WORLD OF MICROBIOLOGY AND IMMUNOLOGY Phylogeny
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other animals for vision. Bacteriorhodopsin and halorhodopsin
are embedded in the cell membranes of halobacteria and each
pigment consists of retinal, a vitamin-A derivative, bound to a
protein. Irradiation of these pigments causes a structural
change in their retinal. This is referred to as photoisomeriza-
tion. Retinal photoisomerization leads to the synthesis of ATP.
Halobacteria have two additional rhodopsins, sensory
rhodopsin-I and sensory rhodopsin-II. These compounds regu-
late phototaxis, the directional movement in response to light.
See alsoEvolutionary origin of bacteria and viruses
PPhotosynthetic microorganismsHOTOSYNTHETIC MICROORGANISMS
Life first evolved in the primordial oceans of Earth approxi-
mately four billion years ago. The first life forms were prokary-
otes, or non-nucleated unicellular organisms, which divided in
two domains, the Bacteriaand Archaea. They lived around hot
sulfurous geological and volcanic vents on the ocean floor,
forming distinct biofilms, organized in multilayered symbiotic
communities, known as microbial mats. Fossil evidence sug-
gests that these first communities were not photosynthetic, i.e.,
did not use the energy of light to convert carbon dioxide and
water into glucose, releasing oxygen in the process. About 3.7
billions years ago, anoxygenic photosynthetic microorganisms
probably appeared on top of pre-photosynthetic biofilms
formed by bacterial and Archaean sulphate-processers.
Anoxygenic photosynthesizers use electrons donated by sul-
phur, hydrogen sulfide, hydrogen, and a variety of organic
chemicals released by other bacteria and Archaea. This ances-
tor species, known as protochlorophylls, did not synthesized
chlorophylland did not release oxygen during photosynthesis.
Moreover, in that deep-water environment, they probably used
infrared thermo taxis rather than sunlight as a source of energy.
Protochlorophylls are assumed to be the common
ancestors of two evolutionary branches of oxygenic photo-
synthetic organisms that began evolving around 2.8 billion
years ago: the bacteriochlorophyll and the chlorophylls.
Bacteriochlorophyll gave origin to chloroflexus, sulfur green
bacteria, sulfur purple bacteria, non-sulfur purple bacteria,
and finally to oxygen-respiring bacteria. Chlorophylls origi-
nated Cyanobacteria, from which chloroplasts such as red
algae, cryptomonads, dinoflagellates, crysophytes, brown
algae, euglenoids, and finally green plants evolved. The first
convincing paleontological evidence of eukaryotic microfos-
sils (chloroplasts) was dated 1.5 at billion years old. In oxy-
genic photosynthesis, electrons are donated by water
molecules and the energy source is the visible spectrum of
visible light. However, the chemical elements utilized by
oxygenic photosynthetic organisms to capture electrons
divide them in two families, the Photosystem I Family and the
Photosystem II Family. Photosystem II organisms, such as
Chloroflexus aurantiacus(an ancient green bacterium) and
sulfur purple bacteria, use pigments and quinones as electron
acceptors, whereas member of the Photosystem I Family,
such as green sulfur bacteria, Cyanobacteria, and chloroplasts
use iron-sulphur centers as electron acceptors.
It is generally accepted that the evolutionof oxygenic
photosynthetic microorganisms was a crucial step for the
increase of atmospheric oxygen levels and the subsequent
burst of biological evolution of new aerobic species. About 3.5
billion years ago, the planet atmosphere was poor in oxygen
and abundant in carbon dioxide and sulfuric gases, due to
intense volcanic activity. This atmosphere favored the evolu-
tion of chemotrophic Bacteria and Archaea. As the populations
of oxygenic photosynthetic microorganisms gradually
expanded, they started increasing the atmospheric oxygen
level two billion years ago, stabilizing it at its present level of
20% about 1.5 billion years ago, and additionally, reduced the
carbon dioxide levels in the process. Microbial photosynthetic
activity increased the planetary biological productivity by a
factor of 100–1,000, opening new pathways of biological evo-
lution and leading to biogeochemical changes that allowed life
to evolve and colonize new environmental niches. The new
atmospheric and biogeochemical conditions created by photo-
synthetic microorganisms allowed the subsequent appearance
of plants about 1.2 billion years ago, and 600 million years
later, the evolution of the first vertebrates, followed 70 million
years later by the Cambrian burst of biological diversity.
See alsoAerobes; Autotrophic bacteria; Biofilm formation
and dynamic behavior; Biogeochemical cycles; Carbon cycle
in microorganisms; Chemoautotrophic and chemolithotrophic
bacteria; Electron transport system; Evolutionary origin of
bacteria and viruses; Fossilization of bacteria; Hydrothermal
vents; Plankton and planktonic bacteria; Sulfur cycle in
microorganisms
PPhylogenyHYLOGENY
Phylogeny is the inferred evolutionary history of a group of
organisms (including microorganisms). Paleontologists are
interested in understanding life through time, not just at one
time in the past or present, but over long periods of past time.
Before they can attempt to reconstruct the forms, functions,
and lives of once-living organisms, paleontologists have to
place these organisms in context. The relationships of those
organisms to each other are based on the ways they have
branched out, or diverged, from a common ancestor. A phy-
logeny is usually represented as a phylogenetic tree or clado-
gram, which are like genealogies of species.
Phylogenetics, the science of phylogeny, is one part of
the larger field of systematics, which also includes taxonomy.
Taxonomy is the science of naming and classifying the diver-
sity of organisms. Not only is phylogeny important for under-
standing paleontology (study of fossils), however,
paleontology in turn contributes to phylogeny. Many groups of
organisms are now extinct, and without their fossils we would
not have as clear a picture of how modern life is interrelated.
There is an amazing diversity of life, both living and
extinct. For scientists to communicate with each other about
these many organisms, there must also be a classification of
these organisms into groups. Ideally, the classification should
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