1. 4-a The Bacteria The Prokaryotic Cell
pps. 77 – 106
The Prokaryotic Cell
Size, shape, arrangement of cells
Structures external to cell wall

2. (Membrane Transport Quiz)
Animations
Bacterial Motility4
(Bacterial Motility Quiz)
Membrane Transport4
(Membrane Transport Quiz)
Log on to:

3. Prokaryote vs Eukaryote
“Prenucleus”
“True nucleus”
One circular chromosome
Paired chromosomes
Not in a membrane
In nuclear membrane
No histones
Histones
Organelles
(Golgi, ER, cilia, etc.)
No organelles
Peptidoglycan cell walls
Polysaccharide cell walls
Binary fission
Mitotic spindle

4. Vast heterogeneous group
The Prokaryotic World
Vast heterogeneous group
Include bacteria, archaea
Ubiquitous in nature
Very small
Unicelluar

5. Differentiated by many factors
Morphology (shape)
Chemical composition (~staining)
Nutritional requirements
Biochemical activities
Sources of energy
Go through your Lab Manual and list Ex #s next to each of the factors above

6. Morphology, Shapes Coccus (plural = cocci; berries)
Spherical cells
Bacillus (plural = bacilli; small staffs)
Rod-shaped, often motile
Large surface area to volume and adsorption is more effective
Coccobacillus
Cells not perfectly round (as cocci)
Have ‘blunted’ ends, ‘oval’ shape

7. Spirillum (plural = spirilla)
Spiral or curved bodies, one or more ‘twists’
Rigid, fairly inflexible
Often motile by external flagella
Spirochetes
Also ‘spiral’ shaped, but more flexible
Motile by an internal flagellum, axial filament
Vibrio
Comma shaped cells, motile via flagella

8. Average size: 0.2 -1.0 µm  2 - 8 µm Basic shapes
Figures 4.1a, 4.2a, 4.2d, 4.4b, 4.4c

9. Arrangements, Groupings
Arrangement & groupings - useful identification characteristics
Cells can remain attached to each other as bacteria divide
Cocci tend to display more variation in grouping than rods
Cocci divide along more than one axis
Rods only divide along their short axis

10. Diplococci = pairs of cocci
Streptococci = chains of cocci
Staphylococci = clusters of geometrically arranged cocci (sometimes grape-like)
Tetrads = ‘packets’ of 4 cells
Sarcinus = ‘packets’ of 8 cells
Diplobacilli = pairs of cells
Streptobacilli = chains of cells

11. Figures 4.1, 4.2

12. Unusual shapes Most bacteria are monomorphic
Star-shaped Stella
Square Haloarcula
Most bacteria are monomorphic
A few are pleomorphic (Corynebacterium)
Figure 4.5

13. Structures External to the Cell Wall
Glycocalyx
Flagella
Axial filaments
Fimbriae, pili

14. Pili
Fimbriae
Flagellum
Glycocalyx
Cell wall

15. Glycocalyx The outer surface covered in Functions include:
Polysaccharide, protein, polyalcohols, amino sugars, spp specific
Functions include:
Attachment
Protection from desiccation
Protection from ‘attack’
Figure 4.6

16. 2 Types of Glycocalyx Capsules Slime layers Capsules are
Closely associated with cells
Does not ‘wash’ off easily
Slime layer is
More diffuse, easily washed off

17. Glycocalyx can be thick or thin, rigid or flexible
Observe with India ink
See dark cells with ‘clear outline’ around them
Stain does not penetrate glycocalyx
Stain?
See Ch 3, Fig 3.13a, p 72 & LM

18. Functions Attachment Streptococcus mutans Vibrio cholerae
Produces a slime layer
Forms a surface that allows other bacteria to aggregate on tooth surfaces
Results in dental plaque
Vibrio cholerae
Attach to intestinal villi of host
Results in cholera

19. Capsules and slime layers are hydrophilic
Avoid Desiccation
Capsules and slime layers are hydrophilic
Bind ‘extra’ water in the environment
Contribute to protection from desiccation
Also provide protection from loss of nutrients
Holds nutrients within the layer

20. It is difficult to engulf a bacterium that has a capsule
Avoid Phagocytosis
It is difficult to engulf a bacterium that has a capsule
Streptococcus pneumoniae
Able to cause pneumonia and ‘kill’ patient
Non-encapsulated cannot cause pneumonia
Klebsiella colonize respiratory tract

21. Capsules and Virulence
Bacteria
Disease
Bacillus anthracis
Streptococcus pneumoniae
Klebsiella
Streptococcus mutans

22. Flagella A tail-like structure Bacterial example:
Projects from the cell body of bacteria
Functions in movement
Bacterial example:
Helicobacter pylori
Uses multiple flagella to propel itself
Through mucus lining to reach stomach epithelium
Figure 4.6
Singular: Flagellum; whip

23. Flagella are Helical Filaments
Rotate like screws
Provide several kinds of bacterial motility
Consist of protein: flagellin
Attach to a protein ‘hook’
Connects to ‘basal body’ rings
Gram + microbes have 2 basal body rings
Gram negative have 4 rings

24. Gram negative bacterium
Note: 4 rings vs 2 in Gram +
Figure 4.8b

25. Flagella and Motility
Via rotation of the basal body
Rotational ‘speed’ can increase or decrease
Moves bacteria through liquid media

26. Flagella Variation Monotrichous (polar) Amphitrichous One flagellum
Vibrio cholera
Amphitrichous
Have a single flagellum on each end
Only one operates at a time
Allows bacteria to reverse course rapidly

27. Lophotrichous (one or both ends of cell)
Have multiple flagellum at same ‘spot’
Act in concert to move bacteria in single direction
Peritrichous
Have a flagella projecting in all directions
Escherichia coli

28. Flagella Arrangement

29. Move in one direction called a ‘run’
Flagella: Run, Tumble
Move in one direction called a ‘run’
Change in direction called ‘tumbles’
Interruptions in a run, changes direction
Caused by reversal of flagella rotation
Bacteria with many flagella
Proteus
Swarms, wavelike movement across media

30. Running and Tumbling View animation: Bacterial Motility4
Figure 4.9
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31. Move toward or away from stimuli: TAXIS
Due to chemical stimuli: chemotaxis
Or, light: phototaxis
If toward the stimuli, called an attractant
And the bacteria moves towards it with many ‘runs’ and few ‘tumbles’
If away from the stimuli, called a repellent
The frequency of ‘tumbles’ increases as it moves away from the stimulus

33. Flagella and Virulence
The flagellar protein called H antigen is used to identify serovars
Among Gram negative bacteria
(e.g., E. coli O157:H7)
At least 50 different H antigens for E. coli
Associated with foodborne epidemics (Ch 1, p. 20)

34. Endoflagella, movement only In spirochetes
Axial Filaments
Endoflagella, movement only
In spirochetes
Anchored at one end of a cell
Rotation causes cell to move in spiral motion
Fig 4.10

35. Axial Filaments and Virulence
Spirochetes
Move through body fluids
Treponema pallidum
Syphilis
Borrelia burgdorferi
Lyme disease
Fig 26.10
Fig 23.13

36. Fimbriae & Pili Are short, thin appendages
Fimbriae allow attachment to initiate disease
Pili join cells to transfer DNA from one cell to another called:
Fig 4.11
Conjugation
Fig 8.25

37. These structures consist of a protein called pilin
Fimbriae vs Pili
These structures consist of a protein called pilin
Divided into 2 types, different functions
Fimbriae
Pili

38. Fimbriae Characteristics
Occur at poles of cells, or all over
Number from a few to >hundreds
Enable a cell to adhere to surfaces
Example:
Neisseria gonorrhoreae
Causes gonorrhea
Fimbriae helps colonize mucus membranes
Fig 4.11

39. Usually longer than fimbriae Number only one or 2
Pili Characteristics
Usually longer than fimbriae
Number only one or 2
Pili join cells to transfer DNA
Process called conjugation
Fig 8.25

40. Q’s
1. The structure used by bacteria to transfer genetic information is:
Flagella
Pili
Glycocalyx
Ribosome
Prokaryotic cells
Have a single chromosome
Lack a nuclear membrane
Divide by binary fission
Have cell walls containing peptidoglycan
All of the above

41. Q’s 1. Which is not a function of glycocalyx
It forms pseudopodia for faster mobility of an organism
It can protect a bacterial cell from drying out
It can contribute to the disease-causing process
It allows a bacterium to stick to a host
All of these are involved in bacterial attachment except:
Fimbriae
Pili
Capsules
Axial filaments

42. Q’s The cell arrangement shown here is:
Streptococcus
Staphylococcus
Diplococcus
Tetrads
Sarcinae
The plane in which a bacterium divides determines the arrangement.
True
False

43. Q’s What is taxis? What are the 3 parts of a flagellum?
Movement towards a stimulus
Movement toward or away from a stimulus
Movement towards light
Movement away from a stimulus
What are the 3 parts of a flagellum?
Tubulin, flagellin, basal body
Flagellin, filament, hook
Filament, hook, basal body
Tubulin, hook, filament

44. Q’s
Which of the following is NOT a structure found in prokaryotic cells?
Cilia
Axial filaments
Peritrichous flagella
Flagella
Pili