60 4 Taxonomy, Physiology, and Ecology of Aquatic Microorganisms
allows the spirochete to move about. The spiro
chete shape may also be described as consisting of
an axial filament around which the cell is wound
giving spirochetes their characteristic corkscrew
shapes. Most spirochetes are freeliving and anaer
obic, but they also include the following disease
causing members:- Leptospira species, which causes leptospirosis
(also known as Weil’s disease) - Borrelia burgdorferi, which causes Lyme disease
- Borrelia recurrentis, which causes relapsing
fever - Treponema pallidum, which causes syphilis
- Green sulfur bacteria
Green Sulfur Bacteria are found in anaerobic
environments such as muds, anaerobic, and sul
fidecontaining fresh or marine waters, and wet
lands. These anoxygenic phototrophic bacteria
live in environments where light and reduced
sulfur compounds are present. They are found
most often under the Purple Sulfur bacterial
layer. Green sulfur bacteria are capable of using
sulfide or elemental S as the electron donor. The
elemental S arises from H 2 S oxidation and is
deposited extracellularly, before the oxidation of
sulfate. There are four genera of green sulfur
bacteria, Chlorobium, Prosthecohloris (with stalks
or prostheca), Pelodictyon (with vacuoles), and
Clathrochloris (motile).
The Green Sulfur Bacteria strains are green
because of the presence of bacteriochlorophylls
(bchls) “c” and “d” and small traces of bchl “a”
located in chlorobium vesicles attached to the
cytoplasmic membrane. Some are brown and they
contain bacteriochlorophyll “e.” These brown
strains are found in the deeper layers of wetlands
and water. Both of the two groups can be found
also living in extreme conditions of salinity and
high temperatures. The morphology of both color
types is most often either straight or curved rods.
They are nonmotile phototrophic short to long
rods which utilize H 2 S as electron donor oxidizing
it to SO 2 and to SO 4 2+. The sulfur so produced lies
outside the cells. Light energy absorbed by
Bacteriochlorophylls c, d, or e is channeled to
Bacteriochlorophyll a, which actually carries out
photosynthetic energy conversion, and ATP syn
thesis takes place. A wellknown member is
Chlorobium tepidum.
In marine environments, they are found in the
water column where hydrogen sulfide diffuses up
from anaerobic sediments and where oxygen dif
fuses down from surface waters where oxygenic
photosynthesis is taking place. In the Black Sea, the
largest anoxic water body in the world, they are
found at a depth of 100 m (Manske et al. 2008 ).
They also live in special tissues in invertebrates such
as Riftia pachyptila (vestimentiferan tube worms)
and Calyptogena magnifica (“giant” white clams)
that live around deep sea hydrothermal vents. There
they provide energy, by oxidizing reduced sulfur
compounds, and organic matter, by converting car
bon dioxide to organic compounds, which the inver
tebrates use. They are sometimes abundant in coastal
waters, and several members of the group have gas
vacuoles in their cells to help them float.- Flavobacteria
Flavobacteria are Gram negative rods that are
motile by gliding and found in aquatic environ
ments, both freshwater and marine, and in the soil.
Colonies are usually yellow to orange in color,
hence their name. Flavobacteria are a group of
commensal bacteria and opportunistic pathogens.
Flavobacterium psychrophilum causes the septi
cemic diseases of rainbow trout fry syndrome and
bacterial cold water disease. They decompose sev
eral polysaccharides including agar but not cellu
lose. The type species is F. aquatile. - Defferibacter
These are thermophilic, anaerobic, chemolithoau
totrophic Gram negative straight to bent rods.
They can use a wide range of electron acceptors
including Fe3+ and Mn2+. They are found in a wide
range of aquatic environments including deepsea
hydrothermal vents. A wellknown member is
Deferribacter desulfuricans - Cytophaga
Cytophaga are unicellular, Gramnegative gliding
bacteria. They are rodshaped, but specific strains
differ in diameter and length with some being
pleomorphic (many shaped). The type species is
C. johnsonae, which has a moderately long thin
shape. Many strains are red, yellow, or orange
because of unique pigments synthesized by the
group. Cytophaga strains tend to be versatile in
making these and one strain may synthesize 25
different structural varieties of pigment. The main
habitats of Cytophaga are soils at or close to neu