In-Text Art, Ch. 9, p. 166. In-Text Art, Ch. 3, p. 37

In-Text Art, Ch. 9, p. 166

In-Text Art, Ch. 3, p. 37

Figure 3.1 Nucleotides Have Three Components

Figure 3.2 Linking Nucleotides Together

In-Text Art, Ch. 3, p. 36

Figure 3.3 RNA

Figure 3.4 DNA

Figure 3.5 DNA Replication and Transcription

In-Text Art, Ch. 9, p. 169

In-Text Art, Ch. 9, p. 169

Figure 9.5 DNA Is a Double Helix

Figure 9.6 Base Pairs in DNA Can Interact with Other Molecules

In-Text Art, Ch. 9, p. 172

Figure 9.7 Each New DNA Strand Grows by the Addition of Nucleotides to Its 3′ End

Figure 9.8 The Origin of DNA Replication

Figure 9.9 DNA Forms with a Primer

Figure 9.10 DNA Polymerase Binds to the Template Strand

Figure 9.11 The Two New Strands Form in Different Ways

Figure 9.12 The Lagging Strand Story

Figure 9.12 The Lagging Strand Story (Part 1)

Figure 9.12 The Lagging Strand Story (Part 2)

Figure 9.12 The Lagging Strand Story (Part 3)

Figure 9.13 Telomeres and Telomerase

Figure 9.13 Telomeres and Telomerase

Figure 9.14 DNA Repair Mechanisms

Figure 9.14 DNA Repair Mechanisms (Part 2)

Figure 9.16 Mutation and Phenotype

Figure 9.18 Spontaneous and Induced Mutations

Figure 9.18 Spontaneous and Induced Mutations (Part 1)

Figure 9.18 Spontaneous and Induced Mutations (Part 2)

Figure 9.18 Spontaneous and Induced Mutations (Part 3)

Figure 9.19 5-Methylcytosine in DNA Is a “Hotspot” for Mutations

Figure 10.1 Metabolic Diseases and Enzymes

Figure 10.2 Gene Mutations and Amino Acid Changes

Figure 10.3 From Gene to Protein

Figure 10.5 DNA Is Transcribed to Form RNA

Figure 10.5 DNA Is Transcribed to Form RNA (Part 1)

Figure 10.5 DNA Is Transcribed to Form RNA (Part 2)

Figure 10.5 DNA Is Transcribed to Form RNA (Part 3)

Figure 10.5 DNA Is Transcribed to Form RNA (Part 4)

Figure 10.6 Transcription of a Eukaryotic Gene

Figure 10.6 Transcription of a Eukaryotic Gene (Part 1)

Figure 10.6 Transcription of a Eukaryotic Gene (Part 2)

Table 10.1 Differences between Prokaryotic and Eukaryotic Gene Expression

Figure 10.9 The Spliceosome: An RNA Splicing Machine

Figure 10.9 The Spliceosome: An RNA Splicing Machine

In-Text Art, Ch. 10, p. 195

Figure 10.11 The Genetic Code

Figure 10.12 Mutations

Figure 10.12 Mutations (Part 1)

Figure 10.12 Mutations (Part 2)

Figure 10.12 Mutations (Part 3)

Figure 10.12 Mutations (Part 4)

Figure 10.13 Transfer RNA

Figure 10.14 Ribosome Structure

Figure 10.15 The Initiation of Translation

Figure 10.15 The Initiation of Translation

Figure 10.15 The Initiation of Translation (Part 1)

Figure 10.15 The Initiation of Translation (Part 2)

Figure 10.16 The Elongation of Translation

Figure 10.16 The Elongation of Translation (Part 1)

Figure 10.16 The Elongation of Translation (Part 2)

Figure 10.17 The Termination of Translation

Figure 10.17 The Termination of Translation (Part 1)

Figure 10.17 The Termination of Translation (Part 2)

Table 10.2 Signals that Start and Stop Transcription and Translation

Figure 10.18 A Polysome

Figure 10.18 A Polysome (Part 1)

Figure 10.18 A Polysome (Part 2)

Figure 10.19 Destinations for Newly Translated Polypeptides in a Eukaryotic Cell

Figure 10.19 Destinations for Newly Translated Polypeptides in a Eukaryotic Cell (Part 2)

Figure 10.21 Posttranslational Modifications of Proteins

Figure 10.21 Posttranslational Modifications of Proteins

Figure 10.22 An Antibiotic at the Ribosome