1. Cell Structure and Function
Chapter 4

2. 4.1 What is a Cell?
Each cell has a plasma membrane, cytoplasm, and a nucleus (in eukaryotic cells) or a nucleoid (in prokaryotic cells)

3. a Bacterial cell (prokaryotic)
cytoplasm
DNA
plasma membrane
a Bacterial cell (prokaryotic)
Fig. 4.3, p. 52

4. b Plant cell (eukaryotic)
cytoplasm
DNA in nucleus
plasma membrane
b Plant cell (eukaryotic)
Fig. 4.3, p. 52

5. c Animal cell (eukaryotic)
cytoplasm
DNA in nucleus
plasma membrane
c Animal cell (eukaryotic)
Fig. 4.3, p. 52

6. Components of Cell Membranes
Lipid bilayer

7. “head”
two “tails”
Fig. 4.4, p. 53

8. fluid
lipid bilayer
fluid
Fig. 4.4, p. 53

9. extracellular environment one layer of lipids one layer of lipids
membrane
protein
cytoplasm
Fig. 4.4, p. 53

10. Cell Size and Shape
Surface-to-volume ratio limits cell size

11. Key Concepts: WHAT ALL CELLS HAVE IN COMMON
Each cell has a plasma membrane, a boundary between its interior and the outside environment
The interior consists of cytoplasm and an innermost region of DNA

12. 4.2 How Do We See Cells? Three key points of the cell theory:
All organisms consist of one or more cells
The cell is the smallest unit that retains the capacity for life
A cell arises from the growth and division of another cell

13. Relative Sizes

14. Fig. 4.6, p. 54

15. Microscopes
Different microscopes use light or electrons to reveal details of cell shapes or structures

16. path of light rays (bottom to top) to eye
Ocular lens enlarges
primary image formed
by objective lenses.
prism that
directs rays to
ocular lens
Objective lenses (those closest
to specimen) form the primary
image. Most compound light
microscopes have several.
stage supports
microscope slide
Condenser lenses focus
light rays through specimen.
illuminator
light source (in base)
Fig. 4.7, p. 55

17. incoming electron beam
condenser lens (focuses a beam of electrons onto specimen)
specimen
objective lens
intermediate lens
projector lens
viewing screen (or
photographic film)
Fig. 4.7, p. 55

18. Five Different Views

19. Key Concepts: MICROSCOPES
Microscopic analysis supports three generalizations of the cell theory:
Each organism consists of one or more cells and their products
A cell has a capacity for independent life
Each new cell is descended from a living cell

20. 4.3 Membrane Structure and Function
Each cell membrane is a boundary (lipid bilayer) that controls the flow of substances across it
Fluid mosaic model
Membrane is composed of phospholipids, sterols, proteins, and other components
Phospholipids drift within the bilayer

21. Membrane Proteins
Many proteins are embedded in or attached to cell membrane surfaces
Receptors, transporters, communication proteins, and adhesion proteins
Plasma (outer) membrane also incorporates recognition proteins

22. Common Membrane Proteins

23. A glucose transporter
allows glucose to cross
the membrane through
a channel in its interior.
An ATP synthase,
which makes ATP when
H+ crosses a membrane
through its interior.
A calcium pump
moves calcium ions
across the membrane;
requires ATP energy.
EXTRACELLULAR FLUID
LIPID
BILAYER
B cell receptor.
It binds to bacteria,
other foreign agents.
Recognition protein that
identifies a cell as belonging
to one’s own body.
phospholipid
protein filaments of the cytoskeleton
CYTOPLASM
Fig. 4.9, p. 57

24. Membrane Structure Studies

25. fusion into hybrid cell proteins from both cells in fused membrane
human cell
mouse cell
fusion into
hybrid cell
proteins from
both cells
in fused
membrane
Fig. 4.10, p. 57

26. Key Concepts: COMPONENTS OF CELL MEMBRANES
All cell membranes are mostly a lipid bilayer (two layers of lipids) and a variety of proteins
The proteins have diverse tasks, including control over which water-soluble substances cross the membrane at any given time

27. 4.4 Introducing Prokaryotic Cells
Bacteria and archaeans
The simplest cells
The groups with greatest metabolic diversity
Biofilms
Shared living arrangements of prokaryotes

28. Prokaryote Structure Cell wall Flagella Pili Surrounds plasma membrane
Used for motion
Pili
Protein filaments used for attachment
“Sex” pilus transfers genetic material

29. Prokaryote Structure

30. Prokaryote Structure

31. Most prokaryotic cells have a cell wall outside the plasma membrane,
cytoplasm,
with ribosomes
bacterial flagellum
Most prokaryotic cells have a cell
wall outside the plasma membrane,
and many have a thick, jellylike
capsule around the wall.
cell
wall
plasma membrane
DNA in nucleoid
pilus
capsule
Fig. 4.11, p. 58

32. 4.5 Microbial Mobs
Biofilm formation

33. Key Concepts: PROKARYOTIC CELLS
Archaeans and bacteria are prokaryotic cells which have few, if any, internal membrane-enclosed compartments
In general, they are the smallest and structurally the simplest cells

34. 4.6 Introducing Eukaryotic Cells
Start with a nucleus and other organelles
Carry out specialized functions inside a cell

35. plasma
membrane
nucleus
mitochondria
Fig. 4.14, p. 60

36. cell wall plasma membrane central vacuole nucleus chloroplast
Fig. 4.14, p. 60

37. Components of Eukaryotic Cells

38. 4.7 Components of The Nucleus
Nucleus separates DNA from cytoplasm
Chromatin (all chromosomal DNA with proteins)
Chromosomes (condensed)
Nucleolus assembles ribosome subunits
Nuclear envelope encloses nucleoplasm
Pores, receptors, transport proteins

39. Nucleus and Nuclear Envelope

40. Nucleus and Nuclear Envelope

41. Nucleus and Nuclear Envelope

42. nuclear envelope
chromatin
nucleolus
cytoplasm
Fig. 4.15, p. 61

43. nucleus pore across the nuclear envelope nucleoplasm nucleolus
chromatin
nuclear envelope’s
outer lipid bilayer
merging with an
ER membrane
Fig. 4.15, p. 61

44. nuclear pore nuclear envelope (two lipid bilayers) cytoplasm
Fig. 4.15, p. 61

45. 4.8 The Endomembrane System
Endoplasmic reticulum (ER)
An extension of the nuclear envelope
RER modifies new polypeptide chains
SER makes lipids; other metabolic functions
Golgi bodies
Further modify polypeptides
Assemble lipids

46. The Endomembrane System
Vesicles
Endocytic and exocytic: Transport or store polypeptides and lipids
Peroxisomes: Digest fatty acids and amino acids; break down toxins and metabolic by-products
Lysosomes: Intracellular digestion (animals)
Central vacuole: Storage; fluid pressure (plants)

47. Endomembrane System

48. Endomembrane System

49. Endomembrane System

50. nucleus
rough ER
smooth ER
Golgi body
vesicles
Fig. 4.16, p. 62

51. the cell nucleus rough ER chromatin pore cytoplasm nucleolus
nuclear envelope
(two lipid bilayers)
ribosome
vesicle
the cell nucleus
rough ER
Fig. 4.16, p. 62

52. plasma membrane smooth ER Golgi body smooth ER channel, cross-section
budding vesicle
plasma membrane
smooth ER
Golgi body
Fig. 4.16, p. 62

53. 4.9 Mitochondria and Chloroplasts
Break down organic compounds by aerobic respiration (oxygen-requiring)
Produce ATP
Chloroplasts
Produce sugars by photosynthesis

54. Mitochondria and Chloroplasts

55. two outer membranes stroma thylakoids (inner membrane
system folded into
flattened disks)
Fig. 4.18, p. 63

56. 4.10 Visual Summary: Plant Cells

57. Visual Summary: Animal Cells

58. a Typical plant cell components.
CELL WALL
CHLOROPLAST
CENTRAL VACUOLE
NUCLEUS
nuclear envelope
nucleolus
DNA in
nucleoplasm
CYTOSKELETON
microtubules
microfilaments
intermediate
filaments
(not shown)
RIBOSOMES
ROUGH ER
MITOCHONDRION
SMOOTH ER
PLASMODESMA
GOLGI BODY
PLASMA MEMBRANE
LYSOSOME-LIKE VESICLE
a Typical plant cell components.
Fig. 4.19, p.65

59. b Typical animal cell components.
NUCLEUS
nuclear envelope
nucleolus
DNA in
nucleoplasm
CYTOSKELETON
microtubules
microfilaments
intermediate
filaments
RIBOSOMES
ROUGH ER
MITOCHONDRION
SMOOTH ER
CENTRIOLES
GOLGI BODY
LYSOSOME
PLASMA MEMBRANE
b Typical animal cell components.
Fig. 4.19, p. 64

60. b Typical animal cell components.
NUCLEUS
nuclear envelope
nucleolus
DNA in
nucleoplasm
CYTOSKELETON
microtubules
microfilaments
intermediate
filaments
RIBOSOMES
ROUGH ER
MITOCHONDRION
CENTRIOLES
SMOOTH ER
GOLGI BODY
PLASMA MEMBRANE
LYSOSOME
Stepped Art
b Typical animal cell components.
Fig. 4-19, p. 64

61. 4.11 Cell Surface Specializations
Most prokaryotes, protists, fungi, all plant cells have a cell wall around their plasma membrane
Protects, supports, maintains cell shape
Primary and secondary cell walls
Plasmodesmata across cell walls connect plant cells

62. Plant Cell Walls

63. Plant Cell Walls

64. plasma membrane middle cytoplasm lamella primary cell wall secondary
(added in
layers)
primary
cell wall
pipeline
made of
abutting
cell walls
Fig. 4.20, p. 66

65. middle lamella Plasmodesmata plasmodesma middle lamella
Fig. 4.20, p. 66

66. Plant Cuticle
Protective surface secretion, limits water loss

67. thick, waxy cuticle at leaf surface cell of leaf epidermis
photosynthetic
cell inside leaf
Fig. 4.21, p. 67

68. Extracellular Matrixes
Surrounds cells of specific tissues

69. Animal Cell Junctions Connect cells of animals
Adhering junctions, tight junctions, gap junctions

70. (extracellular matrix) adhering junction
free surface of
epithelial tissue
different kinds of
tight junctions
gap junction
basement membrane
(extracellular matrix)
adhering junction
Fig. 4.23, p. 67

71. Key Concepts: EUKARYOTIC CELLS
Cells of protists, plants, fungi, and animals are eukaryotic; they have a nucleus and other membrane-enclosed compartments
They differ in internal parts and surface specializations

72. 4.12 The Dynamic Cytoskeleton
Components of the cytoskeleton
Microtubules
Microfilaments
Intermediate filaments (in most)

73. Fig. 4.12, p. 59

74. Fig. 4.12, p. 59

75. Fig. 4.12, p. 59

76. Components of the Cytoskeleton

77. tubulin
subunit
25 nm
Fig. 4.24, p. 68

78. actin
subunit
5–7 nm
Fig. 4.24, p. 68

79. one
polypeptide
chain
8–12 nm
Fig. 4.24, p. 68

80. Cytoskeleton Function
Organizes and moves cell parts
Reinforces cell shape
Interactions between motor proteins and microtubules in cilia, flagella, and pseudopods can move the whole cell

81. Motor Protein: Kinesin
Moves vesicles along microtubules

82. Flagellum and Pseudopods

83. Eukaryotic Flagella and Cilia: Dynein

84. Eukaryotic Flagella and Cilia: Dynein

85. basal body pair of microtubules in a central sheath protein spokes
plasma
membrane
pair of
microtubules
dynein arms
dynein arms
basal body
Fig. 4.27, p. 69

86. Key Concepts: A LOOK AT THE CYTOSKELETON
Diverse protein filaments reinforce a cell’s shape and keep its parts organized
As some filaments lengthen and shorten, they move chromosomes or other structures to new locations

87. Animation: Animal cell junctions
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88. Animation: Cell membranes
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89. Animation: Common eukaryotic organelles
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90. Animation: Cytoskeletal components
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91. Animation: Flagella structure
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92. Animation: How a light microscope works
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93. Animation: How an electron microscope works
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94. Animation: Lipid bilayer organization
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95. Animation: Motor proteins
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96. Animation: Nuclear envelope
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97. Animation: Overview of cells
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98. Animation: Plant cell walls
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99. Animation: Structure of a chloroplast
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100. Animation: Structure of a mitochondrion
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101. Animation: Surface-to-volume ratio
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102. Animation: The endomembrane system
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103. Animation: Typical prokaryotic cell
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