Chapter 2 (The Prokaryotes).pdf

Transcript

Chapter 2:
The Prokaryotes
(Domains
Bacteria and
Archaea)

Jason M. Madronero, MEd
BIO 313
(Microbiology and Parasitology)
The
Prokaryotes

Prokaryotes are
unicellular organisms
without a nucleus or other
membrane-bound
organelles. They
represent two of the three
domains of life: Bacteria
and Archaea.
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The
Prokaryotes

These organisms are
incredibly diverse, both in
their genetic makeup and
in their ecological niches,
thriving in environments
ranging from the human
gut to deep-sea
hydrothermal vents.
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Domains of
Prokaryotes

Domain Bacteria:
Includes a wide range of
prokaryotic microorganisms
that are found in various
environments. They have
significant roles in nutrient
cycling, human health, and
biotechnology.

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Domains of
Prokaryotes

Domain Archaea:
Comprises prokaryotes that often live in
extreme environments (extremophiles) such
as hot springs, salt lakes, and anaerobic
environments. Archaea have unique
biochemical and genetic traits that
differentiate them from bacteria.

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Prokaryotic
Cells
Size
Prokaryotic cells are typically
small, ranging from 0.2 to 2.0
µm in diameter and 2 to 8 µm
in length. Their small size
allows for a high surface-area-
to-volume ratio, which is
advantageous for nutrient
uptake and waste elimination.

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Prokaryotic Cells
Shape
Prokaryotic cells exhibit various shapes, including:
Coccus (spherical): These bacteria can be found singly (coccus), in pairs
(diplococci), chains (streptococci), clusters (staphylococci), or tetrads
(groups of four).
Bacillus (rod-shaped): Bacilli can occur as single rods, pairs (diplobacilli),
or chains (streptobacilli).
Spiral: These include spirilla (rigid spiral structures), spirochetes (flexible
spiral structures), and vibrios (comma-shaped bacteria).

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Prokaryotic Cells
Shape
The shape of a bacterium is determined by heredity.
Most bacteria are monomorphic, maintaining a single, consistent
shape.
Environmental conditions can sometimes alter the shape of bacteria,
making identification challenging.
Some bacteria, like Rhizobium and Corynebacterium, are
pleomorphic, meaning they can exhibit multiple shapes.
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Prokaryotic Cells
Arrangement
The arrangement of cells can vary depending on the plane of division
and whether the cells remain attached after division. This can result
in distinctive patterns like chains (strepto-), clusters (staphylo-), or
pairs (diplo-).

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Structures External to the Cell Wall
Glycocalyx
Composition and Types:
The glycocalyx (meaning sugar coat) is a sticky, gelatinous polymer
composed of polysaccharides, polypeptides, or both. It is located outside
the cell wall and can exist in two forms:
Capsule: A neatly organized and firmly attached layer that protects
bacteria from phagocytosis.
Slime Layer: An unorganized and loosely attached layer that allows
bacteria to adhere to surfaces, forming biofilms.
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Structures External to the Cell Wall
Glycocalyx
Functions:
Protects cells from desiccation.
Helps in the formation of biofilms, which are protective communities of
bacteria that adhere to surfaces like teeth, medical devices, and river rocks.
Enhances bacterial virulence by protecting pathogenic bacteria from the
host's immune system.

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Structures External to the Cell Wall
Flagella
Structure:
Flagella are long, filamentous appendages that protrude from the cell
surface and are responsible for motility. They consist of three parts:
Filament: The long, helical structure made of the protein flagellin.
Hook: A curved structure that connects the filament to the basal body.
Basal Body: A complex structure anchored in the cell wall and plasma
membrane, consisting of a rod and several rings that rotate to propel
the bacterium.
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Structures External to the Cell Wall
Archaella
Archaella (singular: archaellum) are the motility structures found in archaea,
analogous to bacterial flagella but distinct in structure and mechanism.
Like flagella, archaella allow archaea to move in liquid environments, aiding in
chemotaxis and adaptation to extreme habitats.

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Structures External to the Cell Wall
Flagella
Types of Flagellar Arrangements
Monotrichous: A single flagellum at one end of the cell.
Lophotrichous: A cluster of flagella at one or both ends of the cell.
Amphitrichous: A single flagellum or cluster of flagella at both ends of the
cell.
Peritrichous: Flagella distributed over the entire surface of the cell.

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Structures External to the Cell Wall
Flagella
Rotation:
Counterclockwise Rotation: Typically results in a "run," where the bacterium
moves forward in a straight line.
Clockwise Rotation: Causes the bacterium to "tumble," changing its direction
randomly.

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Structures External to the Cell Wall
Flagella
Motility and Taxis:
Flagella enable bacteria to move toward or away from stimuli (taxis).
Chemotaxis refers to movement in response to chemical stimuli, and
phototaxis refers to movement in response to light.

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Structures External to the Cell Wall
Axial Filaments
Axial Filaments are specialized structures used for motility in spirochetes, a
unique group of spiral-shaped bacteria.
Also known as endoflagella, these structures allow spirochetes to move in a
corkscrew motion, enabling them to navigate through viscous environments,
such as mucus or host tissues.

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Structures External to the Cell Wall
Axial Filaments
The unique motility provided by axial filaments is crucial for the pathogenicity
of some spirochetes, as it allows them to penetrate host tissues and evade
immune responses.
For example, in Treponema pallidum, the causative agent of syphilis, uses its
corkscrew motion to penetrate mucous membranes and tissues.

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Structures External to the Cell Wall
Fimbriae and Pili
Fimbriae:
Short, hair-like structures that are involved in attachment to
surfaces and other cells. Fimbriae play a crucial role in the formation
of biofilms and in the adherence of pathogens to host tissues,
facilitating infection.

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Structures External to the Cell Wall
Fimbriae and Pili
Pili
Longer than fimbriae and usually fewer in number, pili are involved in
the transfer of DNA between bacterial cells during a process called
conjugation. This transfer of genetic material can contribute to the
spread of antibiotic resistance.

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The Cell Wall
Composition:
The bacterial cell wall is primarily composed of peptidoglycan, a
mesh-like polymer of sugars and amino acids that provides structural
strength and shape to the cell.
Peptidoglycan consists of repeating units of N-acetylglucosamine
(NAG) and N-acetylmuramic acid (NAM), which are linked by short
peptide chains.

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The Cell Wall
Functions:
Maintains the cell shape and protects against osmotic lysis (bursting
due to water intake).
Anchors the flagella and serves as a site for some antibiotic action, as
certain antibiotics (e.g., penicillin) target the synthesis of peptidoglycan,
weakening the cell wall and leading to cell death.

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The Cell Wall
Gram-Positive vs. Gram-Negative Bacteria
Gram-Positive Bacteria:
Have a thick peptidoglycan layer that is interspersed with teichoic
acids, which provide rigidity and contribute to the cell's antigenic
specificity.
The absence of an outer membrane makes gram-positive bacteria
more susceptible to antibiotics that target peptidoglycan synthesis.

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The Cell Wall
Gram-Positive vs. Gram-Negative Bacteria
Gram-Negative Bacteria:
Have a thin peptidoglycan layer located between the inner plasma
membrane and an outer membrane. The outer membrane contains
lipopolysaccharides (LPS), which contribute to the structural integrity
and protect against certain antibiotics.

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The Cell Wall
Gram-Positive vs. Gram-Negative Bacteria
Gram-Negative Bacteria:
The presence of an outer membrane also serves as a barrier to
environmental threats, but it makes gram-negative bacteria less
susceptible to antibiotics that target peptidoglycan.

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The Gram Stain
Mechanism

The Gram stain is a differential staining
technique developed by Hans Christian
Gram in 1884. It is one of the most
important techniques in microbiology for
distinguishing between gram-positive and
gram-negative bacteria based on
differences in cell wall structure.

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The Gram Stain Mechanism
Steps of the Gram Stain Procedure
1. Primary Stain (Crystal Violet):
Crystal violet is applied to a heat-fixed smear of bacterial cells.
Both gram-positive and gram-negative cells are initially stained
purple.

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The Gram Stain Mechanism
Steps of the Gram Stain Procedure
2. Mordant (Iodine Solution)
Iodine is added as a mordant, forming a crystal violet-iodine
complex (CV-I) within the cells, which is larger and more insoluble
than crystal violet alone.

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The Gram Stain Mechanism
Steps of the Gram Stain Procedure
3. Decolorization (Alcohol or Acetone):
The decolorizing agent (usually ethanol or acetone) is added, which
dehydrates the thick peptidoglycan layer in gram-positive cells, trapping
the CV-I complex.
In gram-negative cells, the alcohol dissolves the outer membrane and
disrupts the thin peptidoglycan layer, allowing the CV-I complex to
escape, rendering the cells colorless.

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The Gram Stain Mechanism
Steps of the Gram Stain Procedure
4. Counterstain (Safranin):
Safranin, a red counterstain, is applied, staining the now colorless
gram-negative cells pink. Gram-positive cells remain purple due to
the retained crystal violet.

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The Gram Stain Mechanism
Interpretation of Gram Stain Results
Gram-Positive Bacteria:
Appear purple due to the retention of the crystal violet stain in the
thick peptidoglycan layer.
Gram-Negative Bacteria:
Appear pink or red after the counterstain because the
decolorization step removes the initial crystal violet stain.

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Gram-Negative Bacteria Gram-Positive Bacteria
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Atypical Cell Walls
Mycoplasma
Mycoplasmas are a group of bacteria that lack a cell wall entirely.
They have only a plasma membrane that contains sterols, which
provide added strength and rigidity to the membrane.
Clinical Relevance: Mycoplasma pneumoniae is known to cause
atypical pneumonia. The absence of a cell wall makes Mycoplasma
resistant to antibiotics like penicillin that target cell wall synthesis.

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Atypical Cell Walls
Acid-Fast Bacteria
Mycobacteria and Nocardia:
These bacteria have a cell wall with a high lipid content, specifically
mycolic acids (waxy, long-chain fatty acids), which make the cell
wall impermeable to many stains and chemicals.

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Atypical Cell Walls
Acid-Fast Bacteria
Acid-Fast Staining
Acid-fast bacteria retain the primary stain (carbolfuchsin) even after
decolorization with acid-alcohol due to the mycolic acid layer. Non-
acid-fast bacteria do not retain the stain and are counterstained with
methylene blue.

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Atypical Cell Walls
Acid-Fast Bacteria
Acid-Fast Staining
Clinical Relevance: Mycobacterium tuberculosis (causes
tuberculosis) and Mycobacterium leprae (causes leprosy) are
notable acid-fast bacteria

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Acid-fast stain of Mycobacterium tuberculosis

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Atypical Cell Walls
Archaea Cell Walls
Archaeal cell walls do not contain peptidoglycan. Instead, they have
unique structures:
Pseudopeptidoglycan: Composed of polysaccharides and
proteins similar to peptidoglycan but with different chemical
linkages.
S-layers: Made of protein or glycoprotein, providing structural
support and protection.

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Atypical Cell Walls
Archaea Cell Walls
Adaptations:
These variations allow archaea to survive in extreme
environments, such as high temperatures, acidity, or salinity.

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Structures Internal to the Cell Wall
Plasma (Cytoplasmic) Membrane
Structure:
The plasma membrane is a phospholipid bilayer with embedded proteins.
It serves as a selective barrier that regulates the entry and exit of
substances into and out of the cell.
In bacteria, the plasma membrane lacks sterols (found in eukaryotic
membranes) but may contain hopanoids, which help in stabilizing the
membrane.

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Structures Internal to the Cell Wall
Plasma (Cytoplasmic) Membrane
Functions:
Involved in energy production (e.g., via the electron transport chain in
respiration) and contains enzymes necessary for metabolic processes such
as ATP synthesis.
Regulates the movement of materials in and out of the cell via processes
like diffusion, facilitated diffusion, osmosis, and active transport.

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Structures Internal to the Cell Wall
Plasma (Cytoplasmic) Membrane
Cytoplasm
The cytoplasm is the gel-like substance inside the plasma membrane
that contains water, enzymes, nutrients, waste products, and gases.
It is the site of many metabolic reactions and houses the cell's
genetic material (nucleoid) and ribosomes.

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Structures Internal to the Cell Wall
Nucleoid
The nucleoid is the region in the cytoplasm where the bacterial
chromosome resides. Unlike eukaryotic cells, bacteria lack a true nucleus,
and their DNA is not enclosed by a membrane.
The bacterial chromosome is typically a single, circular DNA molecule that
contains the genetic information required for the cell's functions and
replication.

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Structures Internal to the Cell Wall
Plasmids
Plasmids are small, circular, double-stranded DNA molecules that
are separate from the chromosomal DNA. They often carry genes
that provide advantageous traits, such as antibiotic resistance, and
can be transferred between bacteria through conjugation.

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Structures Internal to the Cell Wall
Ribosomes
Prokaryotic ribosomes (70S) are composed of two subunits (30S and
50S) and are the sites of protein synthesis. These ribosomes are
targeted by certain antibiotics (e.g., tetracycline, erythromycin), which
inhibit protein synthesis by binding to the bacterial ribosome.

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Structures Internal to the Cell Wall
Inclusions
Intracellular structures that serve as storage deposits for nutrients
and other substances.
Allow bacteria and archaea to store essential compounds when they
are in excess and utilize them when needed.
Help cells survive fluctuating environmental conditions and
contribute to the efficiency of cellular metabolism by minimizing
osmotic pressure.

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Structures Internal to the Cell Wall
Inclusions
Metachromatic Granules (Volutin)
Function: Store inorganic phosphate for ATP synthesis and nucleic
acid production.
Occurrence: Found in bacteria like Corynebacterium diphtheriae and
Mycobacterium tuberculosis.

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Structures Internal to the Cell Wall
Inclusions
Polysaccharide Granules
Function: Store glycogen and starch as energy reserves.
Occurrence: Present in bacteria such as Escherichia coli and
Clostridium species.

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Structures Internal to the Cell Wall
Inclusions
Lipid Inclusions
Function: Store lipids, particularly poly-β-hydroxybutyrate (PHB), for
carbon and energy.
Occurrence: Found in bacteria like Bacillus megaterium and
Mycobacterium species.

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Structures Internal to the Cell Wall
Inclusions
Sulfur Granules
Function: Store sulfur for energy production in sulfur-oxidizing
bacteria.
Occurrence: Seen in bacteria such as Thiobacillus and Beggiatoa
species.

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Structures Internal to the Cell Wall
Inclusions
Carboxysomes
Function: Contain RuBisCO enzyme for carbon fixation in autotrophic
bacteria.
Occurrence: Found in cyanobacteria and nitrifying bacteria like
Nitrosomonas.

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Structures Internal to the Cell Wall
Inclusions
Gas Vacuoles
Function: Provide buoyancy to aquatic bacteria, allowing optimal light
and nutrient positioning.
Occurrence: Present in photosynthetic bacteria, such as
cyanobacteria (Anabaena, Microcystis).

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Structures Internal to the Cell Wall
Inclusions
Magnetosomes
Function: Contain magnetite or greigite crystals to help bacteria
orient along the Earth’s magnetic field.
Occurrence: Found in magnetotactic bacteria like Magnetospirillum.

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Structures Internal to the Cell Wall
Endospores
Formation and Function:
Endospores are highly durable, dormant structures formed by
certain gram-positive bacteria (e.g., Bacillus and Clostridium) as a
survival mechanism under adverse conditions. They are resistant to
extreme heat, desiccation, radiation, and chemicals.

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Structures Internal to the Cell Wall
Endospores
Sporulation
The process by which a vegetative cell forms an endospore. This
involves the replication of the cell's DNA, the formation of a spore
septum, and the deposition of protective layers around the DNA.

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Structures Internal to the Cell Wall
Endospores
Germination
When favorable conditions return, the endospore germinates,
returning to its vegetative state and becoming metabolically active.

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Classification of
Microorganisms
Three Domains
Based on genetic analysis, particularly rRNA
sequences.
1. Bacteria: True bacteria, prokaryotic cells
with peptidoglycan in their cell walls.
2. Archaea: Prokaryotic cells without
peptidoglycan, often extremophiles.
3. Eukarya: Eukaryotic cells, including
protists, fungi, plants, and animals.
Classification of
Microorganisms
Taxonomic Hierarchy
Domain
Kingdom
Phylum
Class
Order
Family
Genus
Species
Classification of
Microorganisms
Five-Kingdom System
Prior to the three-domain system,
organisms were classified into five
kingdoms:
Monera (prokaryotes)
Protista (unicellular eukaryotes)
Fungi
Plantae
Animalia
Prokaryote Diversity
Prokaryotes are divided into two domains: Bacteria and Archaea.
These microorganisms are distinguished based on differences in
their rRNA sequences, membrane lipid structure, and other
molecular characteristics.

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Domain Bacteria
Gram-Negative Bacteria
Proteobacteria
This is the largest phylum of gram-negative bacteria, including a wide variety
of pathogenic and non-pathogenic species. Members of this phylum include:
Alphaproteobacteria
Betaproteobacteria
Gammaproteobacteria
Deltaproteobacteria
Epsilonproteobacteria
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Domain Bacteria
Phylum Proteobacteria
Class Alphaproteobacteria
Characteristics: This class consists of bacteria that are often
oligotrophic (capable of growing in low-nutrient environments). They
include both free-living and intracellular symbionts.

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Domain Bacteria
Phylum Proteobacteria
Class Alphaproteobacteria
Notable Genera
Rickettsia: Obligate intracellular parasites transmitted by arthropods;
responsible for diseases like typhus and Rocky Mountain spotted
fever.
Rhizobium: Nitrogen-fixing bacteria forming symbiotic relationships
with legumes, contributing to soil fertility.

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Rickettsia Rhizobium

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Domain Bacteria
Phylum Proteobacteria
ClassBetaproteobacteria
Characteristics: Betaproteobacteria are generally aerobic or
facultatively anaerobic, and they include pathogens and
environmental bacteria.

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Domain Bacteria
Phylum Proteobacteria
Class Betaproteobacteria
Notable Genera
Neisseria: Includes pathogens like Neisseria gonorrhoeae (causing
gonorrhea) and Neisseria meningitidis (causing meningitis).
Bordetella: Bordetella pertussis is the causative agent of whooping cough.

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Neisseria gonnorhoeae Bordetella pertussis

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Domain Bacteria
Phylum Proteobacteria
Class Gammaproteobacteria
Characteristics: This is the largest class within Proteobacteria,
comprising a wide variety of physiological types, including many
medically significant pathogens.

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Domain Bacteria
Phylum Proteobacteria
Class Gammaproteobacteria
Notable Genera
Escherichia: Escherichia coli is a model organism in research and can also be
pathogenic, causing foodborne illnesses.
Salmonella: Pathogens responsible for foodborne illnesses and typhoid fever.
Vibrio: Includes Vibrio cholerae, the causative agent of cholera.
Pseudomonas: Known for their metabolic diversity, Pseudomonas species are
often involved in infections, especially in immunocompromised individuals.
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Escherichia coli Salmonella typhi

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Vibrio cholerae Pseudomonas aeruginosa

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Domain Bacteria
Phylum Proteobacteria
Class Deltaproteobacteria
Characteristics: This group includes bacteria that are primarily
involved in the sulfur cycle and some that are predators of other
bacteria.

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Domain Bacteria
Phylum Proteobacteria
Class Deltaproteobacteria
Notable Genera
Bdellovibrio: Preys on other gram-negative bacteria by invading their
periplasmic space.
Desulfovibrio: Sulfate-reducing bacteria that play a role in the sulfur cycle
by reducing sulfate to hydrogen sulfide.

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Bdellovibrio Desulfovibrio desulfuricans

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Domain Bacteria
Phylum Proteobacteria
Class Epsilonproteobacteria
Characteristics: This group includes bacteria that are often
microaerophilic and are found in the digestive tract of animals.

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Domain Bacteria
Phylum Proteobacteria
Class Epsilonproteobacteria
Notable Genera
Campylobacter: Includes species like Campylobacter jejuni, a common
cause of foodborne gastrointestinal infections.
Helicobacter: Helicobacter pylori is associated with peptic ulcers and
stomach cancer.

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Campylobacter jejuni Helicobacter pylori

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Domain Bacteria
Nonproteobacteria Gram-Negative Bacteria
Phylum Cyanobacteria
Characteristics: Photosynthetic bacteria, formerly known as blue-
green algae, capable of oxygenic photosynthesis. They are
important contributors to oxygen production and nitrogen fixation in
aquatic environments.

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Domain Bacteria
Nonproteobacteria Gram-Negative Bacteria
Phylum Cyanobacteria
Ecological Role: Cyanobacteria are pivotal in aquatic ecosystems,
forming the base of the food chain and contributing to nutrient
cycles.

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Cyanobacteria

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Domain Bacteria
Nonproteobacteria Gram-Negative Bacteria
Phylum Chlamydiae
Characteristics: Obligate intracellular pathogens with a unique
developmental cycle, including an infectious elementary body and a
replicative reticulate body.

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Domain Bacteria
Nonproteobacteria Gram-Negative Bacteria
Phylum Chlamydiae
Notable Species:
Chlamydia trachomatis: Causes chlamydia, a common sexually
transmitted infection, and trachoma, a leading cause of blindness.

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Chlamydia trachomatis

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Domain Bacteria
Nonproteobacteria Gram-Negative Bacteria
Phylum Spirochaetes
Characteristics: Spiral-shaped bacteria with axial filaments allowing
them to move in a corkscrew motion. They are often found in aquatic
environments and as pathogens in hosts.

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Domain Bacteria
Nonproteobacteria Gram-Negative Bacteria
Phylum Spirochaetes
Notable Species:
Treponema: Includes Treponema pallidum, the causative agent of
syphilis.
Borrelia: Known for causing Lyme disease, transmitted by ticks.

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Treponema pallidum Borrelia burgdorferi

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Domain Bacteria
Nonproteobacteria Gram-Negative Bacteria
Phylum Bacteroidetes
Characteristics: A diverse group of gram-negative bacteria,
commonly found in the intestines of humans and animals.

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Domain Bacteria
Nonproteobacteria Gram-Negative Bacteria
Phylum Bacteroidetes
Notable Species:
Bacteroides: Dominant bacteria in the human colon, involved
in digesting complex molecules.

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Bacteroides fragilis

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Domain Bacteria
Nonproteobacteria Gram-Negative Bacteria
Phylum Fusobacteria
Characteristics: Gram-negative anaerobic bacteria often involved in
human infections, particularly in the oral cavity.

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Domain Bacteria
Nonproteobacteria Gram-Negative Bacteria
Phylum Fusobacteria
Notable Species:
Fusobacterium nucleatum: Associated with periodontal
disease and has been linked to colorectal cancer.

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Bacteroides fragilis

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Domain Bacteria
Gram-Positive Bacteria
Phylum Firmicutes
Characteristics: This phylum includes bacteria with a low G+C
content in their DNA, many of which are gram-positive. They are
known for forming endospores, which are resistant to harsh
conditions.

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Domain Bacteria
Gram-Positive Bacteria
Phylum Firmicutes
Notable Species:
Clostridium: Includes pathogens such as Clostridium botulinum (causing
botulism), Clostridium tetani (causing tetanus), and Clostridium difficile
(associated with severe colitis).
Bacillus: Known for species like Bacillus anthracis (causing anthrax) and
Bacillus subtilis, a model organism for studying bacterial cell processes.

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Domain Bacteria
Gram-Positive Bacteria
Phylum Firmicutes
Notable Species:
Staphylococcus: Includes Staphylococcus aureus, a common cause of
skin infections, and Staphylococcus epidermidis, often associated with
medical device-related infections.
Lactobacillus: Important in the food industry for the production of
yogurt, cheese, and other fermented products.

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Domain Bacteria
Gram-Positive Bacteria
Phylum Firmicutes
Notable Species:
Streptococcus: Includes Streptococcus pyogenes (causing strep
throat) and Streptococcus pneumoniae (causing pneumonia).

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Clostridium botulinum Bacillus anthracis

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Staphylococcus aureus Lactobacillus acidophilus

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Streptococcus pyogenes

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Domain Bacteria
Gram-Positive Bacteria
Phylum Tenericutes
Characteristics:
Tenericutes lack a cell wall, making them unique among bacteria. They
only have a plasma membrane, which contains sterols for added rigidity
and stability. They are pleomorphic (variable in shape) due to the
absence of a rigid cell wall. In Gram Stain, they do not retain crystal
violet and appear gram-negative due to the lack of a cell wall.

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Domain Bacteria
Gram-Positive Bacteria
Phylum Tenericutes
Notable Species:
Mycoplasma pneumoniae causes atypical pneumonia (often referred to
as "walking pneumonia").
Mycoplasma genitalium is associated with urogenital tract infections,
including urethritis in men and cervicitis in women.

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Mycoplasma pneumoniae Mycoplasma genitalium

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Domain Bacteria
Gram-Positive Bacteria
Phylum Actinobacteria
Characteristics: This phylum is characterized by a high G+C content
in their DNA and includes bacteria that are important both in
medicine and the environment.

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Domain Bacteria
Gram-Positive Bacteria
Phylum Actinobacteria
Notable Genera:
Streptomyces: Known for their role in producing a wide range of
antibiotics, including streptomycin, tetracycline, and erythromycin.
Mycobacterium: Includes Mycobacterium tuberculosis (causing
tuberculosis) and Mycobacterium leprae (causing leprosy).

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Domain Bacteria
Gram-Positive Bacteria
Phylum Actinobacteria
Notable Genera:
Corynebacterium: Includes Corynebacterium diphtheriae, the causative
agent of diphtheria.
Nocardia: Soil-dwelling bacteria, some species of which can cause
pulmonary and cutaneous infections in humans.
Propionibacterium: Involved in the production of propionic acid in
cheese-making and includes Propionibacterium acnes, associated with
acne. 130
Streptomyces Mycobacterium leprae

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Corynebacterium diphtheriae Nocardia asteroides Propionibacterium acnes

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Domain Archaea
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Domain Archaea
Major Groups of Archaea
Methanogens
Characteristics: Methanogens are a unique group of archaea that
produce methane as a byproduct of their metabolic processes. They
are obligate anaerobes, meaning they can only survive in
environments devoid of oxygen.

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Domain Archaea
Major Groups of Archaea
Methanogens
Ecological Role: Methanogens play a crucial role in the carbon cycle by
breaking down organic material in anaerobic environments, such as
wetlands, landfills, and the digestive tracts of ruminants (e.g., cows). This
process produces methane, a potent greenhouse gas.

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Domain Archaea
Major Groups of Archaea
Methanogens
Notable Genera:
Methanobacterium, Methanococcus, and Methanosarcina are examples of
methanogens that contribute to methane production in various
environments.

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Methanococcus jannaschii Methanosarcina acetivorans

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Domain Archaea
Major Groups of Archaea
Extreme Halophiles
Characteristics: Extreme halophiles thrive in environments with high
salt concentrations, such as salt lakes, salt mines, and salt pans.
These archaea require high levels of sodium chloride (NaCl) for
growth.

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Domain Archaea
Major Groups of Archaea
Extreme Halophiles
Adaptations: To survive in such hypertonic environments, extreme
halophiles have developed unique adaptations, including the
production of compatible solutes like potassium chloride (KCl) to
balance osmotic pressure.

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Domain Archaea
Major Groups of Archaea
Methanogens
Notable Genera:
Halobacterium and Halococcus are examples of extreme halophiles,
often found in places like the Dead Sea and Great Salt Lake.

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Halococcus salifonidae Halobacterium salinarum

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Domain Archaea
Major Groups of Archaea
Hyperthermophiles
Characteristics: Hyperthermophiles are archaea that thrive in
extremely high-temperature environments, often exceeding 80°C.
These environments include hydrothermal vents, hot springs, and
geothermal soils.

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Domain Archaea
Major Groups of Archaea
Hyperthermophiles
Enzyme Stability: The proteins and enzymes of hyperthermophiles
are highly stable at elevated temperatures, making them of great
interest for industrial applications, such as in PCR (polymerase chain
reaction) where heat-stable DNA polymerases are required.

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Domain Archaea
Major Groups of Archaea
Hyperthermophiles
Notable Genera:
Thermococcus, Pyrococcus, and Sulfolobus are examples of
hyperthermophiles.
Sulfolobus species are often found in sulfur-rich hot springs and are
capable of both aerobic and anaerobic respiration.

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Sulfolobus acidocaldarius Pyrococcus furiosus

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Domain Archaea
Major Groups of Archaea
Acidophiles and Alkaliphiles
Characteristics: Some archaea are adapted to extreme pH
environments, thriving in either highly acidic or highly alkaline
conditions.

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Domain Archaea
Major Groups of Archaea
Acidophiles and Alkaliphiles
Acidophiles: These organisms grow optimally at a pH below 3.
Sulfolobus is an example, often found in sulfuric hot springs.
Alkaliphiles: These archaea thrive at a pH above 9 and are often
found in alkaline soils and soda lakes.

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