Name: Comparing Mitochondrial, Chloroplast, and Prokaryotic Genomes
Uploaded: 2021-02-22T09:01:48-05:00
Duration: 2 min 16 s
Description: The present-day mitochondrial and chloroplast genomes have retained some of the characteristics of their ancestral prokaryotes and also have acquired new attributes during their evolution within eukaryotic cells.

Chapter 6: DNA Replication Back To Chapter

6.15: Comparing Mitochondrial, Chloroplast, and Prokaryotic Genomes

TABLE OF
CONTENTS

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Chapter 1: DNA, Cells, and Evolution

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

Chapter 2: Biochemistry of the Cell

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2.1: The Periodic Table and Organismal Elements
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2.2: Functional Groups
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2.3: Polymers
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2.4: What are Lipids?
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2.5: Structure of Lipids
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2.6: Chemistry of Carbohydrates
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2.7: Nucleic Acids
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2.8: Intermolecular Forces
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2.9: Noncovalent Attractions in Biomolecules
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2.10: pH
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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
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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
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3.7: Intrinsically Disordered Proteins
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3.8: Protein Complex Assembly
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3.9: Conjugated Proteins
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3.10: Amyloid Fibrils
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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
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4.6: Allosteric Regulation
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4.7: Ligand Binding and Linkage
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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
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4.12: GTPases and their Regulation
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4.13: Covalently Linked Protein Regulators
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4.14: Protein Complexes with Interchangeable Parts
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4.15: Mechanical Protein Functions
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4.16: Structural Protein Function
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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
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5.4: Chromosome Structure
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5.5: Chromosome Replication
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5.6: The Nucleosome
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5.7: The Nucleosome Core Particle
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5.8: Nucleosome Remodeling
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5.9: Chromatin Packaging
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5.10: Karyotyping
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5.11: Position-effect Variegation
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5.12: Histone Modification
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5.13: Spreading of Chromatin Modifications
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5.14: Lampbrush Chromosomes
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5.15: Polytene Chromosomes
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5.16: Histone Variants at the Centromere
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5.17: Inheritance of Chromatin Structures
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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
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7.10: Gene Conversion
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7.11: Overview of Transposition and Recombination
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7.12: DNA-only Transposons
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7.13: Retroviruses
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7.14: LTR Retrotransposons
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7.15: Non-LTR Retrotransposons
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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?
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8.2: RNA Structure
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8.3: RNA Stability
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8.4: Bacterial RNA Polymerase
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8.5: Bacterial Transcription
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8.6: Types of RNA
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8.7: Transcription
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8.8: Transcription Factors
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8.9: Eukaryotic RNA Polymerases
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8.10: Transcription Initiation
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8.11: RNA Polymerase II Accessory Proteins
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8.12: Transcription Elongation Factors
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8.13: Pre-mRNA Processing
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8.14: RNA Splicing
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8.15: Alternative RNA Splicing
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8.16: Chromatin Structure Regulates pre-mRNA Processing
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8.17: Nuclear Export of mRNA
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8.18: Ribosomal RNA Synthesis
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8.19: Transfer RNA Synthesis
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8.20: The Nucleolus
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8.21: Additional Subnuclear Structures

Chapter 9: Translation: RNA to Protein

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

Chapter 10: Gene Expression

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10.1: Cell-Specific Gene Expression
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10.2: Regulation of Expression Occurs at Multiple Steps
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10.3: Cis-regulatory Sequences
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10.4: Cooperative Binding of Transcription Regulators
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10.5: Prokaryotic Transcriptional Activators and Repressors
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10.6: Operons
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10.7: The Eukaryotic Promoter Region
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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
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10.11: Combinatorial Gene Control
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10.12: Induced Pluripotent Stem Cells
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10.13: Master Transcription Regulators
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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
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11.5: Leaky Scanning
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11.6: mRNA Stability and Gene Expression
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11.7: RNA Interference
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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

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12.1: Punnett Squares
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12.2: Monohybrid Crosses
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12.3: Dihybrid Crosses
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12.4: Trihybrid Crosses
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12.5: Law of Independent Assortment
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12.6: Chi-square Analysis
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12.7: Pedigree Analysis
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12.8: Incomplete Dominance
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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
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12.21: Blood Transfusion and Agglutination

Chapter 13: Genomes and Evolution

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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
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13.5: Multi-species Conserved Sequences
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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
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14.6: Notch Signaling Pathway
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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
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14.12: Circadian Rhythms and Gene Regulation
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14.13: G-protein Coupled Receptors
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14.14: What are Second Messengers?
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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
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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
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17.6: S-Cdk Initiates DNA Replication
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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
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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
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20.5: The Tumor Microenvironment
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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
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20.11: The Ras Gene
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20.12: mTOR Signaling and Cancer Progression
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20.13: Mechanisms of Retrovirus-induced Cancers
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20.14: Rous Sarcoma Virus (RSV) and Cancer
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20.15: Cancer Stem Cells and Tumor Maintenance
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20.16: Mouse Models of Cancer Study
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20.17: Cancer Prevention
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20.18: Cancer Therapies
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20.19: Targeted Cancer Therapies
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20.20: Treatment Resistant Cancers
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20.21: Combination Therapies and Personalized Medicine

Full Table of Contents

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Comparing Mitochondrial, Chloroplast, and Prokaryotic Genomes

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6.14: Animal Mitochondrial Genetics

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TRANSCRIPT

Primitive predator cells internalized bacteria that later evolved into mitochondria, forming eukaryotic cells. Photosynthetic cyanobacteria also formed symbiotic relationships with some of these eukaryotic cells and eventually developed into the chloroplast.

The present-day mitochondrial and chloroplast genomes are the remnants of these ancestral prokaryotic genomes.

Compared to mitochondrial genomes, the genomes of current day prokaryotes are large such as in Escherichia coli which contain around 5 million bps and nearly 5000 genes.

The human mitochondrial genome is almost 17,000 bps long and contains 37 genes - whereas the mitochondrial genome of Arabidopsis thaliana, a flowering plant, has over 350,000 bps but contains only 57 genes.

Compared to current day cyanobacterial genomes, like the Synechocystis genome which has around 3.5 million bps and carries approximately 3200 genes, the chloroplast genome among terrestrial plants has up to 200,000 bps contains 120-135 genes.

Even though they are much smaller, both mitochondrial and chloroplast genomes are similar to the prokaryotic genome in several ways. Their DNA does not associate with histone proteins and is usually circular and double-stranded, similar to that of bacterial plasmids.

Compared to the mitochondrial genome, the chloroplast genome more closely resembles the prokaryotic genome. Both chloroplast and prokaryotic genomes have quite similar DNA sequences for transcription promoters and terminators.

Additionally, animal mitochondrial genomes are generally smaller than the mitochondrial genome in plants, as both chloroplast and plant mitochondrial genomes have introns that are absent in most animal mitochondrial genomes.

6.15: Comparing Mitochondrial, Chloroplast, and Prokaryotic Genomes

The present-day mitochondrial and chloroplast genomes have retained some of the characteristics of their ancestral prokaryotes and also have acquired new attributes during their evolution within eukaryotic cells. Like prokaryotic genomes, mitochondrial and chloroplast genomes neither bind with histone-like proteins nor show complex packaging into chromosome-like structures, as observed in eukaryotes. Unlike mitotic cell divisions observed in eukaryotic cells, mitochondria and chloroplasts undergo binary fission and equally separate their DNA into the daughter organelles as observed in prokaryotes. Furthermore, ribosomes in both mitochondria and chloroplasts are sensitive to antibacterial antibiotics.

Prokaryotic genomes have millions of base pairs and thousands of genes; mitochondrial and chloroplast genomes, except in a few plants, are much smaller with numbers of base pairs in the thousands with a few hundred genes. This difference in genome size occurred because, during evolution, significant parts of primitive mitochondrial and chloroplast genomes were exported to the nucleus. This export of genes made them dependent on the nuclear genome for the supply of some of the proteins required for their biogenesis.

The different evolutionary paths taken by animals and plants have resulted in significant differences between genomes of animal mitochondria and plant mitochondria and chloroplasts. Animal mitochondrial genomes are smaller than plant mitochondrial and chloroplast genomes. Also, similar to most prokaryotic genomes, animal mitochondrial genomes do not carry any introns. However, introns are present in the genomes of both plant mitochondria and chloroplasts. Compared to mitochondrial genomes, chloroplast genomes show less variation in size and structure and also contain more genes. For example, the number of genes present in the chloroplast genome of Arabidopsis thaliana is almost double of the genes present in its mitochondrial genome. Furthermore, chloroplast genomes are more similar to their prokaryotic counterparts than the mitochondrial genome as they are similar in their regulatory sequences and arrangement of many gene clusters.

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

6.15: Comparing Mitochondrial, Chloroplast, and Prokaryotic Genomes

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