaling in Plants
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21.12: Plant Hormones

Chapter 22: Signaling Networks of G Protein-coupled Receptors

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22.1: G Protein-coupled Receptors
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22.2: Activation and Inactivation of G Proteins
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22.3: GPCR Desensitization
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22.4: G-Protein Gated Ion Channels
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22.5: GPCRs Regulate Adenylyl Cyclase Activity
30
22.6: cAMP-dependent Protein Kinase Pathways
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22.7: IP3/DAG Signaling Pathway
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22.8: Feedback Regulation of Calcium Concentration
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22.9: Calmodulin-dependent Signaling
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22.10: Nitric Oxide Signaling Pathway

Chapter 23: Signaling Networks of Kinase Receptors

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23.1: Receptor Tyrosine Kinases
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23.2: Small GTPases - Ras and Rho
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23.3: MAPK Signaling Cascades
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23.4: The JAK-STAT Signaling Pathway
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23.5: PI3K/mTOR/AKT Signaling Pathway
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23.6: TGF - β Signaling Pathway

Chapter 24: Alternative Signaling Routes in Gene Expression

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24.1: Notch Signaling Pathway
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24.2: Canonical Wnt Signaling Pathway
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24.3: Non-Canonical Wnt Signaling Pathways
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24.4: Hedgehog Signaling Pathway
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24.5: NF-kB-dependent Signaling Pathway
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24.6: Circadian Rhythms and Gene Regulation

Chapter 25: The Cytoskeleton I: Actin and Microfilaments

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25.1: Introduction to the Cytoskeleton
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25.2: Adaptability of Cytoskeletal Filaments
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25.3: Polarity of the Cytoskeleton
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25.4: Assembly of Cytoskeletal Filaments
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25.5: Cytoskeletal Linker Proteins - Plakins
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25.6: Cytoskeletal Accessory Proteins
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25.7: Cytoskeletal Proteins in Bacteria
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25.8: Intracellular Movement of Viruses and Bacteria
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25.9: Studying the Cytoskeleton
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25.10: Introduction to Actin
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25.11: Actin Polymerization
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25.12: Actin Treadmilling
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25.13: Generation of Straight or Branched Actin Filaments
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25.14: Actin Filament Depolymerization
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25.15: Formation of Higher-order Actin Filaments
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25.16: Overview of Myosin Structure and Function
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25.17: Actin and Myosin in Muscle Contraction
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25.18: The Role of Actin and Myosin in Non-muscle Cells

Chapter 26: The Cytoskeleton II: Microtubules and Intermediate Filaments

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26.1: Microtubules
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26.2: Microtubule Instability
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26.3: Microtubule Formation
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26.4: Microtubule Associated Proteins (MAPs)
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26.5: Destabilization of Microtubules
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26.6: Microtubule Associated Motor Proteins
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26.7: The Movement of Organelles and Vesicles
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26.8: Assembly of Complex Microtubule Structures
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26.9: Microtubules in Cell Motility
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26.10: Mechanism of Ciliary Motion
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26.11: Microtubules in Signaling
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26.12: Drugs that Stabilize Microtubules
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26.13: Drugs that Destabilize Microtubules
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26.14: The Structure of Intermediate Filaments
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26.15: Types of Intermediate Filaments
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26.16: Formation of Intermediate Filaments
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26.17: Disassembly of Intermediate Filaments
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26.18: Septins
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26.19: Role of Septins

Chapter 27: Extracellular Matrix in Animals

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27.1: The Extracellular Matrix
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27.2: Glycosaminoglycans
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27.3: Collagens are the Major Structural Proteins of ECM
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27.4: Fibril-associated Collagen
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27.5: Elastin is Responsible for Tissue Elasticity
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27.6: Fibronectins Connect Cells with ECM
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27.7: Matrix Proteoglycans and Glycoproteins
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27.8: Role of Matrix Metalloproteases in Degradation of ECM
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27.9: Basal Lamina are the Specialized Form of ECM
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27.10: Laminins are the Adhesive Proteins of Basal Lamina
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27.11: Type IV Collagen of Basal Lamina

Chapter 28: Cell-Matrix Interactions

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28.1: Overview of Cell-Matrix Interactions
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28.2: Integrins
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28.3: Activation of Integrins
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28.4: Intracellular Signaling Affects Focal Adhesions
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28.5: Anchoring Junctions
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28.6: Cell-matrix's Response to Mechanical Forces

Chapter 29: Cell-Cell Interactions

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29.1: Cell Adhesion Molecules - Types and Functions
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29.2: Structure of Cadherins
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29.3: Cadherins in Tissue Organization
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29.4: Catenins
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29.5: Selectins
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29.6: Immunoglobulin-like Cell Adhesion Molecules
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29.7: Overview of Cell-Cell Junctions
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29.8: Adherens Junctions
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29.9: Tension Response at Adheren Junctions
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29.10: Desmosomes
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29.11: Tight Junctions
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29.12: Gap Junctions

Chapter 30: Cell Polarization and Migration

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30.1: Cell Migration
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30.2: Actin Polymerization and Cell Motility
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30.3: Types of Membrane Protrusions
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30.4: Mechanism of Lamellipodia Formation
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30.5: Mechanism of Filopodia Formation
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30.6: Cancer Cell Migration through Invadopodia
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30.7: Cell Motility through Blebbing
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30.8: Role of Myosin in Cell Migration
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30.9: Cell Polarization by Rho Proteins
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30.10: Chemotaxis and Direction of Cell Migration
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30.11: Cytoskeletal Coordination in Cell Migration

Chapter 31: Plant Cell Structure and Organization

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31.1: Plant Tissues
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31.2: Plant Cell Wall
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31.3: Tonicity in Plants
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31.4: Cellulose and Pectic Polysaccharides
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31.5: Role of Microtubules in Cell Wall Deposition
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31.6: Plasmodesmata
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31.7: Cell Adhesion in Plants

Chapter 32: Analyzing Cells and Proteins

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32.1: Overview Of Cell Separation And Isolation
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32.2: Cell Culture
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32.3: Cell Lines
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32.4: Hybridoma Technology
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32.5: Tissue Homogenization and Cell Lysis
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32.6: Subcellular Fractionation
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32.7: Flow Cytometry
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32.8: Principles Of Column Chromatography
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32.9: Types Of Column Chromatography
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32.10: Immunoprecipitation
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32.11: Tagging and Fusion Proteins
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32.12: SDS-PAGE
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32.13: Western Blotting
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32.14: Two-dimensional Gel Electrophoresis
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32.15: Enzyme-Linked Immunosorbent Assay
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32.16: MALDI-TOF Mass Spectrometry
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32.17: Peptide Identification Using Tandem Mass Spectrometry
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32.18: X-ray Diffraction of Biological Samples
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32.19: Applications Of NMR In Biology
30
32.20: Proteomics

Chapter 33: Visualizing Cells, Tissues, and Molecules

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33.1: Imaging Biological Samples with Optical Microscopy
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33.2: Phase Contrast and Differential Interference Contrast Microscopy
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33.3: Fixation and Sectioning
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33.4: Immunofluorescence Microscopy
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33.5: Immunocytochemistry and Immunohistochemistry
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33.6: Confocal Fluorescence Microscopy
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33.7: Protein Dynamics in Living Cells
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33.8: Total Internal Reflection Fluorescence Microscopy
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33.9: Atomic Force Microscopy
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33.10: Super-resolution Fluorescence Microscopy
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33.11: Overview of Electron Microscopy
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33.12: Scanning Electron Microscopy
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33.13: Transmission Electron Microscopy
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33.14: Preparation of Samples for Electron Microscopy
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33.15: Immunogold Electron Microscopy
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33.16: Cryo-electron Microscopy
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33.17: Electron Microscope Tomography and Single-particle Reconstruction

Chapter 34: Cell Proliferation

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34.1: What is the Cell Cycle?
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34.2: Interphase
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34.3: The Cell Cycle Control System
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34.4: Positive Regulator Molecules
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34.5: Inhibition of CDK Activity
30
34.6: S-Cdk Initiates DNA Replication
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34.7: M-Cdk Drives Transition Into Mitosis
30
34.8: Mitogens and the Cell Cycle
30
34.9: Replicative Cell Senescence
30
34.10: Abnormal Proliferation
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34.11: Cells Coordinate Growth and Proliferation

Chapter 35: Cell Division

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35.1: Mitosis and Cytokinesis
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35.2: Chromosome Duplication
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35.3: Cohesins
30
35.4: Condensins
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35.5: The Mitotic Spindle
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35.6: Centrosome Duplication
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35.7: Spindle Assembly
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35.8: Attachment of Sister Chromatids
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35.9: Forces Acting on Chromosomes
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35.10: Separation of Sister Chromatids
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35.11: The Spindle Assembly Checkpoint
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35.12: Anaphase A and B
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35.13: Anaphase Promoting Complex
30
35.14: The Contractile Ring
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35.15: Determining the Plane of Cell Division
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35.16: The Phragmoplast
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35.17: Distribution of Cytoplasmic Content

Chapter 36: Meiosis

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36.1: What is Meiosis?
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36.2: Meiosis I
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36.3: Meiosis II
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36.4: Meiosis vs. Mitosis
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36.5: Crossing Over
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36.6: Nondisjunction

Chapter 37: Cell Death

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37.1: Overview of Cell Death
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37.2: Apoptosis
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37.3: Caspases
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37.4: The Extrinsic Apoptotic Pathway
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37.5: The Intrinsic Apoptotic Pathway
30
37.6: Phagocytosis of Apoptotic Cells
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37.7: Autophagic Cell Death
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37.8: Necrosis

Chapter 38: Cancer

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38.1: What is Cancer?
30
38.2: Cancers Originate from Somatic Mutations in a Single Cell
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38.3: Tumor Progression
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38.4: Adaptive Mechanisms in Cancer Cells
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38.5: The Tumor Microenvironment
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38.6: Metastasis
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38.7: Cancer-Critical Genes I: Proto-oncogenes
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38.8: Cancer-Critical Genes II: Tumor Suppressor Genes
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38.9: Loss of Tumor Suppressor Gene Functions
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38.10: The Retinoblastoma Gene
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38.11: Mechanisms of Retrovirus-induced Cancers
30
38.12: Rous Sarcoma Virus (RSV) and Cancer
30
38.13: The Ras Gene
30
38.14: mTOR Signaling and Cancer Progression
30
38.15: Cancer Stem Cells and Tumor Maintenance
30
38.16: Mouse Models of Cancer Study
30
38.17: Cancer Prevention
30
38.18: Cancer Therapies
30
38.19: Targeted Cancer Therapies
30
38.20: Treatment Resistent Cancers
30
38.21: Combination Therapies and Personalized Medicine

Chapter 39: Stem Cell Biology And Renewal in Epithelial Tissue

30
39.1: Zygotic Development And Stem Cell Formation
30
39.2: Source And Potency Of Stem Cells
30
39.3: Stem Cell Niche
30
39.4: Renewal of Intestinal Stem Cells
30
39.5: Role of Ephrin-Eph Signalling in Intestinal Stem Cell Renewal
30
39.6: Role Of Notch Signalling In Intestinal Stem Cell Renewal
30
39.7: Renewal of Skin Epidermal Stem Cells
30
39.8: Multipotency and Niche of Bulge Stem Cell
30
39.9: Clinical Applications of Epidermal Stem Cells
30
39.10: Distinctive Features of Adult Stem Cells vs Cancer Stem Cells
30
39.11: Stem Cell Culture
30
39.12: Tissue Renewal without Stem Cells
30
39.13: Unrenewable Cells

Chapter 40: A Hierarchical Stem-Cell System: Blood Cell Formation

30
40.1: Overview of the Vascular System
30
40.2: Mechanism of Angiogenesis
30
40.3: Regulation of Angiogenesis and Blood Supply
30
40.4: Hematopoiesis
30
40.5: Multipotency of Hematopoietic Stem Cells
30
40.6: Lineage Commitment
30
40.7: Erythropoiesis
30
40.8: Differentiation of Common Myeloid Progenitor Cells
30
40.9: Regulation of Hematopoietic Stem Cells

Chapter 41: Fibroblast Transformation and Muscle Stem Cells

30
41.1: Connective Tissue Cell Types
30
41.2: Introduction to Fibroblasts
30
41.3: Mesenchymal Stem Cells
30
41.4: Growth of Cartilage and Bone Tissue
30
41.5: Osteoclasts in Bone Remodeling
30
41.6: Overview of Skeletal Muscle
30
41.7: Formation of Muscle Fibers from Myoblasts
30
41.8: Satellite Stem Cells and Muscular Dystrophy

Chapter 42: Regeneration and Repair

30
42.1: Overview of Regeneration and Repair
30
42.2: Phases of Wound Repair
30
42.3: Whole Body Regeneration
30
42.4: Liver Regeneration
30
42.5: Stem Cell Therapy for Tissue Regeneration
30
42.6: Introduction to Nuclear Reprogramming
30
42.7: Methods of Nuclear Reprogramming
30
42.8: Cloning of Dolly the Sheep

Chapter 43: Embryonic and Induced Pluripotent Stem Cells

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43.1: Embryonic Stem Cells
30
43.2: Maintenance of the ES Cell State
30
43.3: Induced Pluripotent Stem Cells
30
43.4: Somatic to iPS Cell Reprogramming
30
43.5: Chromatin Modification in iPS Cells
30
43.6: iPS Cell Differentiation
30
43.7: Forced Transdifferentiation
30
43.8: EPS and iPS Cells in Disease Research

Full Table of Contents

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Oxidation and Reduction of Organic Molecules

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TRANSCRIPT

Living organisms break down organic molecules in a series of reactions to generate energy. Many of these reactions are oxidation-reduction reactions or redox reactions.

Oxidation is the removal of electrons from an atom, while reduction is the addition of electrons. Because the number of electrons in a reaction is conserved, oxidation and reduction half-reactions always occur in pairs.

Inside cells, when a molecule gains an electron, it often accepts a proton from its surroundings. This addition of hydrogen is called hydrogenation, and the molecule is reduced. Conversely, when a molecule loses hydrogens, this is a dehydrogenation, and the molecule is oxidized.

Protons and electrons can be transferred to electron-carrying molecules, including coenzymes.

For example, in the dehydrogenation of succinate to fumarate, electrons and protons are transferred to the coenzyme FAD, reducing it to FADH₂. The reduced FADH₂ further transfers the electrons through the electron transport chain and is oxidized back to FAD.

3.10: Oxidation and Reduction of Organic Molecules

Energy production within a cell involves many coordinated chemical pathways. Most of these pathways are combinations of oxidation and reduction reactions, which occur at the same time. An oxidation reaction strips an electron from an atom in a compound, and the addition of this electron to another compound is a reduction reaction. Because oxidation and reduction usually occur together, these pairs of reactions are called redox reactions.

The removal of an electron from a molecule, results in a decrease in potential energy in the oxidized compound. However, the electron (sometimes as part of a hydrogen atom) does not remain unbonded in the cytoplasm of a cell. Rather, the electron is shifted to a second compound, reducing the second compound. The shift of an electron from one compound to another removes some potential energy from the first compound (the oxidized compound) and increases the potential energy of the second compound (the reduced compound). The transfer of electrons between molecules is important because most of the energy stored in atoms and used to fuel cell functions is in the form of high-energy electrons. The transfer of energy in the form of high-energy electrons allows the cell to transfer and use energy in an incremental fashion—in small packages rather than in a single, destructive burst.

In living systems, a small class of compounds functions as electron shuttles: they bind and carry high-energy electrons between compounds in biochemical pathways. The principal electron carriers we will consider are derived from the B vitamin group and are derivatives of nucleotides. These compounds can be easily reduced (that is, they accept electrons) or oxidized (they lose electrons). Nicotinamide adenine dinucleotide (NAD) is derived from vitamin B3, niacin. NAD⁺ is the oxidized form of the molecule; NADH is the reduced form of the molecule after it has accepted two electrons and a proton (which together are the equivalent of a hydrogen atom with an extra electron).

This text is adapted from Openstax, Biology 2e, Section 7.1 Energy in Living Systems

Chapter 1: Cells, Genomes, and Evolution

Chapter 2: Biochemistry of the Cell

Chapter 3: Energy and Catalysis

Chapter 4: Introduction to Metabolism

Chapter 5: Protein Structure

Chapter 6: Protein Function

Chapter 7: Structure and Organization of DNA

Chapter 8: DNA Replication and Repair

Chapter 9: Transcription: DNA to RNA

Chapter 10: Translation: RNA to Protein

Chapter 11: Control of Gene Expression

Chapter 12: Membrane Structure and Components

Chapter 13: Membrane Transport and Active Transporters

Chapter 14: Channels and the Electrical Properties of Membranes

Chapter 15: Transmembrane Transport in Endoplasmic Reticulum and Peroxisomes

Chapter 16: Intracellular Compartments and Protein Sorting

Chapter 17: Intracellular Membrane Traffic

Chapter 18: Endocytosis and Exocytosis

Chapter 19: Mitochondria and Energy Production

Chapter 20: Chloroplasts and Photosynthesis

Chapter 21: Principles of Cell Signaling

Chapter 22: Signaling Networks of G Protein-coupled Receptors

Chapter 23: Signaling Networks of Kinase Receptors

Chapter 24: Alternative Signaling Routes in Gene Expression

Chapter 25: The Cytoskeleton I: Actin and Microfilaments

Chapter 26: The Cytoskeleton II: Microtubules and Intermediate Filaments

Chapter 27: Extracellular Matrix in Animals

Chapter 28: Cell-Matrix Interactions

Chapter 29: Cell-Cell Interactions

Chapter 30: Cell Polarization and Migration

Chapter 31: Plant Cell Structure and Organization

Chapter 32: Analyzing Cells and Proteins

Chapter 33: Visualizing Cells, Tissues, and Molecules

Chapter 34: Cell Proliferation

Chapter 35: Cell Division

Chapter 36: Meiosis

Chapter 37: Cell Death

Chapter 38: Cancer

Chapter 39: Stem Cell Biology And Renewal in Epithelial Tissue

Chapter 40: A Hierarchical Stem-Cell System: Blood Cell Formation

Chapter 41: Fibroblast Transformation and Muscle Stem Cells

Chapter 42: Regeneration and Repair

Chapter 43: Embryonic and Induced Pluripotent Stem Cells

3.10: Oxidation and Reduction of Organic Molecules

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