1. The Prokaryotes: Domains Bacteria and Archaea11
The Prokaryotes: Domains Bacteria and Archaea

3. Table 11.1 Classification of Selected Prokaryotes*

4. Gram-Negative Bacteria
Learning Objectives 11-1 Differentiate the alphaproteobacteria described in this chapter by drawing a dichotomous key Differentiate the betaproteobacteria described in this chapter by drawing a dichotomous key Differentiate the gammaproteobacteria described in this chapter by drawing a dichotomous key Differentiate the deltaproteobacteria described in this chapter by drawing a dichotomous key Differentiate the epsilonproteobacteria described in this chapter by drawing a dichotomous key.

5. Proteobacteria
From the mythological Greek god Proteus, who could assume many shapes
Gram-negative
Chemoheterotrophic
Largest taxonomic group of bacteria
Five classes

6. The Alphaproteobacteria
Most are capable of growing with very low levels of nutrients
Many have stalks or buds known as prosthecae

7. The Alphaproteobacteria
Pelagibacter
One of the most abundant microorganisms in oceans
Extremely small
Advantage in low-nutrient environments
Important role in Earth's carbon cycle

8. The Alphaproteobacteria
Azospirillum
Grows in soil, using nutrients excreted by plants
Forms associations with roots
Fixes nitrogen
Acetobacter and Gluconobacter
Convert ethanol into acetic acid

9. The Alphaproteobacteria
Rickettsia
Obligate intracellular parasites
Cause spotted fevers
R. prowazekii: epidemic typhus
R. typhi: endemic murine typhus
R. rickettsii: Rocky Mountain spotted fever
Transmitted by insect and tick bites
Ehrlichia
Transmitted by ticks
Cause ehrlichiosis

10. scattered rickettsias within the cell and the compact masses of
Figure Rickettsias.
Slime
layer
Scattered
rickettsias
Chicken
embryo
cell
Nucleus
Rickettsias grow
only within a host cell,
such as the chicken
embryo cell shown
here. Note the
scattered rickettsias
within the cell and the
compact masses of
rickettsias in the cell
nucleus.
Masses of
rickettsias in
nucleus
A rickettsial cell
that has just been
released from a host
cell

11. The Alphaproteobacteria
Caulobacter and Hyphomicrobium
Found in low-nutrient aquatic environments
Form stalks and prosthecae
Reproduce via budding rather than binary fission

12. Figure Caulobacter.

13. Hypha Holes in filter Bud Bud
Figure Hyphomicrobium, a type of budding bacterium.
Hypha
Holes in
filter
Bud
Bud

14. The Alphaproteobacteria
Rhizobium and Bradyrhizobium
Fix nitrogen in the roots of leguminous plants
Known by the common name of rhizobia
Agrobacterium
Plant pathogen; causes crown gall
Inserts a plasmid into plant cells, inducing a tumor

15. Figure 9.19 Crown gall disease on a rose plant.

16. The Alphaproteobacteria
Bartonella
Human pathogen
B. henselae: cat-scratch disease
Brucella
Obligate parasite of mammals; survives phagocytosis
Causes brucellosis

17. The Alphaproteobacteria
Nitrobacter and Nitrosomonas
Chemoautotrophic; use inorganic chemicals as energy source; CO2 as carbon source
Nitrosomonas: NH4+ → NO2–
Nitrobacter: NO2– → NO3–

18. The Alphaproteobacteria
Wolbachia
Endosymbiont of insects
Affects reproduction of insects

19. Applications of Microbiology 11.1a

20. Unfertilized female infected Infected female offspring
Applications of Microbiology 11.1b
Males
Females
Neither infected
Uninfected offspring
Male infected
No offspring
Female infected
Infected offspring
Both infected
Infected offspring
Wolbachia
Unfertilized female infected
Infected female offspring

21. Check Your Understanding
 Make a dichotomous key to distinguish the alphaproteobacteria described in this chapter. (Hint: See page 292 for a completed example. 11-1

22. The Betaproteobacteria
Acidithiobacillus
Chemoautotrophic; oxidize sulfur to sulfates: H2S → SO42–
Spirillum
Found in freshwater
Move via flagella
Sphaerotilus
Found in freshwater and sewage
Form sheaths to aid in protection and nutrient gathering

23. Figure 11.4 Spirillum volutans.

24. Figure 11.5 Sphaerotilus natans.
Bacterial
cells
Sheath

25. The Betaproteobacteria
Burkholderia
B. cepacia: degrades more than 100 organic molecules
B. pseudomallei: causes meliodosis
Bordetella
Non-motile rods
B. pertussis: causes whooping cough

26. The Betaproteobacteria
Neisseria
N. gonorrhoeae: cause of gonorrhoea
N. meningitidis: cause of meningococcal meningitis
Zoogloea
Important in the activity of the activated sludge system

27. Bacteria Host-cell membrane
Figure The gram-negative coccus Neisseria gonorrhoeae.
Bacteria
Host-cell
membrane

28. Check Your Understanding
 Make a dichotomous key to distinguish the betaproteobacteria described in this chapter. 11-2

29. The Gammaproteobacteria
Thiotrichales
Beggiatoa
Grows in aquatic sediments
Chemoautotrophic; oxidize H2S to S0 for energy
Francisella
F. tularensis: causes tularemia

30. The Gammaproteobacteria
Pseudomonadales
Pseudomonas
Opportunistic pathogens; nosocomial infections
Metabolically diverse
Polar flagella; common in soil
P. aeruginosa: wound and urinary tract infections

31. Figure Pseudomonas.

32. The Gammaproteobacteria
Pseudomonadales (cont'd)
Azotobacter and Azomonas
Nitrogen-fixing
Moraxella
M. lacunata: causes conjunctivitis
Acinetobacter
A. baumanii: respiratory pathogen; resistant to antibiotics

33. The Gammaproteobacteria
Legionellales
Legionella
Found in streams, warm-water pipes, and cooling towers
Causes legionellosis
Coxiella
C. burnetii: causes Q fever; transmitted via aerosols or milk

34. Figure 24.13b Coxiella burnetii, the cause of Q fever.

35. The Gammaproteobacteria
Vibrionales
Found in aquatic habitats
V. cholerae causes cholera
V. parahaemolyticus causes gastroenteritis

36. Figure 11.8 Vibrio cholerae.

37. The Gammaproteobacteria
Enterobacteriales
Commonly called enterics — inhabit the intestinal tract; ferment carbohydrates
Facultative anaerobes
Peritrichous flagella

38. The Gammaproteobacteria
Enterobacteriales (cont'd)
Escherichia
E. coli: indicator of fecal contamination; causes foodborne disease and urinary tract infections
Salmonella
2400 serovars
Common form of foodborne illness
Salmonella typhi causes typhoid fever

39. The Gammaproteobacteria
Enterobacteriales (cont'd)
Shigella
Causes bacillary dysentery
Klebsiella
K. pneumoniae causes pneumonia
Serratia
Produces red pigment
Common cause of nosocomial infections

40. The Gammaproteobacteria
Enterobacteriales (cont'd)
Proteus
Swarming motility; colonies form concentric rings
Yersinia
Y. pestis causes plague
Transmitted via fleas
Erwinia
Plant pathogens

41. Proteus mirabilis with peritrichous flagella
Figure Proteus mirabilis.
Flagella
Proteus mirabilis with peritrichous
flagella
A swarming colony of Proteus
mirabilis, showing concentric rings
of growth

42. The Gammaproteobacteria
Enterobacteriales (cont'd)
Enterobacter
E. cloacae and E. aerogenes cause urinary tract infections and nosocomial infections
Cronobacter
Discovered in 2007
C. sakazakii causes meningitis; found in a variety of environments and foods

43. The Gammaproteobacteria
Pasteurellales
Pasteurella
Pathogen of domestic animals
P. multocida is transmitted to humans via animal bites
Haemophilus
Require X factor (heme) and V factor (NAD+, NADP+) in media
H. influenzae causes meningitis, earaches, and epiglottitis

44. Check Your Understanding
 Make a dichotomous key to distinguish the orders of gammaproteobacteria described in this chapter. 11-3

45. The Deltaproteobacteria
Bdellovibrio
Attacks other gram-negative bacteria
Desulfovibrionales
Use S0 or SO42– instead of O2 as final electron acceptors
Desulfovibrio is found in anaerobic sediments and intestinal tracts

46. Figure 11.10 Bdellovibrio bacteriovorus.

47. The Deltaproteobacteria
Myxococcales
Myxo = mucus
Move by gliding and leave a slime trail
Cells aggregate and form a fruiting body containing myxospores

48. Myxobacteria fruiting body
Figure Myxococcales.
Myxobacteria fruiting body
Myxospores
Myxospores are resistant
resting cells released from
sporangioles upon
favorable conditions.
Myxospores
Sporangiole
Germination
Myxospores germinate and
form gram-negative
vegetative cells, which
divide to reproduce.
Mounds of myxobacteria
differentiate into a mature
fruiting body, which
produces myxospores
packed within
sporangioles.
Vegetative growth cycle
Vegetative myxobacteria
are motile by gliding,
forming visible slime trails.
Mounding
Aggregations of
cells heap up into a
mound, an early
fruiting body.
Aggregation
Under favorable conditions, the
vegetative cells swarm to central
locations, forming an aggregation.

49. Check Your Understanding
 Make a dichotomous key to distinguish the deltaproteobacteria described in this chapter. 11-4

50. The Epsilonproteobacteria
Helical or curved; microaerophilic
Campylobacter
One polar flagellum
C. jejuni causes foodborne intestinal disease
Helicobacter
Multiple flagella
Cause peptic ulcers and stomach cancer

51. Figure 11.12 Helicobacter pylori.
Flagella

52. Check Your Understanding
 Make a dichotomous key to distinguish the epsilonproteobacteria described in this chapter. 11-5

53. The Nonproteobacteria Gram-Negative Bacteria
Learning Objective
11-6 Differentiate planctomycetes, chlamydias, Bacteroidetes, Cytophaga, and Fusobacteria by drawing a dichotomous key.
11-7 Compare and contrast purple and green photosynthetic bacteria with the cyanobacteria.
Describe the features of spirochetes and Deinococcus.

54. Cyanobacteria (The Oxygenic Photosynthetic Bacteria)
Carry out oxygenic photosynthesis
Many contain heterocysts that can fix nitrogen
Gas vesicles that provide buoyancy
Unicellular or filamentous

55. Filamentous cyanobacterium showing heterocysts, in which
Figure Cyanobacteria.
Heterocysts
Glycocalyx
Filamentous cyanobacterium
showing heterocysts, in which
nitrogen-fixing activity is located
A unicellular, nonfilamentous
cyanobacterium, Gloeocapsa. Groups
of these cells, which divide by binary
fission, are held together by the
surrounding glycocalyx.

56. The Phyla Chlorobi and Chloroflexi (The Anoxygenic Photosynthetic Bacteria)
Carry out anoxygenic photosynthesis
Green sulfur: phylum Chlorobi
Green nonsulfur: phylum Chloroflexi
Purple sulfur and purple nonsulfur photosynthetic bacteria are proteobacteria

57. Figure 11.14 Purple sulfur bacteria.

58. Table 11.2 Selected Characteristics of Photosynthesizing Bacteria

59. Chlamydiae No peptidoglycan in the cell wall; grow intracellularly
Chlamydia and Chlamydophila
Form an elementary body that is infective
Chlamydia trachomatis causes trachoma and urethritis
Chlamydophila psittaci causes respiratory psittacosis

60. Figure 11.15a Chlamydias. The elementary bodies Elementary body
are released from the
host cell.
Elementary body
The bacterium's infectious
form, the elementary
body, attaches to a host
cell.
Nucleus
The reticulate bodies
begin to convert back to
elementary bodies.
The host cell phagocytizes
the elementary body,
housing it in a vacuole.
Host cell
Vacuole forming
Vacuole
Reticulate body
The reticulate body divides
successively, producing
multiple reticulate bodies.
The elementary body
reorganizes to form a
reticulate body.
Life cycle of the chlamydias, which takes about 48 hours to complete

61. Figure 11.15b Chlamydias.
Micrograph of Chlamydophila psittaci in the cytoplasm of a
host cell. The elementary bodies are the infectious stage; they
are dense, dark, and relatively small. Reticulate bodies, the
form in which chlamydias reproduce within the host cell, are
larger with a speckled appearance. Intermediate bodies, a stage
between the two, have a dark center.
Elementary body
Reticulate body
Intermediate body

62. Planctomycetes
Gemmata obscuriglobus has a membrane around DNA resembling a eukaryotic nucleus

63. Figure 11.16 Gemmata obscuriglobus.
Nucleoid
Nuclear
envelope

64. The Nonproteobacteria Gram-Negative Bacteria
Bacteroidetes
Anaerobic
Bacteroides are found in the mouth and large intestine
Cytophaga degrade cellulose in soil
Fusobacteria
Are found in the mouth; cause dental abscesses

65. Figure Fusobacterium.

66. Spirochaetes Coiled and move via axial filaments Treponema Borrelia
T. pallidum causes syphilis
Borrelia
Causes relapsing fever and Lyme disease
Leptospira
Excreted in animal urine

67. This cross section of a spirochete
Figure Spirochetes.
Axial
filaments
Sheath
This cross section of a spirochete
shows numerous axial filaments between
the dark cell and the outer sheath.
Axial filament
anchored at one
end to cell body
Body of cell
Sheath
Axial filament
The end of an axial filament (endoflagellum) is attached to the cell and extends
through most of the length of the cell. Another axial filament is attached to the
opposite end of the cell. These axial filaments do not extend away from the cell but
remain between the body of the cell and the external sheath. Their contractions
and relaxations cause the helical cell to rotate in a corkscrew fashion.

68. Deinococci Deinococcus radiodurans Thermus aquaticus
More resistant to radiation than endospores
Thermus aquaticus
Found in a hot spring in Yellowstone National Park
Source of Taq polymerase

69. Check Your Understanding
 Which gram-negative group has a life cycle that includes different stages? 11-6
 Both the purple and green photosynthetic bacteria and the photosynthetic cyanobacteria use plantlike CO2 fixation to make carbohydrates. In what way does the photosynthesis carried out by these two groups differ from plant photosynthesis? 11-7
 The axial filament distinguishes what genera of bacteria? 11-8

70. The Gram-Positive Bacteria
Learning Objective
11-9 Differentiate the genera of firmicutes described in this chapter by drawing a dichotomous key.
11-10 Differentiate the actinobacteria described in this chapter by drawing a dichotomous key.

71. The Gram-Positive Bacteria
Firmicutes (low G + C ratios)
Actinobacteria (high G + C ratios)

72. Firmicutes (Low G + C Gram-Positive Bacteria)
Clostridiales
Clostridium
Endospore-producing
Obligate anaerobes
Includes disease-causing C. tetani, C. botulinum, C. perfringens, and C. difficile
Epulopiscium
Can be seen with the unaided eye
Daughter cells form within the parent cell; no binary fission

73. Figure 11.19 Clostridium difficile.
Endospore

74. Epulopiscium Paramecium
Figure A giant prokaryote, Epulopiscium fishelsoni.
Epulopiscium
Paramecium

75. Firmicutes (Low G + C Gram-Positive Bacteria)
Bacillales
Bacillus
Endospore-producing rods
B. anthracis causes anthrax
B. thuringiensis is an insect pathogen
B. cereus causes food poisoning
Staphylococcus
Grapelike clusters
S. aureus causes wound infections, is often antibiotic resistant, and produces an enterotoxin

76. Bacillus thuringiensis. The diamond-shaped
Figure Bacillus.
Endospore
Collapsed
B. thuringiensis
Toxic crystal
Bacillus thuringiensis. The diamond-shaped
crystals shown next to the endospore are toxic
to insects that ingest them. This electron
micrograph was made using the technique of
shadow casting.

77. Figure 11.22 Staphylococcus aureus.

78. Firmicutes (Low G + C Gram-Positive Bacteria)
Lactobacillales
Aerotolerant anaerobes; produce lactic acid from simple carbohydrates
Lactobacillus colonize the body and are used commercially in food production

79. Firmicutes (Low G + C Gram-Positive Bacteria)
Lactobacillales (cont'd)
Streptococcus
Spherical in chains
Produce enzymes that destroy tissue
Beta-hemolytic streptococci hemolyze blood agar; includes S. pyogenes
Non-beta-hemolytic streptococci include S. pneumoniae and S. mutans, which causes dental caries

80. Figure Streptococcus.

81. Firmicutes (Low G + C Gram-Positive Bacteria)
Lactobacillales (cont'd)
Enterococcus
Found in intestinal tract; hospital contaminants
E. faecalis and E. faecium infect surgical wounds and the urinary tract
Listeria
L. monocytogenes contaminates food

82. Firmicutes (Low G + C Gram-Positive Bacteria)
Mycoplasmatales
Lack a cell wall; pleomorphic
M. pneumoniae causes mild pneumonia

83. Figure 11.24 Mycoplasma pneumoniae.

84. Check Your Understanding
 To which genus is Enterococcus more closely related: Staphylococcus or Lactobacillus? 11-9

85. Actinobacteria (High G + C Gram-Positive Bacteria)

86. Actinobacteria (High G + C Gram-Positive Bacteria)
Often pleomorphic; branching filaments
Often common inhabitants of soil
Mycobacterium
Outermost layer of mycolic acids that is waxy and water-resistant
Often slow-growing
M. tuberculosis causes tuberculosis
M. leprae causes leprosy

87. Actinobacteria (High G + C Gram-Positive Bacteria)
Corynebacterium
C. diphtheriae causes diphtheria
Propionibacterium
Forms propionic acid
P. acnes causes acne
Gardnerella
G. vaginalis causes vaginitis
Frankia
Forms N-fixing nodules on tree roots

88. Actinobacteria (High G + C Gram-Positive Bacteria)
Streptomyces
Isolated from soil; produce most antibiotics
Actinomyces
Form filaments in the mouth and throat; destroy tissue
Nocardia
Form fragmenting filaments; acid-fast
N. asteroides causes pulmonary infections

89. Drawing of a typical streptomycete showing filamentous, branching
Figure Streptomyces.
Conidiospores
in coils
Filament
Drawing of a typical streptomycete showing filamentous, branching
growth with asexual reproductive conidiospores at the filament tips
Filament
Conidiospores in coils
Coils of conidiospores supported by filaments of
the streptomycete

90. Figure Actinomyces.

91. Check Your Understanding
 What group of bacteria makes most of the commercially important antibiotics? 11-10

92. Diversity Within the Archaea
Learning Objective
11-11 Name a habitat for each group of archaea.

93. Diversity Within the Archaea
Distinct taxonomic grouping; lack peptidoglycan
Extremophiles
Halophiles
Require salt concentration >25%
Thermophiles
Require growth temperature >80 C
Methanogens
Anaerobic and produce methane

94. Figure Archaea.

95. Check Your Understanding
 What kind of archaea would populate solar evaporating ponds? 11-11

96. Microbial Diversity Learning Objective
11-12 List two factors that contribute to the limits of our knowledge of microbial diversity.

97. Microbial Diversity Bacteria size range
Thiomargarita (diameter of 750 µm)
Carsonella ruddii (182 genes)
PCR indicates up to 10,000 bacterial species per gram of soil
Many bacteria have not been identified
Have not been cultured
Are a part of complex food chains requiring the products of other bacteria

98. Figure 11.28 Thiomargarita namibiensis.

99. Check Your Understanding
 How can you detect the presence of a bacterium that cannot be cultured? 11-12