MICR20010 Lecture 6.pptx

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MICR20010 Lecture 6
Bacterial Physiology and
Metabolic Diversity
Dr. Jennifer Mitchell
Microbiology
School of Biomolecular and Biomedical Science

Lecture 5
• Microbial Growth and Physiology
• Growth of Bacteria
– Bacteria Divide by Binary Fission
– Growth of Bacteria on Solid Medium
– Growth of Bacteria in Liquid Medium

Growth Phases of liquid Bacterial Culture
Measurements of Bacterial Growth
Direct Measurements of Bacterial Growth:
Indirect Measurements of Bacterial
Growth:
• Growth Requirements
•
•
•
•

Learning Outcomes
•
•
•
•
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•
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Metabolic diversity
Chemical basis of energy production
Simplified model of energy production
Energy storage and release
Chemotrophs
Phototrophs
Chemotrophs
– Chemoorganotrophs
– Chemolithotrophs

• Autotrophs
• Heterotrophs
• Photosynthesis

Carbon and Energy
All cells need carbon and energy sources for their
metabolic activities
Different microorganisms have evolved every
conceivable means of obtaining carbon and energy
This results in significant metabolic diversity
Hence microbes have been able to colonise
environmental habitats which are too extreme for
other
life forms.

s://www.teagasc.ie/news--events/daily/other/the-soil-microbiome-and-soil-health.

Chemical Basis of Energy
Production
1. Chemical reactions used to generate energy
2. Specifically chemical reactions involving the release of electrons
3. Electrons have stored energy and when an atom or molecule
loses that electron (becomes oxidized) that energy is released
4. Oxidation: atom or molecule loses one or more electrons
5. Reduction: atom or molecule gains those electrons.
6. Energy sources are oxidised to release electrons which have
stored energy
7. Energy generated is stored in the form of ATP
OIL RIG
Oxidation Is Loss of electrons
Reduction Is Gain of electrons

Simplified Model of Energy
Production
Light

Iron

oxidised
Enzymes

ed
s
i
d
s
oxi yme
z
Glucose En

e- ee- eee-

Example of simple oxidation reaction:
Fe2+ ⇋ Fe3+ + eFerrous iron
Ferric iron

ATP

ENERGY
Energy Storage:
•
•
•

•
•

Used to trap energy released
from chemical reactions
Energy stored as high-energy
phosphate bond
Inorganic phosphate group
attached to adenosine
diphosphate (ADP)
Adenosine triphosphate (ATP)
The energy currency of the
cell

Energy Release:
•

Phosphate enzymatically
removed from ATP to release
energy

How to get Energy?
• Chemotrophs: Derive energy from
chemicals
• Chemotrophs
– Chemoorganotrophs (Use organic chemicals)
– Chemolithotrophs (Use inorganic chemicals)

• Phototrophs
– Derive energy from light

Chemoorganotrophs
• Derive energy from organic chemicals
• Organic chemicals are compounds
containing carbon
• All cells require carbon as a major nutrient,
hence these chemicals are a good source of
carbon and energy for chemoorganotrophs
• 1000’s of different organic chemicals present
on Earth
• ALL can be broken down by microorganisms
to derive energy

How do chemoorganotrophs derive energy from
organic chemicals?
Answer:
• Oxidation of the compound releases electrons, which
are ultimately used to generate ATP.
• Electrons have stored energy and when an atom or
molecule loses that electron (becomes oxidized) that
energy is released
• Oxidation: atom or molecule loses one or more
electrons
• Reduction: atom or molecule gains those electrons.
• Energy sources are oxidised to release electrons
which have stored energy

Aerobes
• Some chemoorganotrophs can only
produce energy in the presence of oxygen
Anaerobes
• Microbes that can only produce energy in
the absence of oxygen
Facultative anaerobes
• Microbes that produce energy in the
presence or absence of oxygen

Methanogens
• Livestock produce significant amounts of methane as
part of their normal digestive processes. Some feed
additives can inhibit the microorganisms that produce
methane in the rumen and subsequently reduce
methane emissions.
• Ruminant livestock – cattle, sheep, buffalo, goats, deer
and camels – have a fore-stomach (or rumen) containing
microbes called methanogens, which are capable of
digesting coarse plant material and which
produce methane as a by-product of digestion (enteric
fermentation): this methane is released to the
atmosphere by the animal belching.

www.agric.wa.gov.au/climate-change/carbon-farming-reducing-methaneons-cattle-using-feed-additives#:~:text=Feed%20additives%20or%20supplemen

Supplements
• Methane-reducing feed additives and
supplements inhibit methanogens in
the rumen, and subsequently reduce
enteric methane emissions.
• Methane-reducing feed additives and
supplements are most effective when
grain, hay or silage is added to the diet,
especially in beef feedlots and dairies.

Reducing Methane
• Methane-reducing feed additives and
supplements can be:
• synthetic chemicals
• natural supplements and compounds, such
as tannins and seaweed
• fats and oils.

• Feeding one type of seaweed at 3%
of the diet has resulted in up to 80%
reduction in methane emissions from
cattle.

Active inhibitors
• trihalomethanes, such as bromoform,
which is an active ingredient that
decreases methane emissions
• Tannins

Benefits:
• The reduced volume of methane
formation may lead to better
efficiency of feed utilisation, given
that methane emissions represent a
gross energy loss from feed intake of
about 10%.

Chemolithotrophs
• Derive energy from inorganic chemicals
• Inorganic chemicals are compounds which
do not contain carbon, e.g. H2, H2S, Fe2+
• These inorganic compounds are oxidised
to release electrons for ATP synthesis
• However all cells require carbon as a
major nutrient

Chemolithotrophs
Name

Examples

Iron bacteria

Acidithiobacillus
ferrooxidans

Nitrosifying bacteria

Nitrosomonas

Nitrifying bacteria

Nitrobacter

Chemotrophic purple
sulfur bacteria
Sulfur-oxidizing
bacteria
Aerobic hydrogen
bacteria
Thiobacillus
denitrificans
Sulfate-reducing
bacteria: Hydrogen
bacteria
Sulfate-reducing
bacteria: Phosphite
bacteria
Methanogens
Carboxydotrophic
bacteria

Halothiobacillaceae

Source of energy and
electrons
Fe2+ (ferrous) → Fe3+
(ferric) + eNH3 (ammonia) → NO2(nitrite) + eNO2- (nitrite) → NO3- (nitrate)
+ e-

Respiration electron
acceptor

S2 (sulfide) → S0 (sulfur) + e-

O2 → H2O

O2 → H2O
O2 → H2O
O2 → H2O

S0 (sulfur) → Sulfate (SO2−4)
O2 → H2O
+ eH2 (hydrogen) → H2O (water)
Cupriavidus
O2 → H2O
metallidurans
+ eS0 (sulfur) → Sulfate (SO2−4)
NO3- (nitrate)
Thiobacillus denitrificans
+ eChemotrophic
Rhodobacteraceae

H2 (hydrogen) → H2O (water)
Sulfate (SO2−4)
+ eDesulfotignum
phosphitoxidans

PO3−3 (phosphite) → PO3−4
(phosphate) + e-

Sulfate (SO2−4)

Archaea

H 2 → H2O + e -

CO2 (carbon dioxide)

Carboxydothermus
hydrogenoformans

carbon monoxide (CO) →
carbon dioxide (CO2) + e-

H2O (water) → H2
(hydrogen)

Chemolithotrophs
• Chemolithotrophs obtain carbon from CO 2 –
autotrophy
• Ecological niche and competition
• Lithotrophy is advantageous because organisms
deriving energy from inorganic compounds do
not have to compete with chemoorganotrophs.
• In addition some of their energy sources (H 2,
H2S) are waste products from the
chemoorganotrophs

Heterotrophs and Autotrophs
Heterotrophs
• Microbial cells which use one or more
organic compounds as their carbon source
are called heterotrophs
Autotrophs
• Microbial cells which use CO2 as their
carbon source are called autotrophs
– CO2 fixation or Calvin cycle

Autotrophs
• Autotrophs are called primary producers
because they produce organic matter from
CO2 in the air.
• Chemoorganotrophs and other organisms
can ultimately use this organic matter by
feeding on the autotrophs or their waste
products
• All organic matter on the planet has been
synthesised from CO2 by autotrophs

Phototrophs
• Use light as energy source
• Phototrophs contain pigments which allow
them to use light as an energy source
• These pigments give the cells colour

Photosynthesis
• Phototrophs obtain energy from light using
photosynthesis
• Photosynthesis involves reactions in which
ATP is generated
• Oxygenic photosynthesis – oxygen is
produced as a bi-product
• Anoxygenic photosynthesis – no oxygen is
produced

What are the Pigments in
Phototrophic Cells?
Chlorophylls
Carotenoids

Chlorophylls
• Green colour
• Similar to the pigments responsible for
photosynthesis in plants
• Phototrophic bacteria contain chlorophylls
called bacteriochlorophylls
• In plant cells photosynthesis takes place in
chloroplasts
• In bacteria photosynthesis takes place in a
specially developed cytoplasmic membrane.

Carotenoids
• Yellow, red, brown and green colours
• Carotenoids are closely associated
with bacteriochlorophyll but play no
direct role in photosynthesis
• Transfer light energy to
bacteriochlorophyll
• Carotenoids have a photoprotective
role

Photosynthetic Bacteria

Further Reading
• Brock Biology of Microorganisms
• Chapter 5 “Nutrition, Laboratory Culture
and Metabolism of Microorganisms”