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Figure 16.0 Watson and Crick. Figure 16.0x James Watson.

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Presentation on theme: "Figure 16.0 Watson and Crick. Figure 16.0x James Watson."— Presentation transcript:

1 Figure 16.0 Watson and Crick

2 Figure 16.0x James Watson

3 Figure 16.1 Transformation of bacteria

4 Figure 16.2a The Hershey-Chase experiment: phages

5 Figure 16.2ax Phages

6 Figure 16.2b The Hershey-Chase experiment

7 Figure 16.3 The structure of a DNA stand

8 Figure 16.4 Rosalind Franklin and her X-ray diffraction photo of DNA

9 Figure 16.5 The double helix

10 Unnumbered Figure (page 292) Purine and pyridimine

11 Figure 16.6 Base pairing in DNA

12 Figure 16.7 A model for DNA replication: the basic concept (Layer 1)

13 Figure 16.7 A model for DNA replication: the basic concept (Layer 2)

14 Figure 16.7 A model for DNA replication: the basic concept (Layer 3)

15 Figure 16.7 A model for DNA replication: the basic concept (Layer 4)

16 Figure 16.8 Three alternative models of DNA replication

17 Figure 16.9 The Meselson-Stahl experiment tested three models of DNA replication (Layer 1)

18 Figure 16.9 The Meselson-Stahl experiment tested three models of DNA replication (Layer 2)

19 Figure 16.9 The Meselson-Stahl experiment tested three models of DNA replication (Layer 3)

20 Figure 16.9 The Meselson-Stahl experiment tested three models of DNA replication (Layer 4)

21 Figure 16.10 Origins of replication in eukaryotes

22 Figure 16.11 Incorporation of a nucleotide into a DNA strand

23 Figure 16.12 The two strands of DNA are antiparallel

24 Figure 16.13 Synthesis of leading and lagging strands during DNA replication

25 Figure 16.14 Priming DNA synthesis with RNA

26 Figure 16.15 The main proteins of DNA replication and their functions

27 Figure 16.16 A summary of DNA replication

28 Figure 16.17 Nucleotide excision repair of DNA damage

29 Figure 16.18 The end-replication problem

30 Figure 16.19a Telomeres and telomerase: Telomeres of mouse chromosomes

31 Figure 16.19b Telomeres and telomerase

32 Figure 17.0 Ribosome

33 Figure 17.1 Beadle and Tatum’s evidence for the one gene-one enzyme hypothesis

34 Figure 17.2 Overview: the roles of transcription and translation in the flow of genetic information (Layer 1)

35 Figure 17.2 Overview: the roles of transcription and translation in the flow of genetic information (Layer 2)

36 Figure 17.2 Overview: the roles of transcription and translation in the flow of genetic information (Layer 3)

37 Figure 17.2 Overview: the roles of transcription and translation in the flow of genetic information (Layer 4)

38 Figure 17.2 Overview: the roles of transcription and translation in the flow of genetic information (Layer 5)

39 Figure 17.3 The triplet code

40 Figure 17.4 The dictionary of the genetic code

41 Figure 17.5 A tobacco plant expressing a firefly gene

42 Figure 17.6 The stages of transcription: initiation, elongation, and termination (Layer 1)

43 Figure 17.6 The stages of transcription: initiation, elongation, and termination (Layer 2)

44 Figure 17.6 The stages of transcription: initiation, elongation, and termination (Layer 3)

45 Figure 17.6 The stages of transcription: initiation, elongation, and termination (Layer 4)

46 Figure 17.6 The stages of transcription: elongation

47 Figure 17.7 The initiation of transcription at a eukaryotic promoter

48 Figure 17.8 RNA processing; addition of the 5 cap and poly(A) tail

49 Figure 17.9 RNA processing: RNA splicing

50 Figure 17.10 The roles of snRNPs and spliceosomes in mRNA splicing

51 Figure 17.11 Correspondence between exons and protein domains

52 Figure 17.12 Translation: the basic concept

53 Figure 17.13a The structure of transfer RNA (tRNA)

54 Figure 17.13b The structure of transfer RNA (tRNA)

55 Figure 17.14 An aminoacyl-tRNA synthetase joins a specific amino acid to a tRNA

56 Figure 17.15 The anatomy of a functioning ribosome

57 Figure 17.16 Structure of the large ribosomal subunit at the atomic level

58 Figure 17.17 The initiation of translation

59 Figure 17.18 The elongation cycle of translation

60 Figure 17.19 The termination of translation

61 Figure 17.20 Polyribosomes

62 Figure 17.21 The signal mechanism for targeting proteins to the ER

63 Table 17.1 Types of RNA in a Eukaryotic Cell

64 Figure 17.22 Coupled transcription and translation in bacteria

65 Figure 17.23 The molecular basis of sickle-cell disease: a point mutation

66 Figure 17.24 Categories and consequences of point mutations: Base-pair insertion or deletion

67 Figure 17.24 Categories and consequences of point mutations: Base-pair substitution

68 Figure 17.25 A summary of transcription and translation in a eukaryotic cell

69 Figure 18.19 Regulation of a metabolic pathway

70 Figure 18.20a The trp operon: regulated synthesis of repressible enzymes

71 Figure 18.20b The trp operon: regulated synthesis of repressible enzymes (Layer 1)

72 Figure 18.20b The trp operon: regulated synthesis of repressible enzymes (Layer 2)

73 Figure 18.21a The lac operon: regulated synthesis of inducible enzymes

74 Figure 18.21b The lac operon: regulated synthesis of inducible enzymes

75 Figure 18.22a Positive control: cAMP receptor protein

76 Figure 18.22b Positive control: cAMP receptor protein

77 Figure 19.2 Part of a family of identical genes for ribosomal RNA

78 Figure 19.3 The evolution of human  -globin and  -globin gene families

79 Figure 19.5 Retrotransposon movement

80 Figure 19.6 DNA rearrangement in the maturation of an immunoglobulin (antibody) gene

81 Figure 19.7 Opportunities for the control of gene expression in eukaryotic cells

82 Figure 19.8 A eukaryotic gene and its transcript

83 Figure 19.9 A model for enhancer action

84 Figure 21.6 Nuclear transplantation

85 Figure 21.7 Cloning a mammal

86 Figure 21.8 Working with stem cells

87 Figure 21.9 Determination and differentiation of muscle cells (Layer 1)

88 Figure 21.9 Determination and differentiation of muscle cells (Layer 2)

89 Figure 21.9 Determination and differentiation of muscle cells (Layer 3)

90 Figure 21.10 Sources of developmental information for the early embryo

91 Figure 21.11 Key developmental events in the life cycle of Drosophila

92 Figure 21.12 The effect of the bicoid gene, a maternal effect (egg-polarity) gene in Drosophila

93 Figure 21.13 Segmentation genes in Drosophila

94 Figure 19.10 Three of the major types of DNA-binding domains in transcription factors

95 Figure 19.11 Alternative RNA splicing

96 Figure 19.12 Degradation of a protein by a proteasome

97 Figure 19.13 Genetic changes that can turn proto-ocogenes into oncogenes

98 Figure 19.14 Signaling pathways that regulate cell growth (Layer 1)

99 Figure 19.14 Signaling pathways that regulate cell growth (Layer 2)

100 Figure 19.14 Signaling pathways that regulate cell growth (Layer 3)

101 Figure 19.15 A multi-step model for the development of colorectal cancer

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