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Transcript
Chapter 21
Bacteria: The Deinococci
and Nonproteobacteria
Gram Negatives
1
Life on Earth evolved along three major lines, called domains, all derived
from a common ancestor. Each domain contains several phyla. The domains,
Bacteria and Archaea, remained prokaryotic, whereas the third, Eukarya,
evolved into the modern eukaryotic cell.
2
Aquificae and Thermotogae
• Thermophiles that
grow at temperatures
above 85° C -Aquificae
and Thermotogae
Figure 21.1
3
4
Phylum Aquificae
• Thought to be deepest (oldest)
branch of Bacteria
• Contains one class, one order, and
five genera
– two best studied genera are Aquifex
and Hydrogenobacter
5
Genus Aquifex
• Thermophile with a growth optimum of
85°C and a maximum of 95°C
• Microaerophilic
• Chemolithoautotroph
-uses hydrogen, thiosulfite, and sulfur as electron
donor
-uses oxygen as electron acceptor
-genome ~1/3 size of E. coli
6
Phylum Thermotogae
• Second deepest branch of Bacteria
• Contains one class, one order, and
six genera
– best studied genus is Thermotoga
7
Genus Thermotoga
• Gram-negative rods
– have outer sheathlike envelope that can
balloon out from ends of cell
• Thermophiles
– optimum 80°C; maximum 90°C
– grow in active geothermal areas
– terrestrial solfataric springs
8
Thermotoga…
• Chemoheterotrophs
– have functional glycolytic pathway
– can grow anaerobically on
carbohydrates and proteins digests
• e.g., Thermatoga maritima
– ~24% of coding sequences are similar
to archaeal genes
9
Figure 21.2
10
Deinococcus-Thermus
11
Genus Deinococcus
• Deinococcus is best studied
• Spherical or rod-shaped
– associated in pairs or tetrads
– stain gram-positive but do not have typical
gram-positive cell wall
• layered outer membrane similar to gram-negatives
• L-ornithine in peptidoglycan
• lacks teichoic acid
12
Figure 21.3
13
14
Deinococcus…
• Mesophilic
• Mesophilc, aerobic, produce acid
• Extraordinarily resistant to desiccation
and radiation
– can survive 3-5 million rad (100 rad lethal to
humans)
• Isolated from ground meat, feces, air,
fresh water, and other sources, but
natural habitat unknown
15
Deinococcus……
• Genome consists of two circular
chromosomes, a megaplasmid, and a
small plasmid
– radiation resistance due to ability to repair
genome when it is severely damaged
• Rapidly repairs fragmented DNA within
12-24 hours when exposed to radiation
• D. radiodurans shown to have an efficient
DNA repair system
16
Photosynthetic Bacteria
• Three groups of photosynthetic bacteria
– the purple bacteria
– the green bacteria
– the cyanobacteria
• differ from the purple and green bacteria by
carrying out oxygenic photosynthesis
– have two photosystems
– use water as an electron donor and generate oxygen
during photosynthesis
17
Purple sulfur bacteria
Alga
Bloom of Purple Sulfur Bacteria, Sulfide Spring,
Madison, WI
18
19
differences in
absorption
spectra correlates
with ecological
distribution
Figure 21.4
20
21
Taxonomy of Photosynthetic
Bacteria
•
•
•
•
Phylum Chloroflexi – green nonsulfur bacteria
Phylum Chlorobi – green sulfur bacteria
Phylum Cyanobacteria
Phylum proteobacteria purple bacteria
– purple sulfur bacteria
– purple non-sufur bacteria
• phylum Firmicutes – heliobacteria
22
Purple sulfur bacteria: Note
the sulfur granules deposited
inside the cells
23
Green sulfur bacteria: Note
the sulfur granules deposited
outside the cells
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Purple bacteria
Chlorosomes from green
bacteria
24
Halophilic Purple bacteria
Phylum Chlorobi
• Green sulfur bacteria
• Morphologically diverse
– rods, cocci, or vibrios; single cells, chains, or
clusters
25
Chlorobi…
• Have chlorosomes
– ellipsoidal vesicles attached to plasma membrane
– contain accessory photosynthetic pigments
– most efficient light harvesting complexes found in
nature
26
Chlorosomes –Green Sulfur & Green Non-sulfur
27
Chlorobi…
• Lack flagella; nonmotile
• Some have gas vesicles
– used to adjust depth of cell for adequate light and H2S
• Obligately anaerobic photolithoautotrophs
– use H2S, elemental sulfur and H2 as electron
sources
– elemental sulfur deposited outside cell
28
Figure 21.5
29
Phylum Chloroflexi
• Green nonsulfur bacteria
• Contains photosynthetic and
nonphotosynthetic members
– e.g., genus Chloroflexus –
photosynthetic
– e.g., genus Herpetosiphon nonphotosynthetic
30
Genus Chloroflexus
• Thermophilic
– often isolated form neutral to alkaline hot
springs
– grow in form of orange-reddish mats
• Metabolism
– anoxygenic photosynthesis
• does not use water as electron donor
• photoheterotroph
– can grow aerobically as a chemoheterotroph
31
Chloroflexus sp.
32
Chloronema sp. on
stratified Michigan Lake
Phylum Cyanobacteria
• Largest, most diverse group of
photosynthetic bacteria
• Most obligate photolithoautotrophs;
some can grow slowly in dark as
chemoheterotrophs
• One current classification system divides
group into 62 species and 24 genera
33
Photosynthesis in cyanobacteria
• Resembles that of eucaryotes
– have chlorophyll a
• prochlorophytes have chlorophyll a and b
– have photosystem I and II
– oxygenic photosynthesis
34
Photosynthesis in cyanobacteria…
• Use phycobiliproteins as accessory
pigments
• phycobilisomes, which line thylakoid
membranes, contain phycocyanin and
phycoerythrin
• prochlorophytes lack phycobilins
• use Calvin cycle to fix CO2
35
Cyanobacterial Thylakoids and
Phycobilisomes
Figure 21.6
36
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
contains
phycobilin
pigments
nitrogen
storage
polymer
Figure
21.7
(a)
37
typical
gramnegative
cell
wall
site
of
photosynthesis
Figure 21.7b
38
Oxygenic Photosynthetic Bacteria
Figure 21.8
39
Heterocysts
• Specialized cells used for nitrogen
fixation
– produced when organism is nitrogen
deprived
– differentiate from individual cells in filament
• involves reorganization of photosynthetic
membranes
– thick heterocyst wall prevents O2 diffusion
into heterocyst which would inactivate
nitrogenase, enzyme responsible for nitrogen
fixation
40
Heterocysts and Akinetes
Figure 21.9
41
Prochlorophytes
• Cyanobacteria in genera Prochloron,
Prochlorococcus, and Prochlorothrix
– distinguished by presence of chlorophyll a
and b and lack of phycobilins
• are the only procaryotes to possess
chlorophyll b
–makes them candidates as ancestors of
endosymbionts that give rise to chloroplasts
42
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Prochloron
Figure 21.10
43
Ecology of cyanobacteria
• Tolerant of environmental extremes
– thermophilic species can grow at
temperatures up to 75°C
– often are primary colonizers
• Can cause blooms in nutrient-rich ponds and
lakes
– some produce toxins
• Often form symbiotic relationships
– e.g., are phototrophic partner in most lichens
– e.g., symbionts with protozoa and fungi
– e.g., nitrogen-fixing species form associations
with plants
44
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Figure 21.11
45
Phylum Chlamydiae
46
Genus Chlamydia
• Gram-negative bacteria
– cell walls lack muramic acid and
peptidoglycan
– have very small genomes
• Obligate intracellular parasites with unique
developmental cycle
– involving formation of elementary body (EB)
and reticulate body (RB) or initial body
– found mostly in mammals and birds
– some recently isolated from spiders, clams,
and freshwater invertebrates
47
Figure 21.13b
48
Chlamydial metabolism
• Appear to be energy parasites, obtaining
ATP from host
– do have genes for substrate-level
phosphorylation, electron transport, and
oxidative phosphorylation
• Reticulate bodies have biosynthetic
capabilities when supplied precursors
from host; can synthesize some amino
acids
• Elementary bodies seem to be dormant
forms
49
Important pathogens
• C. trachomatis
– infects humans and mice
– causes trachoma, nongonococcal urethritis,
and other diseases in humans
• C. psittaci
– infects humans and many other animals
– causes psittacosis in humans
• C. pneumoniae
– common cause of human pneumonia
50
Phylum Spirochaetes
• Gram-negative bacteria with distinctive
structure and motility
– slender, long with flexible helical shape
– creeping (crawling) motility due to a
structure called an axial filament
• Chemoheterotrophs
• Ecologically diverse
51
Figure 21.14
52
axial filament = complex of axial fibrils (periplasmic flagella)
Figure 21.15 (a1) and (a2)
53
Figure 21.15 (b)
54
Figure 21.15 (c) and (d)
55
Spirochete Motility
current thought:
axial fibrils rotate, causing
corkscrew-shaped outer sheath
to rotate and move cell through
surrounding liquid
Figure 21.16
56
Symbiotic Associations
• Broad range of organisms
• Found in a variety of locations, for
example
– hindguts of termites
– digestive tracts of mollusks and
mammals
– oral cavities of animals
57
Spirochete-Protozoan Associations
Figure 21.17
58
59