1. Functional Anatomy of Prokaryotic and Eukaryotic Cells
Chapter 4
Functional Anatomy of Prokaryotic and Eukaryotic Cells
Lectures prepared by Christine L. Case
© 2013 Pearson Education, Inc. 1

2. 2

3. Prokaryotic and Eukaryotic Cells
Prokaryote comes from the Greek words for prenucleus.
Eukaryote comes from the Greek words for true nucleus.

4. One circular chromosome, not in a membrane
Prokaryote
Eukaryote
One circular chromosome, not in a membrane
No organelles
Bacteria: peptidoglycan cell walls
Archaea: pseudomurein cell walls
Binary fission
Paired chromosomes, in nuclear membrane
Organelles
Polysaccharide cell walls
Mitotic spindle

5. Prokaryotic Cells: Shapes
Average size: 0.2–1.0 µm  2–8 µm
Most bacteria are monomorphic
A few are pleomorphic

6. Figure 4.9b Flagella and bacterial motility.
A Proteus cell in the swarming stage may have more than 1000 peritrichous flagella.

7. Basic Shapes Bacillus (rod-shaped) Coccus (spherical or circular)
Spiral
Spirillum
Vibrio
Spirochete

8. Plane of division Diplococci Streptococci
Figure 4.1a Arrangements of cocci.
Plane of division
Diplococci
Streptococci

9. Figure 4.2ad Bacilli.
Single bacillus
Coccobacillus

10. Figure 4.4 Spiral bacteria.
Vibrio
Spirillum
Spirochete

11. Bacillus or Bacillus
Scientific name: Bacillus
Shape: bacillus

12. Figure 4.5a Star-shaped and rectangular prokaryotes.
Star-shaped bacteria

13. Figure 4.5b Star-shaped and rectangular prokaryotes.
Rectangular bacteria

14. Arrangements Pairs: diplococci, diplobacilli Clusters: staphylococci
Chains: streptococci, streptobacilli

15. Plane of division Diplococci Streptococci Staphylococci
Figure 4.1ad Arrangements of cocci.
Plane of division
Diplococci
Streptococci
Staphylococci

16. Figure 4.2b-c Bacilli.
Streptobacilli
Diplobacilli

17. Figure 4.6 The Structure of a Prokaryotic Cell.
The drawing below and the
micrograph at right show a bacterium
sectioned lengthwise to reveal the
internal composition. Not all bacteria
have all the structures shown; only structures labeled in red are found in
all bacteria.
Cell wall
Capsule
Although the nucleoid appears
split in the photomicrograph,
the thinness of the “slice” does
not convey theobject’s depth.
Pilus
Cytoplasm
70S Ribosomes
Plasma membrane
Nucleoid containing DNA
Inclusions
Plasmid
Fimbriae
Capsule
Cell wall
Plasma
membrane
Flagella
© 2013 Pearson Education, Inc. .

18. Glycocalyx Outside cell wall Usually sticky Capsule: neatly organized
Capsules prevent phagocytosis
Hard to get rid of
Slime layer: unorganized and loose
Can be rinsed off with disinfectants
Extracellular polysaccharide allows cell to attach
Important component of biofilms

19. Figure 24.12 Streptococcus pneumoniae, the cause of pneumococcal pneumonia.

20. Flagella Outside cell wall Made of chains of flagellin
Attached to a protein hook
Anchored to the wall and membrane by the basal body
Rotate flagella to run or tumble
Move toward or away from stimuli (taxis)

21. Parts and attachment of a flagellum of a gram-positive bacterium
Figure 4.8b The structure of a prokaryotic flagellum.
Flagellum
Gram-
positive
Filament
Cell wall
Hook
Basal body
Peptidoglycan
Plasma
membrane
Cytoplasm
Parts and attachment of a flagellum of a
gram-positive bacterium

22. Parts and attachment of a flagellum of a gram-negative bacterium
Figure 4.8a The structure of a prokaryotic flagellum.
Flagellum
Filament
Gram-
negative
Cell wall
Hook
Basal body
Peptidoglycan
Outer
membrane
Plasma
membrane
Cytoplasm
Parts and attachment of a flagellum of a gram-negative bacterium

23. Run Tumble Run Tumble Run Tumble
Figure 4.9a Flagella and bacterial motility.
Run
Tumble
Run
Tumble
Run
Tumble
A bacterium running and tumbling. Notice that the direction of flagellar rotation (blue arrows) determines which of these movements occurs. Gray arrows indicate direction of movement of the microbe.

24. Figure 4.7 Arrangements of bacterial flagella.
Peritrichous
Monotrichous and polar
Lophotrichous and polar
Amphitrichous and polar

25. Axial Filaments Also called endoflagella In spirochetes
Anchored at one end of a cell
Rotation causes cell to move

26. Figure 4.10b Axial filaments.
Outer sheath
Cell wall
Axial filament
A diagram of axial filaments wrapping around part of a spirochete (see Figure 11.26a for a cross section of axial filaments)

27. Fimbriae and Pili Found on many gram NEGATIVE bacteria
Short, thin, hairlike appendages
2 Types:
Fimbriae
Allow attachment which usually leads to infection
Different numbers
Pili
Facilitate transfer of DNA from one cell to another
Motility
1-2 per cell

28. Figure 4.11 Fimbriae.
Fimbriae

29. The Cell Wall Prevents osmotic lysis
Made of peptidoglycan (in bacteria)
CELL WALL

30. Differences in Cell Walls
GRAM POSITIVE
GRAM NEGATIVE
Thick peptidoglycan
Teichoic acids
May regulate movement of cations
Penicillin sensitive
Thin peptidoglycan
Outer membrane
Lipopolysaccharides
Protection from phagocytes, complement, and antibiotics
Tetracycline Sensitive

31. Figure 4.13b-c Bacterial cell walls.
Peptidoglycan
Wall teichoic acid
Lipoteichoic
acid
Cell wall
Plasma
membrane
Protein
O polysaccharide
Gram-positive cell wall
Core polysaccharide
Core polysaccharide
Lipid A
Lipopolysaccharide
O polysaccharide
Parts of the LPS
Lipid A
Porin protein
Lipoprotein
Outer membrane
Phospholipid
Cell wall
Peptidoglycan
Plasma
membrane
Periplasm
Protein
Gram-negative cell wall

32. The Gram Stain Mechanism
Crystal violet-iodine crystals form in cell
Gram-positive
Alcohol dehydrates peptidoglycan
CV-I crystals do not leave
Gram-negative
Alcohol dissolves outer membrane and leaves holes in peptidoglycan
CV-I washes out

33. Table 4.1 Some Comparative Characteristics of Gram-Positive and Gram-Negative Bacteria

34. Atypical Cell Walls Acid-fast cell walls Like gram-positive cell walls
Waxy lipid (mycolic acid) bound to peptidoglycan
2 Genera:
Mycobacterium
Nocardia

35. Figure 24.8 Mycobacterium tuberculosis.

36. Atypical Cell Walls Mycoplasmas Archaea Lack cell walls
Sterols in plasma membrane
Archaea
Wall-less
Walls without peptidoglycan

37. Damage to the Cell Wall Lysozyme- enzyme that digests peptidoglycan
Penicillin- inhibits peptide bridges in peptidoglycan
Protoplast- wall-less cell gram-positive cell
Spheroplast- wall-less gram-negative cell
Protoplasts and spheroplasts are susceptible to osmotic lysis
L forms-wall-less cells that swell into irregular shapes

38. Plasma membrane of cell
Figure 4.14a Plasma membrane.
Lipid
bilayer of plasma
membrane
Peptidoglycan
Outer membrane
Plasma membrane of cell

39. The Plasma Membrane Selectively permeable Produce ATP
Damage to the membrane by alcohols, ammonium (detergents), and polymyxin antibiotics causes leakage of cell contents
Phospholipid bilayer
Proteins:
Peripheral proteins- inner or outer surface
Act as enzymes
Support
Changes in shape during movement
Integral proteins (transmembrane)-penetrate membrane completely
Channels or pores through which substance leave and enter the cell

40. Lipid bilayer of plasma membrane
Figure 4.14b Plasma membrane.
Outside
Lipid
bilayer
Pore
Peripheral protein
Inside
Polar head
Integral
proteins
Nonpolar fatty
acid tails
Peripheral protein
Polar head
Lipid bilayer of plasma membrane

41. Movement of Materials across Membranes
Simple diffusion: movement of a solute from an area of high concentration to an area of low concentration

42. Movement of Materials across Membranes
Facilitated diffusion: solute combines with a transporter protein in the membrane

43. Movement of Materials across Membranes
Osmosis: the movement of water across a selectively permeable membrane from an area of high water to an area of lower water concentration

44. Movement of Materials across Membranes
Through lipid layer
Aquaporins (water channels)

45. Figure 4.18c-e The principle of osmosis.
Plasma
membrane
Cytoplasm
Solute
Water
Isotonic solution.
No net movement
of water occurs.
Hypotonic solution. Water moves
into the cell. If the cell wall is strong, it contains the swelling. If the cell wall is weak or damaged, the cell bursts (osmotic lysis).
Hypertonic solution.
Water moves out of the
cell, causing its cytoplasm to shrink (plasmolysis).

46. Movement of Materials across Membranes
Active transport: requires a transporter protein and ATP
Group translocation: requires a transporter protein and the substance going across the protein is CHEMICALLY changed

47. Cytoplasm The substance inside the plasma membrane Contains 80% water
Contains major structures of the cell

48. Genetic Information
Bacterial chromosome- genetic information for the cell’s structure and function;usually circular
Plasmid- extrachromosomal genetic information; may carry genes for antibiotic resistance, tolerance to metals, toxin production

49. The Prokaryotic Ribosome
Protein synthesis
70S
50S + 30S subunits

50. Inclusions
Reserve deposits
Store nutrients to have in times of need.

51. Endospores Resting cells Resistant to desiccation, heat, chemicals
Bacillus, Clostridium
Sporulation: endospore formation
Germination: return to vegetative state

52. An endospore of Bacillus subtilis
Figure 4.21b Formation of endospores by sporulation.
Endospore
An endospore of Bacillus subtilis

53. Figure 4.21a Formation of endospores by sporulation.
Cell wall
Cytoplasm
Spore septum begins to isolate
newly replicated DNA and a
small portion of cytoplasm.
Plasma membrane starts to
surround DNA, cytoplasm, and
membrane isolated in step 1.
Plasma
membrane
Bacterial
chromosome
(DNA)
Sporulation, the process of endospore
formation
Spore septum surrounds isolated portion,
forming forespore.
Two
membranes
Peptidoglycan
layer forms between membranes.
Spore coat forms.
Endospore is freed
from cell.

54. Figure 4.22a Eukaryotic cells showing typical structures.
PLANT CELL
ANIMAL CELL
Peroxisome
Flagellum
Nucleus
Mitochondrion
Microfilament
Nucleolus
Golgi complex
Golgi complex
Microtubule
Basal body
Vacuole
Cytoplasm
Chloroplast
Microfilament
Ribosome
Lysosome
Cytoplasm
Centrosome:
Centriole
Pericentriolar material
Smooth endoplasmic
reticulum
Cell wall
Ribosome
Microtubule
Peroxisome
Rough endoplasmic
reticulum
Nucleus
Nucleolus
Mitochondrion
Smooth endoplasmic
reticulum
Plasma membrane
Highly schematic diagram of a composite eukaryotic cell,
half plant and half animal
Plasma membrane

55. Figure 4.23a-b Eukaryotic flagella and cilia.
Flagellum
Cilia
A micrograph of
Euglena, a chlorophyll-
containing alga, with its
flagellum.
A micrograph of
Tetrahymena, a common
freshwater protozoan,
with cilia.

56. Flagella and Cilia Microtubules- long hollow tubes
9 pairs + 2 arrangement
Flagella- move in a wavelike manner.

57. The Cell Wall and Glycocalyx
Plants, algae, fungi
Cellulose (Plants)
Chitin (Fungi)
Glucan and Mannan (Yeasts)
Glycocalyx
Carbohydrates extending from plasma membrane
Strengthens cell surface, attachment of cells together, cell-cell recognition

58. The Plasma Membrane Phospholipid bilayer Peripheral proteins
Integral proteins
Transmembrane proteins
Sterols- important in cells without cell wall because it offers stability to the cell
Glycocalyx carbohydrates

59. The Plasma Membrane
Selective permeability allows passage of some molecules
Simple diffusion
Facilitative diffusion
Osmosis
Active transport
Endocytosis
Phagocytosis: pseudopods extend and engulf particles
Pinocytosis: membrane folds inward, bringing in fluid and dissolved substances

60. Table 4.2 Principal Differences between Prokaryotic and Eukaryotic Cells

61. Cytoplasm Cytosol: fluid portion of cytoplasm
Cytoskeleton: microfilaments, intermediate filaments, microtubules
Provides support and shape and assists in transportation of substances.
Cytoplasmic streaming: movement of cytoplasm throughout cells

62. Ribosomes Protein synthesis 80S 70S Membrane-bound: attached to ER
Free: in cytoplasm
70S
In chloroplasts and mitochondria

63. Organelles Nucleus: contains chromosomes Lysosome: digestive enzymes
The control center
Most prominent internal organelle.
Composed of:
Nuclear envelope- 2 parallel membranes that are separated by a space; also has small pores on the surface
Nucleoplasm- inside space of the nucleus
Nucleolus- granular mass; RNA synthesis and ribosomal subunit collection area
Lysosome: digestive enzymes
Vacuole: brings food into cells and provides support

64. Nuclear pore(s) Nuclear envelope Nucleolus Chromatin
Figure 4.24c The eukaryotic nucleus.
Nuclear
pore(s)
Nuclear
envelope
Nucleolus
Chromatin

65. Endoplasmic Reticulum
Microscopic tunnel system made of cisternae
Functions:
Storage
Transportation
2 types:
Rough endoplasmic reticulum (RER)- continuous with the nuclear envelope; has ribosomes on surface; transports materials from nucleus to the cytoplasm and is responsible for protein synthesis.
Smooth endoplasmic reticulum (SER)- continuous with RER; no ribosomes; is responsible for nutrient processing and synthesis and storage of lipids, electrolytes, and other substances.

66. Nuclear envelope Ribosomes Cisternae Smooth ER Ribosomes Rough ER
Figure 4.25 Rough endoplasmic reticulum and ribosomes.
Nuclear envelope
Ribosomes
Cisternae
Smooth ER
Ribosomes
Rough ER

67. Golgi Complex Modify and secrete proteins 3 types of vesicles:
Transitional- membrane bound packets of proteins that come to the Golgi from the ER for modification.
Condensing- membrane bound packets of proteins that pinch off from the Golgi and are used by organelles on the inside of the cell
Secretory-membrane bound packets of proteins that pinch off from the Golgi and are transported outside of the cell

68. Figure 4.26 Golgi complex.
Secretory
vesicles
Transfer
vesicles
Cisternae
Transport
vesicle from
rough ER

69. Lysosomes
Contain digestive enzymes capable of breaking down substances
Vacuoles
Temporary storage units
Help to bring food into cell
Take in water

70. Transmission electron micrographs of plant and animal cells.
Figure 4.22b Eukaryotic cells showing typical structures.
Animal cell, an
antibody-secreting
plasma cell
Peroxisome
Nucleus
Vacuole
Chloroplast
Plasma membrane
Golgi complex
Nucleus
Mitochondrion
Cytoplasm
Nucleolus
Cell wall
Algal cell
(Tribonema vulgare)
Mitochondrion
Rough endoplasmic
reticulum
Lysosome
Transmission electron micrographs of plant and animal cells.

71. Mitochondria “Powerhouse” of the cell
Supplies most of the energy for the cell
Number varies
Carries out cellular respiration and produces ATP.

72. Chloroplasts
Algae
Helps with photosynthesis

73. Peroxisomes Similar to lysosomes. Store enzymes
Catalase- breaks down hydrogen peroxide (H2O2)

74. Centrosome Composed of protein fibers and centrioles
Plays critical role in cellular division
Makes microtubles

75. Figure 10.2 A model of the origin of eukaryotes.

76. Endosymbiotic Theory
What are the fine extensions on the protozoan shown on the following slide?
Larger bacteria engulfed smaller bacteria. Their relationship became symbiotic.