Name: Cooperative Allosteric Transitions
Uploaded: 2021-01-27T09:19:32-05:00
Duration: 1 min 58 s
Description: Cooperative allosteric transitions can occur in multimeric proteins, where each subunit of the protein has its own ligand-binding site.

Chapter 4: Protein Function Back To Chapter

4.9: Cooperative Allosteric Transitions

TABLE OF
CONTENTS

X

Chapter 1: DNA, Cells, and Evolution

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1.1: The DNA Helix
30
1.2: The Central Dogma
30
1.3: Prokaryotic cells
30
1.4: Eukaryotic Compartmentalization
30
1.5: The Tree of Life - Bacteria, Archaea, Eukaryotes
30
1.6: Mutations
30
1.7: Gene Evolution - Fast or Slow?
30
1.8: Genome Size and the Evolution of New Genes
30
1.9: Gene Families
30
1.10: Types of Genetic Transfer Between Organisms

Chapter 2: Biochemistry of the Cell

30
2.1: The Periodic Table and Organismal Elements
30
2.2: Functional Groups
30
2.3: Polymers
30
2.4: What are Lipids?
30
2.5: Structure of Lipids
30
2.6: Chemistry of Carbohydrates
30
2.7: Nucleic Acids
30
2.8: Intermolecular Forces
30
2.9: Noncovalent Attractions in Biomolecules
30
2.10: pH
30
2.11: Hydrolysis of ATP

Chapter 3: Protein Structure

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3.1: What are Proteins?
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3.2: Protein Organization
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3.3: Protein Folding
30
3.4: Protein Families
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3.5: Conservation of Protein Domains Over Different Proteins
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3.6: Globular and Fibrous Proteins
30
3.7: Intrinsically Disordered Proteins
30
3.8: Protein Complex Assembly
30
3.9: Conjugated Proteins
30
3.10: Amyloid Fibrils
30
3.11: Antibody Structure

Chapter 4: Protein Function

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4.1: Ligand Binding Sites
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4.2: Protein-protein Interfaces
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4.3: Conserved Binding Sites
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4.4: The Equilibrium Binding Constant and Binding Strength
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4.5: Cofactors and Coenzymes
30
4.6: Allosteric Regulation
30
4.7: Ligand Binding and Linkage
30
4.8: Allosteric Proteins-ATCase
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4.9: Cooperative Allosteric Transitions
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4.10: Phosphorylation
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4.11: Protein Kinases and Phosphatases
30
4.12: GTPases and their Regulation
30
4.13: Covalently Linked Protein Regulators
30
4.14: Protein Complexes with Interchangeable Parts
30
4.15: Mechanical Protein Functions
30
4.16: Structural Protein Function
30
4.17: Protein Networks

Chapter 5: DNA and Chromosome Structure

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5.1: DNA Packaging
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5.2: DNA as a Genetic Template
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5.3: Organization of Genes
30
5.4: Chromosome Structure
30
5.5: Chromosome Replication
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5.6: The Nucleosome
30
5.7: The Nucleosome Core Particle
30
5.8: Nucleosome Remodeling
30
5.9: Chromatin Packaging
30
5.10: Karyotyping
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5.11: Position-effect Variegation
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5.12: Histone Modification
30
5.13: Spreading of Chromatin Modifications
30
5.14: Lampbrush Chromosomes
30
5.15: Polytene Chromosomes
30
5.16: Histone Variants at the Centromere
30
5.17: Inheritance of Chromatin Structures
30
5.18: Euchromatin
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5.19: Heterochromatin
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5.20: Chromatin Position Affects Gene Expression

Chapter 6: DNA Replication

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6.1: Replication in Prokaryotes
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6.2: Replication in Eukaryotes
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6.3: DNA Base Pairing
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6.4: The DNA Replication Fork
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6.5: Proofreading
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6.6: Lagging Strand Synthesis
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6.7: DNA Helicases
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6.8: Single-Strand DNA Binding Proteins
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6.9: The Replisome
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6.10: Mismatch Repair
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6.11: DNA Topoisomerases
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6.12: Telomeres and Telomerase
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6.13: Non-nuclear Inheritance
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6.14: Animal Mitochondrial Genetics
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6.15: Comparing Mitochondrial, Chloroplast, and Prokaryotic Genomes
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6.16: Export of Mitochondrial and Chloroplast Genes

Chapter 7: DNA Repair and Recombination

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7.1: Overview of DNA Repair
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7.2: Base Excision Repair
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7.3: Long-patch Base Excision Repair
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7.4: Nucleotide Excision Repair
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7.5: Translesion DNA Polymerases
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7.6: Fixing Double-strand Breaks
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7.7: DNA Damage can Stall the Cell Cycle
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7.8: Homologous Recombination
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7.9: Restarting Stalled Replication Forks
30
7.10: Gene Conversion
30
7.11: Overview of Transposition and Recombination
30
7.12: DNA-only Transposons
30
7.13: Retroviruses
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7.14: LTR Retrotransposons
30
7.15: Non-LTR Retrotransposons
30
7.16: Conservative Site-specific Recombination and Phase Variation

Chapter 8: Transcription: DNA to RNA

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8.1: What is Gene Expression?
30
8.2: RNA Structure
30
8.3: RNA Stability
30
8.4: Bacterial RNA Polymerase
30
8.5: Bacterial Transcription
30
8.6: Types of RNA
30
8.7: Transcription
30
8.8: Transcription Factors
30
8.9: Eukaryotic RNA Polymerases
30
8.10: Transcription Initiation
30
8.11: RNA Polymerase II Accessory Proteins
30
8.12: Transcription Elongation Factors
30
8.13: Pre-mRNA Processing
30
8.14: RNA Splicing
30
8.15: Alternative RNA Splicing
30
8.16: Chromatin Structure Regulates pre-mRNA Processing
30
8.17: Nuclear Export of mRNA
30
8.18: Ribosomal RNA Synthesis
30
8.19: Transfer RNA Synthesis
30
8.20: The Nucleolus
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8.21: Additional Subnuclear Structures

Chapter 9: Translation: RNA to Protein

30
9.1: Translation
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9.2: tRNA Activation
30
9.3: Ribosomes
30
9.4: Improving Translational Accuracy
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9.5: Initiation of Translation
30
9.6: Termination of Translation
30
9.7: Nonsense-mediated mRNA Decay
30
9.8: Molecular Chaperones and Protein Folding
30
9.9: The Proteasome
30
9.10: Regulated Protein Degradation
30
9.11: Proteins: From Genes to Degradation

Chapter 10: Gene Expression

30
10.1: Cell-Specific Gene Expression
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10.2: Regulation of Expression Occurs at Multiple Steps
30
10.3: Cis-regulatory Sequences
30
10.4: Cooperative Binding of Transcription Regulators
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10.5: Prokaryotic Transcriptional Activators and Repressors
30
10.6: Operons
30
10.7: The Eukaryotic Promoter Region
30
10.8: Co-activators and Co-repressors
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10.9: Eukaryotic Transcription Activators
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10.10: Eukaryotic Transcription Inhibitors
30
10.11: Combinatorial Gene Control
30
10.12: Induced Pluripotent Stem Cells
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10.13: Master Transcription Regulators
30
10.14: Epigenetic Regulation
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10.15: Genomic Imprinting and Inheritance

Chapter 11: Additional Roles of RNA

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11.1: Transcription Attenuation in Prokaryotes
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11.2: Riboswitches
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11.3: RNA Editing
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11.4: Regulated mRNA Transport
30
11.5: Leaky Scanning
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11.6: mRNA Stability and Gene Expression
30
11.7: RNA Interference
30
11.8: MicroRNAs
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11.9: siRNA - Small Interfering RNAs
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11.10: piRNA - Piwi-interacting RNAs
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11.11: CRISPR and crRNAs
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11.12: lncRNA - Long Non-coding RNAs
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11.13: Ribozymes
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11.14: Conditions on Early Earth

Chapter 12: Mendelian Genetics

30
12.1: Punnett Squares
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12.2: Monohybrid Crosses
30
12.3: Dihybrid Crosses
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12.4: Trihybrid Crosses
30
12.5: Law of Independent Assortment
30
12.6: Chi-square Analysis
30
12.7: Pedigree Analysis
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12.8: Incomplete Dominance
30
12.9: Lethal Alleles
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12.10: Polygenic Traits
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12.11: Background and Environment Affect Phenotype
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12.12: X and Y Chromosomes
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12.13: The Y Chromosome Determines Maleness
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12.14: The Ratio of X Chromosome to Autosomes
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12.15: X-linked Traits
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12.16: Sex Linked Disorders
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12.17: Dosage Compensation
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12.18: X-inactivation
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12.19: Multiple Allele Traits
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12.20: Blood Types
30
12.21: Blood Transfusion and Agglutination

Chapter 13: Genomes and Evolution

30
13.1: Evolutionary Relationships through Genome Comparisons
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13.2: Genome Copying Errors
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13.3: Phylogenetic Trees
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13.4: Synteny and Evolution
30
13.5: Multi-species Conserved Sequences
30
13.6: Gene Duplication and Divergence
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13.7: Exon Recombination
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13.8: Comparing Copy Number Variations and SNPs

Chapter 14: Cell Signaling Pathways

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14.1: What is Cell Signaling?
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14.2: Autocrine Signaling
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14.3: Paracrine Signaling
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14.4: Endocrine Signaling
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14.5: Intracellular Signaling Cascades
30
14.6: Notch Signaling Pathway
30
14.7: Canonical Wnt Signaling Pathway
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14.8: Non-Canonical Wnt Signaling Pathways
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14.9: Hedgehog Signaling Pathway
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14.10: NF-κB-dependent Signaling Pathway
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14.11: Internal Receptors
30
14.12: Circadian Rhythms and Gene Regulation
30
14.13: G-protein Coupled Receptors
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14.14: What are Second Messengers?
30
14.15: Enzyme-linked Receptors

Chapter 15: Studying DNA and RNA

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15.1: Recombinant DNA
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15.2: DNA Isolation
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15.3: Restriction Enzymes
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15.4: DNA Agarose Gel Electrophoresis
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15.5: Labeling DNA Probes
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15.6: Southern Blot
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15.7: DNA Microarrays
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15.8: Complementary DNA
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15.9: FISH - Fluorescent In-situ Hybridization
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15.10: PCR - Polymerase Chain Reaction
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15.11: Real Time RT-PCR
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15.12: RACE - Rapid Amplification of cDNA Ends
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15.13: Sanger Sequencing
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15.14: Maxam-Gilbert Sequencing
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15.15: Next-generation Sequencing
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15.16: RNA-seq
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15.17: Genome Annotation and Assembly

Chapter 16: Analyzing Gene Expression and Function

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16.1: In vitro Mutagenesis
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16.2: Genetic Screens
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16.3: Test Cross
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16.4: Complementation Tests
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16.5: Epistasis Analysis
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16.6: Single Nucleotide Polymorphisms-SNPs
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16.7: Genome-wide Association Studies-GWAS
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16.8: Bacterial Transformation
30
16.9: Transgenic Organisms
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16.10: Reproductive Cloning
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16.11: CRISPR
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16.12: Experimental RNAi
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16.13: Reporter Genes
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16.14: In-situ Hybridization
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16.15: Chromatin Immunoprecipitation- ChIP
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16.16: Synthetic Biology
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16.17: Ribosome Profiling
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16.18: Transgenic Plants
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16.19: Gene Therapy

Chapter 17: Cell Proliferation

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17.1: What is the Cell Cycle?
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17.2: Interphase
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17.3: The Cell Cycle Control System
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17.4: Positive Regulator Molecules
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17.5: Inhibition of Cdk Activity
30
17.6: S-Cdk Initiates DNA Replication
30
17.7: M-Cdk Drives Transition Into Mitosis
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17.8: Mitogens and the Cell Cycle
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17.9: Replicative Cell Senescence
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17.10: Abnormal Proliferation
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17.11: Cells Coordinate Growth and Proliferation

Chapter 18: Cell Division

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18.1: Mitosis and Cytokinesis
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18.2: Duplication of Chromatin Structure
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18.3: Cohesins
30
18.4: Condensins
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18.5: The Mitotic Spindle
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18.6: Centrosome Duplication
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18.7: Microtubule Instability
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18.8: Spindle Assembly
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18.9: Attachment of Sister Chromatids
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18.10: Forces Acting on Chromosomes
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18.11: Separation of Sister Chromatids
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18.12: The Spindle Assembly Checkpoint
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18.13: Anaphase A and B
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18.14: Anaphase Promoting Complex
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18.15: The Contractile Ring
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18.16: Determining the Plane of Cell Division
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18.17: The Phragmoplast
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18.18: Distribution of Cytoplasmic Content

Chapter 19: Meiosis

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19.1: What is Meiosis?
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19.2: Meiosis I
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19.3: Meiosis II
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19.4: Meiosis vs. Mitosis
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19.5: Crossing over
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19.6: Nondisjunction

Chapter 20: Cancer

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20.1: What is Cancer?
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20.2: Cancers Originate from Somatic Mutations in a Single Cell
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20.3: Tumor Progression
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20.4: Adaptive Mechanisms in Cancer Cells
30
20.5: The Tumor Microenvironment
30
20.6: Metastasis
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20.7: Cancer-Critical Genes I: Proto-oncogenes
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20.8: Cancer-Critical Genes II: Tumor Suppressor Genes
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20.9: Loss of Tumor Suppressor Gene Functions
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20.10: The Retinoblastoma Gene
30
20.11: The Ras Gene
30
20.12: mTOR Signaling and Cancer Progression
30
20.13: Mechanisms of Retrovirus-induced Cancers
30
20.14: Rous Sarcoma Virus (RSV) and Cancer
30
20.15: Cancer Stem Cells and Tumor Maintenance
30
20.16: Mouse Models of Cancer Study
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20.17: Cancer Prevention
30
20.18: Cancer Therapies
30
20.19: Targeted Cancer Therapies
30
20.20: Treatment Resistant Cancers
30
20.21: Combination Therapies and Personalized Medicine

Full Table of Contents

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Cooperative Allosteric Transitions

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TRANSCRIPT

Many proteins have multiple subunits, where each subunit contains a separate ligand binding site.

When a molecule, known as a modulator, binds to one of the subunits it triggers a conformational change in the binding sites of the other subunits changing their affinity for their respective ligands. This is called a cooperative allosteric transition and can be explained by several theoretical models.

The concerted or “all-or-none” model assumes that all of the subunits exist together in either an “off” or “on” conformation.

Binding can occur in either form, however, the “on” state has a higher affinity for the ligand than the “off” state. When a ligand binds at any of the subunits, it promotes the simultaneous transformation of all of the binding sites to the high-affinity form.

Cooperativity can also be explained by the sequential model, which assumes that each subunit can exist independently in a high or low-affinity state, but is more likely to be in the high-affinity state when the ligand is bound to any of the subunits.

The binding sites of allosteric proteins are usually a mix of flexible and fixed segments of the amino acid chain. When a ligand binds, these unstable parts are stabilized in a particular conformation, and this affects the shape of the binding sites on the other subunits.

Hemoglobin is an example of a tetrameric protein that undergoes a cooperative allosteric transition when oxygen binds.

Each subunit of hemoglobin has a single binding site. When one molecule of oxygen binds to a single subunit, cooperativity increases the affinity for oxygen on the remaining binding sites making it easier for oxygen to bind to a molecule of hemoglobin that already has oxygen bound to it.

4.9: Cooperative Allosteric Transitions

Cooperative allosteric transitions can occur in multimeric proteins, where each subunit of the protein has its own ligand-binding site. When a ligand binds to any of these subunits, it triggers a conformational change that affects the binding sites in the other subunits; this can change the affinity of the other sites for their respective ligands. The ability of the protein to change the shape of its binding site is attributed to the presence of a mix of flexible and stable segments in the structure. A molecule that triggers this change is known as a modulator.

Two models are often used to explain cooperativity in multimeric proteins: the concerted and the sequential model. The concerted model, also known as the all-or-none model, hypothesizes that all the subunits of a multimeric protein switch simultaneously between the “on” and “off” conformations. In the “on” form, the binding sites have a high affinity for their respective ligands, and in the “off” form, the binding sites have a low affinity. When a ligand binds to any one of the subunits, it promotes the conversion to the high-affinity form, simultaneously changing the conformation of all other binding sites of the protein. Although a ligand can bind to either form, it is easier for it to bind when in the high-affinity form.

The sequential model assumes that each subunit of a multimeric protein can exist independently in an “on” or “off” conformation, that is in either the low or high-affinity form, regardless of the state of the other subunits. Binding of a ligand to a subunit changes the equilibrium between the low and high-affinity forms such that it is more likely for the subunit to be in high-affinity form. Additionally, a ligand binding on one subunit shifts the equilibrium for the other subunits in the protein. This increases the likelihood that once one ligand is bound, another ligand will bind to a different subunit. This cooperativity increases the sensitivity of the protein to ligand concentration. A ligand binding at a single site can change the affinity on the entire protein molecule, thereby enabling a rapid response at low concentrations.

Suggested Reading

Chapter 1: DNA, Cells, and Evolution

Chapter 2: Biochemistry of the Cell

Chapter 3: Protein Structure

Chapter 4: Protein Function

Chapter 5: DNA and Chromosome Structure

Chapter 6: DNA Replication

Chapter 7: DNA Repair and Recombination

Chapter 8: Transcription: DNA to RNA

Chapter 9: Translation: RNA to Protein

Chapter 10: Gene Expression

Chapter 11: Additional Roles of RNA

Chapter 12: Mendelian Genetics

Chapter 13: Genomes and Evolution

Chapter 14: Cell Signaling Pathways

Chapter 15: Studying DNA and RNA

Chapter 16: Analyzing Gene Expression and Function

Chapter 17: Cell Proliferation

Chapter 18: Cell Division

Chapter 19: Meiosis

Chapter 20: Cancer

4.9: Cooperative Allosteric Transitions

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