Download Freeman 1e: How we got there

An Overview of Microbial Life
Chapter 2
Elements of Cell and Viral
Structures:

3 Domains: Archae, Eubacteria, Eukaryota
 Two structural types of cells are recognized:
the prokaryote and the eukaryote.
 Prokaryotic cells have a simpler internal
structure than eukaryotic cells, lacking
membrane-enclosed organelles.
 Viruses:
– Viruses are not cells but depend on cells for their
replication.
Cells from each domain
Eukarya
Bacteria
Archae
The basic components..

All microbial cells share
certain basic structures in
common, such as
cytoplasm, a cytoplasmic
membrane, ribosomes,
and (usually) a cell wall.
– Note: Animal cells typically
do not have a cell wall

The major components
dissolved in the cytoplasm
include
– Macromolecules
– Inorganic ions
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Eukaryotic Cells



Larger and structurally
more complex
Euk. microorganisms
include algae, fungi and
protozoa
Membrane enclosed
organelles
– Nucleus
– Mitochondria
– Chloroplasts
(photosynthetic cells
only)
Prokaryotic Cells




Lack membrane enclosed organelles
Include Bacteria and Archae
Smaller than eukaryotic cells (Typically ~1-5
um long and ~1um in width)
However, can vary greatly in size
Viruses



Not cells
Static structures which
rely on cells for
replication and
biosynthetic machinery
Many cause disease
and can have profound
effects on the cells they
infect
– Cancer, HIV

However, can alter
genetic material and
improve the cell
Arrangement of DNA in
Microbial Cells

Genes govern the properties of cells, and a
cell's complement of genes is called its
genome.
 DNA is arranged in cells to form
chromosomes.
 In prokaryotes, there is usually a single
circular chromosome; whereas in
eukaryotes, several linear chromosomes
exist.
Nucleus vs. Nucleoid


Nucleus: a membraneenclosed structure that
contains the
chromosomes in
eukaryotic cells.
Nucleoid: aggregated
mass of DNA that
constitutes the
chromosome of cells of
Bacteria and Archaea
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Prokaryotic DNA
Most DNA is circular
 Most have only a single chromosome
 Single copy of genes

– Haploid

Many also contain plasmids
Plasmids

Plasmids are circular
extrachromosomal
genetic elements (DNA),
nonessential for growth,
found in prokaryotes.
 Typically contain genes
that confer special
properties (ie unique
metabolic properties)
 Useful in biotechnology
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Eukaryotic DNA
Organized into linear molecules
 Packaged into chromosomes

– Number varies

Typically contain two copies of each
gene
– Diploid
Genes, genomes, and proteins
E.coli genome= a single circular
chromosome of 4.68 million base pairs
 # of genes: 4,300
 A single cell contains:

– 1,900 different proteins
– 2.4 million protein molecules
– Abundance of proteins varies
Genome size, complexity, and
the C-value paradox

Genome size does
not necessarily
correlate with
organismal
complexity
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In actuality….
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The Tree of Life
Evolution: change in allelic
frequencies over generations
 The evolutionary relationships between
life forms are the subject of the science
of phylogeny.
 Phylogenetic relationships are deduced
by comparing ribosomal sequences

The three domains of life

Comparative ribosomal RNA sequencing has
defined the three domains of life: Bacteria,
Archaea, and Eukarya.
What has this sequencing
revealed??

Molecular sequencing has shown that the
major organelles of Eukarya have
evolutionary roots in the Bacteria
 Mitochondria and chloroplasts were once
free-living cells that established stable
residency in cells of Eukarya eons ago.
– The process by which this stable arrangement
developed is known as endosymbiosis.
What has this sequencing
revealed?? Cont.
Although species of Bacteria and
Archaea share a prokaryotic cell
structure, they differ dramatically in their
evolutionary history.
 Archae are more closely related to
eukaryotes than are species of bacteria

Molecular sequencing and
microbiology

Overall rRNA sequencing technology has
helped reveal the overall evolutionary
connections between all cells
– In particular prokaryotes

Impacted subdispiciplines
– Microbial classification and ecology
– Clinical diagnostics

Can identify organisms without having to
culture them
Microbial Diversity
Cell size and morphology
 Metabolic strategies (physiology)
 Motility
 Mechanisms of cell division
 Pathogenesis
 Developmental biology
 Adaptation to environmental extremes
 And many more

Physiological Diversity of
Microorganisms


All cells need carbon and energy
sources
Energy can be obtained in 3
ways:
– Organic chemicals
– Inorganic chemicals
– Light

Types of physiological diversity:
–
–
–
–
–
Chemoorganotrophs
Chemolithotrophs
Phototrophs
Heterotrophs and Autotrophs
Habitats and Extreme environments
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Chemoorganotrophs

Chemoorganotrophs obtain their energy
from the oxidation of organic compounds.
– Energy conserved as ATP

All natural and even synthetic organic
compounds can be used as an energy source
 Aerobes
 Anaerobes
 Most microorganisms that have been cultured
are chemoorganotrophs
Chemolithotrophs
Chemolithotrophs obtain their energy
from the oxidation of inorganic
compounds.
 Found only in prokaryotes
 Can use a broad spectrum of inorganic
compounds
 Advantageous because can utilize
waste products of chemoorganotrophs

Phototrophs

Phototrophs contain pigments that allow
them to use light as an energy source.
– ATP generated from light energy
– Cells are colored

Oxygenic photosynthesis:
– O2 involved
– Cyanobacteria and relatives

Anoxygenic photosynthesis:
– No O2
– Purple and green bacteria
Autotrophs and Heterotrophs

All cells require carbon as a major nutrient
 Microbial cells are either:
– Autotrophs use carbon dioxide as their carbon
source, whereas heterotrophs use organic
carbon from one or more organic compounds.
– Autotrophs considered primary producers
• Synthesize organic matter from CO2 for themselves and
that of chemoorganotrophs
• All organic matter on earth has been synthesized from
primary producers
Habitats and Extreme
Environments

Microorganisms are everywhere on Earth
that can support life
 Extremophiles: organisms inhabiting
extreme environments
– Boiling hot springs,
– Within ice, extreme pH, salinity, pressure
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Examples of Extremophiles:
Prokaryotic Diversity
Several lineages are present in the
domains Bacteria and Archaea
 An enormous diversity of cell
morphologies and physiologies are
represented
 rRNA analysis has shown dramatic
differences in phenotypic characteristics
within a given phylogenetic group

Bacteria
Proteobacteria

The Proteobacteria is the largest division
(called a phylum) of Bacteria
 A major lineage of bacteria that contains a
large number of gram(-) rods and cocci
 Represent majority of known gram(-) medical,
industrial, and agricultural bacteria of
significance
 Extreme metabolic diversity:
–
–
–
–
Chemorganotrophs: E.coli
Photoautotrophs: Purple sulfur bacterium
Chemolithotrophs: Pseudomonas, Aztobacter
Pathogens: Salmonella, Rickettsia, Neisseria
Proteobacteria examples
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Chemolithotrophic sulfur-oxidizing
bacteria Achromatium
Neisseria gonorrhoeae
Gram-positive bacteria



United by a common cell wall structure
Examples:
Spore forming:
– Clostridium, Bacillus

Antibiotic producing:
– Streptomyces

Lactic acid bacteria:
– Streptococcus
– Lactobacillus

Mycoplasmas:
– Lack cell wall
– Small genomes
– Often pathogenic
Cyanobacteria

The Cyanobacteria
are phylogenetic
relatives of grampositive bacteria and
are oxygenic
phototrophs.
 First oxygenic
phototrophs to have
evolved on Earth
Planctomyces

Characterized by
distinct cells with
stalks that allow for
attachment to solid
surfaces
 Aquatic
Spirochetes

Helical shaped
 Morphologically and
phylogenetically
distinct
 Widespread in
nature and some
cause disease
– Most notable sp
cause Syphilis and
Lyme Disease
Spirochaeta zuelzerae
Green sulfur and non-sulfur
bacteria

Contain similar
photosynthetic
pigments
 Can grow as autotrophs
 Chloroflexus
– Inhabits hot springs and
shallow marine bays
– Dominant organism in
stratified microbial mats
– Important link in the
evolution of
photosynthesis
Chlamydia

Most species are
pathogens
 Obligate intracellular
parasites
 How would this
affect an immune
response?
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Deinococcus

Contain sp with
unusual cell walls
and high level of
resistance to
radiation
 Cells usually exist in
pairs or tetrads
 Can reassemble its
chromosome after
high radiation
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Aquifex, Thermotoga, Env-OP2

Sp that branch early
on the tree
 Unified in that they
grow at very high
temps:
hyperthermophily
 Inhabitats of hot
springs
Archaea

There are two lineages
of Archaea: the
Euryarchaeota and the
Crenarchaeota
 Many are extremophiles
 All are chemotrophic
– Many using organic
carbon
– While others are
chemolithotrophs
Euryarchaeota & Crenarchaeota

Physiologically diverse
groups
 Many inhabit extreme
environments
– From extreme pH,
temperature, salinity
Limitations of Phylogenetic
analyses
Not all Archaea are extremophiles
 Difficult to culture
 Based on molecular microbial ecology,
the extent of diversity is much greater
than once thought

Eukaryotic Microorganisms

Collectively, microbial eukaryotes are known
as the Protista.
 Microbial eukaryotes are a diverse group that
includes algae, protozoa, fungi, and slime
molds
 Cells of algae and fungi have cell walls,
whereas the protozoa do not.
 The “early-branching” Eukarya are
structurally simple eukaryotes lacking
mitochondria and other organelles
– Ex Giardia
Eukaryotic microbial diversity
Eukaryotic microbial diversity

Diplomonads: flagellates, many are parasitic
– Ex: Giardia lamblia (synonymous with Lamblia
intestinalis and Giardia duodenalis) is a
flagellated protozoan parasite flagellated
protozoan parasite

Trichomonads: anaerobic protist, many are
pathogenic
– Ex. Trichomonas vaginalis

Flagellates: all protozoa in this group utilize
flagella for motility, free-living, and pathogenic
– Ex. Trypanosomes

Slime molds: resemble fungi and protozoa
– Ex. Dictyostelium discoideum
Fungi
Protozoa
Algae
Lichens

Some algae and
fungi have
developed
mutualistic
associations called
lichens.
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