BIOL2010-Week3-Metabolism-F24.pptx.pdf

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BIOL2010
Week 3: Metabolism
Metabolism
Metabolism can be defined as all of the chemical reactions
that occur in any living organism

1. Catabolism – catabolic reactions – Breaking down
2. Anabolism – anabolic reactions – Building up

Examples include:
Production of biological molecules – proteins, starches,
DNA/RNA
Cellular respiration – utilizing oxygen and sugar to make
energy
Digestion – breaking down larger molecules into usable
molecules
Muscle contraction – energy production for actin/myosin
Metabolism – Carbon Sources
Microbial organisms can also be described by the source
that the organism uses for Carbon
Autotrophs – Use carbon dioxide as their sole source
of carbon.
Ex: Plants, algae, cyanobacteria
Heterotrophs – organisms that use organic
compounds other than carbon dioxide as a source of
carbon.
Ex: humans, fungi, animals and protozoans.
Most microorganisms are chemoheterotrophs
Use nutrients obtained from hosts, living or dead.
Metabolism – Energy Source

Phototrophs – Use light as an energy
source
Energy produced through photosynthesis
Chemotrophs – use organic or inorganic
molecules as an energy source
Two categories of chemotrophs:
Chemolithotrophs – use inorganic molecules as
an energy source
Chemoorganotrophs – use organic molecules
as an energy source.
 Carbon + Energy Sources

The terms relating to an energy source can be combined with
the terms relating to carbon source:
Photoautotrophs – organisms that use photons as an energy source
and carbon dioxide as their carbon source - Plants
Photoheterotrophs – organisms that use light as an energy source
but other organic molecules for carbon – rare form of metabolism
Chemoautotrophs – use chemicals as an energy source and carbon
dioxide as their sole carbon source – rare form of metabolism
Chemoheterotrophs – use chemicals as their energy source and
molecules other than carbon dioxide as their source of carbon –
most organisms (except plants)
Metabolism
The nutrients needed by Microorganisms include:
Carbon, Nitrogen, Sulfur, Phosphorus & Vitamins
Additional elements required include
Sodium, potassium, chlorine, magnesium, calcium, iron, and iodine
Organisms also require a continuous intake of essential nutrients that
cannot be synthesized:
Fatty acids and amino acids
These combine to make the essential macromolecules of life:
Carbohydrates, amino acids, lipids, proteins, and DNA/RNA
Metabolism
Carbon compounds are the main energy source for most microbes
Generally in the form of carbohydrates
Nitrogen is used in the synthesis of specific materials that include:
Enzymes, proteins, nucleic acids
Some bacteria are able to use chemicals as a source of energy
Sulfur is used in the production of amino acids and certain co-enzymes
Phosphorus is used on the production of nucleic acids and phospholipids
Trace elements (Cu, Zn, Co, Fe, Mn, and Se) are used as co-factors with enzymes
Growth factors:
Vitamins are used as co-enzymes
Also require the presence of amino acids, purines and pyrimidines
Metabolism – Nutritional
Requirements
The nutritional requirements of a
microorganism is determined by:
The number and type of enzymes that it has.
Microorganisms with fewer enzymes need
more nutrients because they cannot
synthesize needed substances.
Enzymes

Enzymes are proteins which speed up
chemical reactions that take place inside
cells
Lower the activation energy of a reaction
Allow the reaction to proceed using less energy
Act on substrates which convert to different
molecules
Activation energy is the energy it takes to Start a
chemical reaction
Biological catalysts
Enzymes

Enzymes lower the activation energy
A reaction can occur easily in order from
#1 – #4 as shown by the red line on this
graph
The energy required to start the
reaction, without a catalyst, would
probably damage or destroy the cell
Enzymes

Factors Affecting Enzymes
Enzyme activity can be affected by:
1. pH
2. Temperature
Enzymes and pH

An enzyme works best at a specific pH
Referred to as the optimum pH for that
enzyme
A change in pH will cause the Shape of the
enzyme to change
This alters the enzymes active site so that
the enzyme and substrate no longer fit
together
A protein that has changed its shape is said
to be Denatured
Enzymes and Temperature

An enzyme works best at a specific
temperature range
Referred to as the optimum temperature
for that enzyme
A change in temperature will cause the
shape of the enzyme to change:
Altering its active site and ability to
function
Microbial Metabolism
Anabolic reactions are chemical reactions that involve the
synthesis of large molecules from their smaller
components or from smaller molecules
Anabolic reactions result in the release of larger
molecules and consume energy
Examples include:
2 H2(g) + O2(g) 🡪 2 H2O(g)
Na(s) + Cl2(g) 🡪 NaCl(s)
6C02 + 6H20 + energy → 602 + C6H1206
Amino acid1 + amino acid2 + amino acid3 🡪 a
protein made up of 3 amino acids
Microbial Metabolism
Catabolic reactions are chemical reactions that
involve the breakdown of large molecules into their
components or into smaller molecules.
Catabolic reactions result in the release of smaller
molecules and energy
Examples include:
2 H2O(g) 🡪 2 H2(g) + O2(g)
NaCl(s) 🡪 Na(s) + Cl2(g)
602 + C6H1206 → 6C02 + 6H20 + energy
Microbial Metabolism
Adenosine triphosphate (ATP) is the energy
molecule used by cells

ATP:
Produced in the MITOCHONDRIA
Provides the energy required for metabolism
Movement such as muscle contractions
Movement of chromosomes during cell division
Active transport
Production of proteins for enzymes, hormones
etc.
Microbial Metabolism
Adenosine diphosphate (ADP) is the PRECUSOR to
ATP
ADP:
A lower energy compound
During cellular respiration an extra phosphate
group added to it using a high energy bond
When the cell needs energy this phosphate group
can be removed, releasing energy for the cell to
use
Adenosine triphosphate (ATP) is the energy molecule
used by cells
Microbial Metabolism
One other special molecule of interest produced: CyclicAMP (cyclic adenosine
monophosphate):
A molecule made from ATP that is a common signaling (or second messenger) molecule found
inside cells
cAMP is an INTERGRAL part of a series of reactions required for a chemical reaction to occur
It RELAYS messages from molecules outside the cell telling the cell what metabolic activity to
INITIATE inside the cell
cAMP which will go on to catalyze a specific reaction inside the cell
EPINEPHRINE (adrenaline) is an example of one compound that uses cAMP
Epinephrine is used to initiate (start) the breakdown of glycogen by cells in the in liver
Epinephrine increases this breakdown even though it does not enter the cells
Glycolysis
All living cells can convert glucose into pyruvate
Process is called glycolysis
Takes place in the cytoplasm
Bacteria can convert specific sugars into pyruvate using the glycolytic pathway
Mannitol – only a few medically significant bacteria can convert
Staphylococcus aureus, Enterococcus & Enterobacter
Glucose
Lactose
Sucrose
The ability to convert those sugars forms the basis for biochemical tests to identify bacteria
Mannitol Salt Agar test - looks for the evidence of mannitol fermentation and acid production
The end result of each catabolic process is the production of pyruvate
Krebs Cycle

Krebs Cycle = Citric Acid Cycle =
Tricarboxylic Acid Cycle
After glycolysis:
In the presence of oxygen (aerobes), pyruvate is
changed to Acetyl-CoA, and can then pass
through to the Krebs cycle. Occurs in the
cytoplasm.
The Products of the Krebs cycle include ATP,
carbon dioxide gas, and electrons are transferred
to molecules of NADH, and FADH2. These act as
electron carriers in the next step.
Electron Transport Chain (ETC)
A series of proteins within the membrane of the
cell (happens in the mitochondria in eukaryotic
cells).
These proteins accept electrons from NADH, and
FADH2, and pump the H+ ions outside the
membrane.
This builds up a electro chemical (charge)
gradient. H+ ions then flow back across the
membrane through an enzyme, ATP synthase.
As the ion pass through the pump Pi is added to
ADP to create ATP.
Proteins

Proteases

Deamination
Protein metabolism
Amino
Acids

Bacteria can also use proteins and fatty acids
as a source of energy
Can convert proteins into pyruvate which is cycled
into the Krebs cycle
Can also produce intermediaries from amino acids
- Acetyl-CoA
To use proteins, deamination must take place
Remove the amine group from the AA
Ammonia is produced and excreted
Some bacteria convert the ammonia to urea and use
that as an entry point into the TCA cycle
 Fats and Lipids Metabolism
Fats and Lipids

Fatty Acids Glycerol Bacteria can cycle fats into the TCA
cycle.
Pyruvate Fats decompose to glycerol and fatty acids
Acetyl-CoA
Glycerol is converted to Pyruvate so enters
Acetyl-CoA Acetyl-CoA through the Acetyl-CoA entry point
Fatty acids are entered directly into the Krebs
Acetyl-Co-A Enters directly into the Kreb’s Cycle cycle
Fermentation
Fermentation is a low energy anaerobic metabolic process,
very little energy is created, electron acceptors and carries are
generated which allows the organism to continue metabolic
processes.

Some bacteria reduce pyruvate to produce energy using
fermentation
Lactic Acid fermentation
Alcohol fermentation
2,3-Butanediol fermentation
Mixed acid fermentation
Fermentation
The fermentation is dependent upon the types of enzymes
that the organisms make or possess
Lactobacillus uses an enzyme that converts pyruvate to lactic
acid
Lactic acid is very sour and has industrial applications
Humans can also convert pyruvate to lactic acid in the
muscles
When our muscles run out of oxygen and require energy
– during a hard workout – burn
Saccharomyces cerevesii– fungus makes alcohol through
fermentation
Enterobacter – uses fermentation to produce 2,3-butanediol
Eserichia coli produces mixed acids
All of these processes produce a little ATP
 Metabolism
Carbohydrates Fats and Lipids Proteins

Acetyl-CoA NADH

Glycolysis Krebs Cycle Electron Transport Chain

Pyruvate FADH2
34 ATP

2 ATP 2 ATP
FERMENTATION