Agricultural Microbiology MICR20010 Past Paper PDF

Summary

This document appears to be lecture notes on agricultural microbiology, covering topics such as fermentation pathways, wine making, and beer making. It includes information on different microorganisms involved in these processes and details on important factors such as temperature, pH, and osmolarity.

Full Transcript

MICR20010

Agricultural Microbiology

Dr. Tadhg Ó Cróinín
 Praccal MCQ Exam Complete
Praccal Online MCQ exam results will be
released this evening.

Output is a percentage which is converted to a
grade using the alternave linear scale.
Percentage to Grade

3
 Praccal MCQ Exam Complete
Praccal Online MCQ exam results will be
released this evening.

Output is a percentage which is converted to a
grade using the alternave linear scale.

Remember you sll have 70% of the grade to
make up in the *nal exam….. Study the lecture
slides!!!…
 MICR20010 - remaining lectures
Lecture 10 – Microorganisms and Disease
Lecture 11 – The Immune System
Lecture 12 - Pathogenic Bacteria
Lecture 13 – Pathogenic Fungi and Viruses
Lecture 14 – Anbioc Resistant Microorganisms
Lecture 15 – Microbiology in the Food Industry – The
Fungi
Lecture 16 – Microbiology in the Food Industry -
Fermentaons
Lecture 17 – The Nitrogen Cycle
 Fermentaons – Food and Drink..
An ancient process
which pre-dates the
science of microbiology

Crical for the
producon of Beer,
Wine and many Dairy
products.
Fermentaon pathways
 Fermented Vegetables
Soya bean fermenta on
– Koji - Aerobic fermentaon with
Aspergillus
– Moromi - Anaerobic
Tetragenococcus halophila
lowers pH as acid tolerant yeasts
produce avour
SaurKraut
– Lactobacilli fermentaon of
shredded cabbage
– Salt added to prevent Gram
negave contaminants
 Fermented Meat and Fish
Various Dry Sausages
– Salami, Pepperoni, Bologna etc.
– Staphylococcus, Pediococcus,
Micrococcus, Lactobacilli.

Fish Sauces
– Variety of sauces and pastes
used in Asian cooking.
– Incubaon of *sh and shrimps
and salt into sealed vessels to
allow natural micro?ora work
(mostly S. carnosus and
Staphylococcus piscifermentans)
 CoBee and Cocoa
Coee - Co ea arabica
– Wet or dry process to obtain bean
from berry
– Wet process uses indigenous fungi
and bacteria secreng proteolyc
enzymes
– Then an acidic fermentaon by
lacc acid bacteria

Cocoa - Theobrama cacao
– To release the beans from the pods
– A sequence of fermentaons
involving yeasts, lacc acid and
acec acid bacteria
Saccharomyces cerevisiae
 Brewing
Ancient use of fermentaon and most
important economically.

Primarily S. cerevisiae but occasionally
Zymomonas

Zymomonas – African palm wine or Mexican
pulque.
 The Basics
Aerobic pathway is preferred by yeast so need
to keep oxygen low to force fermentaon and
producon of alcohol.
Carbon dioxide produced must be allowed to
escape…
Glucose substrate is needed to provide the
starng material.

DiBerent approaches give diBerent results.
 Wine making
Grapes used as the sugar source.

Fructose + Glucose and natural acidity

Soil, climate, grape variety, method of pressing,
primary and secondary fermentaons.

Red wine - made with skins - anthocyanins
 Making the “Must”
Grapes crushed mechanically or by hand (or
foot).

Fermentaon by indigenous yeasts or starter
cultures.

Rate decided by temperature, pH, inial sugar
content and yeast strain.
 The Fermentor
Typically wooden fermentors but now
stainless steel mostly
Cooling required for fermentaon as heat
produced (1.3oC per 10g/L)
Reduce un-wanted yeasts using SO2.
Add starter culture of S. cerevesiae.
Secondary fermentaon?
Clarifying agents, *ltraon and boJling.
Wine Producon
 Cider?
Cider producon not unlike that of wine.

OLen more sugar is added to help the
reacon but apple juice does have high sugar
levels.

But what about Beer? Where’s the sugar?
 The problem with Barley
Barley unsuitable as
sugar source as 65%
Starch

Starch must be
accessed and converted
to a usable sugar
Malting Process - Partial
Germination

Malting process used to generate
enzymes (amylases) and carbon
source useful for fermentation

Green malt, produced after ve
days of germination, is kiln dried
and partly cooked in a forced ow
of hot air (C).

Kilning used to preserve the malt
 Making Malt - The Steps
Soak or Steep for 2 days at 10-16oC.
Occasionally aerate
Germinate for 3-5 days at 16-19oC on malng
?oors. Aerated and turned mechanically
Kiln by drying at 50-60oC and then cure at 80-
110oC - arrests development, stops enzyme
denaturaon, adds ?avour
Making Wort
Malted grains provide both
the enzymes and the
substrate but adjuncts can
be added.

Starch converted to simple
sugars.

Wort prepared as the
glucose source (mashing).

Then *ltered
 Mashing - Making the Wort
Allowing the enzymes to work on the
endogenous and added substrates
Various types of Mashing
– Decocon mashing - First 35-40oC (protein rest),
then remove some of mash and boil and re-
introduce to raise temp… and repeat

– Infusion mashing
 But what is happening?
Amylase and other enzymes breaking starch down to
fermentable sugars.

Many proteases also present to break down cell walls
to allow access to starch.

If enzymes liming then commercial enzymes can be
added

Finally boil the sweet wort with Hops
Wort is boiled
Amylases inactivated
Starch breakdown now stopped
alpha acids and oils from hops Kills microbes in the
wort
Sugars are caramelized

12
Hops are added;

Bitter herb grown on a vine
Have a preservative effect in the beer
Stabilize flavor
Hop oils have Alpha acids – bitter taste and
preservative.
Brewing
ALer preparaon of
Wort add yeast.

Allow to ferment for
approx 3 days where
large amounts of CO2
produced

Then a further 10 days
Brewing: types of brewing yeasts
Yeast strain type:
1. Top fermenting yeast
 Remain distributed in wort
 Carried to top by CO2
 14-23C fermentation
 Ales
 S.cerevisiae
Yeast strain type:

2.Bottom yeasts
 Settle to bottom
 6-12C fermentation
 Saccharomyces carlsbergensis
(budding yeast)
 Larger
 Differentiation of an ale yeast from a lager yeast

27oC S.carlsbergensis

S. cervisiae

S. Cervisiae and S. carlsbergensis will grow at 27oC
S. cervisiae
37 C
o

S.carlsbergensis

S. cervisiae will grow at 37oC S. carlsbergensis will not
Brewing
Allow yeast to seJle to
boJom

Siphon oB beer into
boJles and allow to age
further.
 Dislled Beverages?
Alcohol boils at 78 degrees

Malt – Whiskey
Wine - Brandy
Molasses – Rum
Grain/potatoes – Vodka

Colour due to aging in
barrels
 Economic importance?
We are one of the
largest consumers of
alcohol in Europe.

What is our history in
brewing like?

A signi*cant growth
area.. Local breweries!
Scaling up Ethanol producon
50 Billion litres from
the fermentaon of
various feedstocks.

Industrial solvent

Biofuels
 Vinegar
Not only a condiment but an important
preservave
A soluon with greater than 4% Acec acid
America - Cider
Europe - Wine
Britain - Malt
Key being Acec acid bacteria
Vinegar Producon

Changing ethanol to
Vinegar

Dislled vinegar

Acec acid bacteria
convert ethanol to
acec acid
Vinegar Producon
Fermented Dairy products

Milk
87% water
Proteins: whey and casein
Fat- flavour
Carbohydrates- Lactose
Vitamines

Cheese and Yoghurt
 Microorganisms involved in Dairy
Fermentaons
Lactococci, Lactobacilli and S. thermophilus
are the main organisms.

Can be single or mixed cultures

Other organisms can be used to add ?avour or
texture
 Curdling Milk
Acidi*caon of the milk leads to the coagulaon of
milk proteins - curd

This can be achieved by a pure starter culture or a
mixed culture.

Rennet – enzyme mix that promotes curdling

Tradionally Calf Chymosin but now oLen using
fungal proteases.
Dairy Products
 A second inoculum
ALer curd salted a second microbial inoculum can be
added and fermentaon proceeds
– Swiss Cheese - Propionibacterium freundenreichii ?avour
and gas bubbles
– “Blue Cheeses” - Penecillium roquefor inoculated into
cheese
– Camembert - Penicillium camember gives the
characterisc rind and ?avor

DiBerent variaons in the procedure lead to a huge
variety in cheeses.
Huge variaon in Cheeses
 Dairy Products
Other Fermented milk
products
– Yoghurt
– Buttermilk
– Sour Cream

Streptococcus
thermophilus
Yoghurt
controlled fermentation of milk
– Lactobacillus bulgaricus and Lactotococcus
thermophilus (also known as Streptococcus
thermophilus)
Take pasteurised milk
add Streptococcus thermophilus
Lactobacillus bulgaricus
incubate 42-45C..yoghurt

Symbiotic event:
L.bulgaricus: proteases—peptides (stimulate) and
lactic acid
S. Thermophillus: acids (folic and formic) used by
L bulgaricus for purine synthesis.
 The Probioc World
The “Good Bacteria” theory

Begun by Elie MetchnikoB
(1845-1916)

Later pasteur instute
produces “la Ferment”

1930s Minoru Shirota selects L.
casei Shirota from Human
feces… now produced by
Yakult.
 The Probioc World

Bi*dobacteria and Lacc acid
bacteria - Commensals found in gut
(16 and 3% of normal ?ora)

Said to be useful in treang anbioc
induced diarrhea, IBS, IBD and even
associated with Brain and behavior..

Others suggest eBects may be more
placebo than eBect

Sll much research needed to *nd
out how these organisms aBect the
host.
 In Summary
Fermentaons key in Industrial Microbiology.
Crical for Dairy Industry
– Cheese, Yoghurt, Probiocs
Beer and Wine
– Fermentaon by S. cerevesiae
Acec acid bacteria and the producon of
vinegar.
 Final lecture on Friday

The Nitrogen Cycle and Environmental Microbiology

How to study for exam!

Dr. Tadhg Ó Cróinín
 MICR20010 Lecture 8

Microbial responses to
unfavourable environments

Dr. Jennifer Mitchell
Microbiology

School of Biomolecular
and Biomedical Science
 Learning Outcomes

Environmental conditions
Temperature
pH
Osmolarity
Oxygen
Spore formation
Bacterial Biofilms
What are ideal growth conditions
for a microbe?

A temperature where all their enzymes are
folded properly and working at the optimum rate

Plenty of food

The correct atmosphere for their own type of
respiration

Available water
Environmental conditions dictate microbial
growth and the distribution and
habitats of microbes

Temperature

pH

Osmolarity (water concentration/availability)

Oxygen
 Effect of temperature on growth

Perhaps the most important environmental factor controlling microbial growth

Too hot or too cold can prevent growth

However different microbes have evolved to growth at very different
temperatures

Cardinal temperatures

Minimum Optimum Maximum
Temperature controls chemical and enzymatic reactions

Above the maximum temperature, enzymes and proteins are denatured

Below the minimum temperature, the cell membrane may no longer function

Cell Membrane is required for nutrient transport and for energy production.

Cell Membrane composition is altered depending on growth media –

Maximum and minimum temperatures supporting growth are
different in rich media versus minimal media
 Growth at cold temperatures
Organisms adapted for growth at cold temperatures do better when the
temperature is constant e.g. deep ocean (approx 2oC, arctic/antarctic
waters.

Environments with high summer temperatures and cold winter
temperatures are less suited to growth.

Psychrophiles have an optimal growth temperature of 15oC or lower

Found in environments that are constantly cold and rapidly die at room
temperature – difficult to isolate and grow in laboratory

Enzymes in psychrophiles are denatured/inactivated at even moderate
temperature

Cold-active enzymes are structurally different to normal enzymes

Membrane structure is different in psychrophiles – allows normal nutrient
transport at cold temps.
 Frozen but not dead
Liquid water is required for microbial growth

Freezing prevents microbial growth but does not always cause cell death

Effects of freezing:

1. Dehydration
2. Ice crystal formation

Water-miscible liquids (e.g. glycerol, DMSO – liquids which mix well with
water) at a low concentration (10%) are protective:

These penetrate the cell and reduce the severity of the effects if freezing

Routinely used for storing bacterial cultures at -20oC and -80oC.

Can occur to varying degrees in natural environments
 Growth at high temperatures
Microbial life flourishes at high temperatures up to and including boiling
point of water

Above 65oC only prokaryotic life (bacteria and archaea) exists

Thermophiles – optimum growth temperature >45oC

Hyperthermophiles – optimum growth temperature >80oC

High temperature environments found in nature are associated with
volcanic phenomena – hot springs, hydrothermal vents in deep oceans

Archaea are more thermophilic than bacteria
Protein/enzyme stability at high temperature
Critical amino acid substitutions facilitate heat stable folding

Membrane stability at high temperature
Alternative membrane composition maintains structure and function

DNA stability at high temperature
Double stranded DNA molecule usually separates at high temperature

In hyperthermophiles, an enzyme called reverse DNA gyrase prevents
this from happening. This enzyme is absent in organisms that grow
below
80oC.

Introduces positive supercoils into DNA, resulting in increased stability
 Bacterial DNA

Gyrase

Heat labile Heat stable
 Effect of pH on growth

pH refers to the concentration of hydrogen ions (H+) in a solution and is
commonly expressed in terms of the pH scale, which is a log scale.

A log scale is used because the large variations in H+ ion concentration in
different solutions.

Low pH corresponds to high hydrogen ion concentration

High pH corresponds to low hydrogen ion concentration.

pH values are calculated as (-) the log of the H+ concentration (- log is used to
get positive values for the pH scale).

pH = -log [H+]
 Most microorganisms grow best at pH 6 – pH 8 (Neutrophiles)

Acidity and alkalinity can greatly affect growth

Acidophiles – acid loving

Alkaliphiles – alkaline loving

Tolerance of extreme pH may depend in part on altered membrane stability

Important:

Internal cell pH must be close to neutral (between pH
5
– pH 9) even if external pH is very acidic or alkaline

At pH extremes – the cell macromolecules (enzymes,
proteins, nucleic acid) are destroyed
How does Helicobacter withstand
Stomach acid?
 Effect of osmolarity on growth

Water is required for growth of all cells – water is the solvent of life

Water availability is dictated not only by how moist or dry an
environment is but is also dependent on the concentration of solutes
(e.g. NaCl or sugar) in the water

Why? Because dissolved solutes have an affinity for water and
make it unavailable to the microbial cell

Osmosis is the diffusion of water from high water concentration (low
solute concentration) to low water concentration (high solute
concentration.

Controlled in cells by the cytoplasmic membrane
 Osmosis
Diffusion of water

Water molecules diffuse easily across the CM
Water molecules associated with other molecules in
solution do not

Dissolved sugar limits
that availability of water
to the cell
In nature, absence of water inhibits life and thus biologically
relevant water availability linked to solute (usually NaCl)
concentration

Halophiles – NaCl loving

Osmophiles – can grow high sugar concentrations

Food preservatives:
Salt and sugar are commonly used as preservatives to inhibit microbial growth
How do microbes grow under conditions of low water availability?

NaCl NaCl NaCl
NaCl H2O
NaCl NaCl NaCl NaCl
NaCl NaCl NaCl
NaCl H 2O
NaCl NaCl
NaCl NaCl Compatible solute H2O NaCl
H2O NaCl
Compatible solute
H2O
NaCl H2O NaCl
NaCl
Cell NaCl Cell
NaCl
NaCl NaCl H2O Compatible solute H2O NaCl
H2O
NaCl NaCl Compatible solute
H 2O
H2 O
NaCl NaCl NaCl
NaCl NaCl
NaCl NaCl NaCl
NaCl NaCl
NaCl H2O NaCl NaCl
NaCl
H2O

Increase in internal solute concentration
High NaCl, low H2O availability
- Increased uptake of H2O
Compatible Solutes
Microbes in high solute, low water environments

Obtain water by increasing intracellular solute concentration

Synthesising or accumulating an organic solute

This solute must be non-toxic to cellular metabolism –
hence called
compatible solute

Compatible solutes are highly water soluble – thus they
“attract” water into cell
 Effect of oxygen on growth
Because most higher animals require oxygen – doesn’t mean the same is true for
microbes

O2 is only weakly water soluble – hence many aquatic habitats are anoxic

Aerobes – grow at full oxygen tensions (air is 21% O2)

Microaerophiles – grow at reduced O2 concentrations (may have oxygen
sensitive enzymes

Anaerobes - cannot use oxygen for respiration – strict and aerotolerant

Facultative anaerobes – can grow in presence or absence of oxygen
Oxygen killing bacteria in neutrophils

ROS
 Bacterial Sporulation

Some Gram-positive bacteria can form Spores which
provide protection from adverse conditions

Spores introduced into a wound site can germinate
and cause infection

Gram-negative bacteria cannot form spores
 Spore Formation

Adverse environmental conditions trigger spore formation.
The spore is surrounded by a peptidoglycan-rich cortex
layer and a keratin-like spore coat.
 Spores are resistant to:

Heat,
Drying,
Radiation,
Freezing,
Toxic chemicals
Antibiotics
&
Can be difficult to eradicate with standard
disinfectants.
The existence of bacterial spores highlights the need for
proper sterilisation - 121oC, 15psi

Spores can persist for hundreds and possibly thousands
of years, before germinating under the right conditions
Although harmless themselves until they germinate, they
are involved in the transmission of some diseases to
humans including:

*anthrax, caused by Bacillus anthracis;

*tetanus, caused by Clostridium tetani;

*botulism, caused by Clostridium botulinum; and

*gas gangrene, caused by Clostridium perfringens
 B. anthracis - Anthrax
Spores persist in soil - animals and animal products
are usual source of human infection
Woolsorters were often infected - woolsorters’
disease
Disease:
Treatment:
High fever, bacteraemia
Penicillin, ciprofloxacin
Massive swelling (oedema)
Systemic affects
Death

Anthrax endospores as
bioterrorism agents ?
Bacterial Biofilms
In all natural environments, microbes grow in complex
communities called biofilms.

Biofilms offer safety in numbers and provide increased
resistance to adverse environmental conditions

The majority of bacterial infections treated by clinicians
involve biofilms

Pseudomonas aeruginasa infections in cystic fibrosis
patients

Staphylococcus epidermidis catheter related infections
Coagulase-negative staphylococci form biofilms or
slime on implanted biomaterials and catheters
Biofilms form when bacteria adhere to
surfaces and excrete
slimy glue-like substances
which anchor the cells
 Why are biofilm infections
difficult to treat?

Antibiotic Doses
1 1000

Planktonic Biofilm
cells cells
 Further Reading

Brock Biology of Microorganisms
Chapter 6 “Microbial Growth”
 MICR20010

Agricultural Microbiology

Dr. Tadhg Ó Cróinín
 Praccal MCQ Exam
Praccal Online MCQ exam is on this Friday Nov
22nd from 2-3pm

Please try the sample quesons under quiz tab in
brightspace and note instrucons in e-mail to
follow. Separate e-mail for DSS students.

Sample MCQ quesons for *nal exam in RDS also
available on Brightspace.
 MICR20010 - remaining lectures
Lecture 10 – Microorganisms and Disease
Lecture 11 – The Immune System
Lecture 12 - Pathogenic Bacteria
Lecture 13 – Pathogenic Fungi and Viruses
Lecture 14 – Anbioc Resistant Microorganisms
Lecture 15 – Microbiology in the Food Industry – The
Fungi
Lecture 16 – Microbiology in the Food Industry -
Fermentaons
Lecture 17 – The Nitrogen Cycle
Single cell protein
+
Microbial
Biomass
 Single Cell Protein
Began in WW2 to produce protein cheaply - S.
cerevisiae and Candida ulis.
Rapid development in 1960s and 1970s with
emergence of phrase SCP.
Most used as animal feed rather than human
consumpon
Producon of yeast from whey or Quorn
producon
Protein
increase in global population…search for alternative
protein source
Single cell protein (SCP)
– SCP= microbial cells grown and harvested for
animal/ human food

WHY SCP? Choice of m/os due to
rapid growth
high protein content
use cheap organic substrates to grow
Protein production by cattle + yeast
bullock.. Wt 500Kg..yields 0.4kg protein/24h
Yeast.. Wt 500kg..yields> 50,000kg/24h
The Fermentor
Applicaons for Yeast in the Food Industry
 Producon of Yeast Biomass
Key to high yield is aeraon – avoid
fermentaon
Cheap media –historically media from cereal
grains, now predominantly molasses.
Gradual scale up of culture from bench-top to
fermentor!
Special feeding regime to avoid fermentaon
(fed batch)
 Producon of Yeast Biomass
Ripening stage to encourage producon of
trehalose and reduce protein producon

Centrifugal separators before washing, drying
and packing

Maximising Biomass is the key aim
Yeast Producon
 What makes a good Bakers Yeast?
High growth rates
Good storage characteriscs including
cryotolerance
Osmotolerance – to funcon within dough
Rapid ulizaon of maltose – main sugar of
dough
High Glycolyc acvity and “gassing power”
SCP-can be produced from
– Algae..spirulina
– fungi…
– bacteria

Biomass can be produced by
– submerged fermentation
– solid state fermentation
– After fermentation: biomass is harvested, washed,
disrupted, and protein extracted
Substrates for micro-organism production:
Algae: use CO2 + sunlight
Fungi: cheap wastes supply C + N source
Bacteria: wastes or by-products of industrial processes
Substrates for micro-organism production:
molasses from sugar manufacture/ starch hydrolysis
spent sulphite liquor
acid hydrolysates of wood
Agricultural wastes
methane
methanol +ethanol
gas oil
Nutritive value of micro-organism
Algae:
rich in proteins, fats + vitamins A,B,C,D +E
40-60% protein
7% mineral

Fungi:
B-complex group of vit.
aa content of A.niger: well balanced
Yeast: have thiamine, riboflavin, biotin

Bacterial SCP:
high in protein + certain essential aa
methionine: 2.2-3% > algal (1.4-2.6%) and fungi (2.5-1.8%)
SCP: limitations for use
Algal SCP
cell wall- cellulytic component cannot be digested by humans..walls must be pre-digested (not for cattle feed)
production is weather dependent

Fungal SCP:
Aspergillus parasiticus, A.flavous:.. Mycotoxins

Bacterial SCP
use is limited to cost
harvesting can be expensive
bacterial cells have high nucleic acid content (uric acid
accumulates in body..kidney stones + gout)
SCP in solving protein malnutrition
source of human + animal feeds
m/o’s accepted for human consumption:
– Saccharmyces cerevisiae
– Candida utilis
– Chlorella spp.
SCP example: Quorn myco-protein

Fusarium graminearum Schwabe A3/5-used in UK
Quorn myco-protein for humans
meat alternative:
– taste,textures of meat products (vegi alternative)

myco-protein:
cells grown on glucose
harvested
High nutritional value
once produced it is mixed with a binder to give desired shape +
flavour
 Indirect
Fermentations

M/O in food production

direct
direct Mushrooms
Single cell protein
Mushrooms
Mushrooms:
Filamentous fungi that form fruiting bodies known as
mushrooms

~12,000 fungal species (~2000 have some edibility)
– Agaricus bisporus (button mushroom)
– Lentinus edodes
– Pleurotus spp (oyster mushroom)
 Mushrooms
A long tradion of use of mushrooms as a food
source (or narcoc)

Very cheap to produce and can readily be grown on
plant waste

Excellent source of protein

Easy to harvest the fruing bodies
Agaricus Bisporis
 Mushroom producon
Preparaon of inoculum in liquid culture
Preparaon of beds - composng
Inoculaon into compost and mycelial growth at
25oC for 2-3 weeks
Applicaon of casing of peat (covering layer)
Fruing body producon in about four Fushes
(successive crops) over a period of 4-6 weeks.
Lennus edulus
Other benefits of mushrooms: Medicinal mushrooms

Extracts of species from genera:
Auricularia
Flammulina,
Ganoderma,
Hericium
And more

Employed medicinally
In medicine:

Immunomodulators
– Some have anti-cancer action

Source of rare minerals and amino acids
– Copper, zinc, selenium, iron.
Problems of fungi:
Mycotoxins
Mycotoxins secondary metabolite of fungi:
– mycotoxicoses in animals + humans
– some linked with certain types of cancer
– present in mycelium and in some cases in the
spores of filamentous fungi
– not all are harmful

In human food chain problems with
– Aspergillus, Penicillium: contaminate foods during
drying and storage
– Fusarium: plant pathogen- produces mycotoxin
before/ immediately after harvesting
Alflatoxins: first discovered in 1960
– 100,000 turkey poults died suddenly in England
– 14,000 ducklings
– 9 out breaks in calves
– common factor: Brazilian peanut meal in animal
feed.

Produced mainly by: Aspergillus flavus, A.parasiticus
Alflatoxins:
4 main alflatoxins: B1,B2,G1, G2 (&M1)

difuranocoumarin derivatives-B &G = Blue (B) &
green (G) fluorescent colours produced under UV
light

Aflatoxins found in:
maize, animal products, peanuts.
 M1= hydroxylated derivative of B1
M2=.... of B2
– M1 & 2
– formed + excreted in milk of lactating animals
– less toxic than B1 or 2
– BUT M1= toxic & carcinogenic
Next Monday on MICR20010

Microbiology in the Food
Industry – Alcohol, Dairy
Industry and Vinegar

Remember Online Praccal
MCQ exam on Friday at 2pm!
MICR20010 Lecture 7

Bacterial Genecs

Dr. Jennifer Mitchell
Microbiology

School of Biomolecular and Biomedical Science
 Lecture 6
Metabolic diversity
Chemical basis of energy producon
Simpli&ed model of energy producon
Energy storage and release
Chemotrophs
Phototrophs
Chemotrophs
– Chemoorganotrophs
– Chemolithotrophs
Autotrophs
Heterotrophs
Photosynthesis
Learning Outcomes

DNA
DNA replicaon
Gene structure
– Transcripon
Protein synthesis
– Translaon
Anbiocs
The Genec Code
Mutaon
Genec Exchange
 DNA

Deoxyribonucleic Acid (DNA)
Monomer building blocks called
deoxyribonucleodes:
– 5-carbon sugar deoxyribose
– a nitrogenous base
– a phosphate group

5

4 1

3 2
 Bases

There are four nitrogenous bases found in DNA
– Adenine (A)

– Guanine (G)

– Cytosine (C)

– Thymine (T)
DNA strand
 DNA

DNA consists of two complementary strands
(double stranded)
Complementary base pairing

A=T

G≡C

G≡C
 DNA Replica#on

The process of generang an idencal set of
genes during cell division
Very accurate process carried out by DNA
polymerases
Occasional inaccuracies give rise to a slightly
altered nucleode sequence – a mutaon
 DNA Replica#on

Iniaon
Elongaon
Proofreading
Terminaon
 DNA Polymerase
DNA polymerase can add free
nucleodes to only the 3'
end of the newly-forming
strand.

This results in elongaon of the
new strand in a 5'-3' direcon.

No known DNA polymerase is
able to begin a new chain
(de novo).

DNA polymerase can add a
nucleode onto only a
preexisng 3'-OH group
DNA strand
Gene#c Code
DNA contains the genec informaon
(genes) required for all cellular processes
Genes can occur individually or in groups
(operons)

Gene Expression:

Transcripon
Iniated at the promoter region
upstream
of the gene
RNA polymerase copies the DNA and
produces an RNA transcript (mRNA)
Translaon
mRNA is decoded by ribosomes and
tRNA
molecules to specify
the exact sequence of amino acids in a
Gene Structure
Protein Expression
 The Gene#c Code

Codon
A set of three adjacent
nucleodes that encode a
parcular amino acid.
Specifying the type and
sequence of amino acids for
protein synthesis.
 An#bio#cs and DNA/RNA/Protein

Some anbiocs target DNA replicaon,
transcripon and translaon
Rifampicin a=ects RNA polymerase
Macrolides (erythromycin), Kanamycin,
Tetracycline a=ect ribosome & protein synthesis
Mutaons in the anbioc target can lead to
bacterial resistance
Ciprofoxacin

Ciprofoxacin targets DNA gyrase, the enzyme
which unwinds bacterial DNA during
replicaon.
Ciprofoxacin prevents cell division
Quinolone anbioc
Plasmids

Circular extrachromosomal DNA
Replicate independently and can move between
cells
Phenotypic advantage for the host cell
Plasmid genes:
– Anbioc resistance genes (oBen mulple)
– Virulence genes (e.g. toxins)
– Metabolic genes
Hospital-acquired Infec#ons

Plasmids with mulple anbioc resistance genes
predominate within hospital bacteria
Infecons caused by such bacteria (nosocomial or
hospital-acquired infecons) are therefore
parcularly serious and diCcult to treat.
Anbioc resistance genes existed before the era
of anbioc treatment but have become
prevalent due to selecve pressure.
Highlights bacterial adaptability.
Transmission of AMR genes between species
Muta#on

Most common source of genec variaon
Spontaneous or induced (mutagens)
Three types
– Substuon
– Deleon
– Inseron
Codons - Muta#on
 Gene#c Varia#on

Important implicaons for microbial virulence:
Resistance to anbiocs
New virulence factors (e.g. E. coli 0157)
 Mutagenesis

Mutagens
Physical - Radiaon
Chemical mutagenesis
– Base analogues
– Intercalang agents
– Metals - ROS
Biological agents
– Virus
– Transposon
Gene#c Exchange

Modes of Genec
Transfer between
Bacterial Cells
 Transforma#on

DNA fragments can be taken up
directly by bacterial cells
Normally degraded
Somemes integrated into host
genome
Some bacteria are naturally
competent e.g. Streptococcus
pneumoniae
 Conjuga#on

Describes plasmid transfer between bacterial cells
Requires cell-to-cell contact & can occur between di=erent
bacterial species and even between G+ve and G-ve
tra genes encode pilus (channel) between the cells through
which the plasmid moves
Plasmids replicate in the donor cell prior to transfer into
the recipient cell
 Transduc#on

DNA transfer between bacteria
via infecon with a
bacteriophage
Phage infect the bacterial cell
and replicate
Involves incorporaon of phage
DNA into phage capsids (heads)
Occasionally host genomic DNA
is also packaged
 Transposi#on

Transposons are DNA sequences that can ‘jump’ within the bacterial
genome and from the genome to plasmids within the same cell
Transposons carry the enzymes required for their own transposion
(homology not needed). This can result in gene disrupon
Transposons oBen contain anbioc resistance genes
Transposion into broad host range plasmids has facilitated rapid
disseminaon of anbioc resistance genes among di=erent bacterial
species
 Genec Variaon and Anbioc
Resistance
Mutaon
– (e.g. drug resistance in tuberculosis)

Transformaon/transposion
– (e.g. Penicillin-resistant gonorrhea)

Conjugaon
– (e.g. mul-resistant shigella)
 Further Reading

Brock Biology of Microorganisms
Chapter 10 “Bacterial Genecs”
 MICR20010

Agricultural Microbiology

Dr. Tadhg Ó Cróinín
 MICR20010 – Assessments
Remember to get your prac#cal reports submi$ed
on #me, watch plagiarism. (15%)

Prac#cal online MCQ exam on 2-3pm Friday Nov
22nd (15%) Sample MCQs to appear next week.

Final MCQ exam in RDS on 12th December 9.30 –
Con6rm on exam #metable (70%) Sample MCQs
to appear next week.
 MICR20010 - remaining lectures
Lecture 10 – Microorganisms and Disease
Lecture 11 – The Immune System
Lecture 12 - Pathogenic Bacteria
Lecture 13 – Pathogenic Fungi and Viruses
Lecture 14 – An#bio#c Resistant Microorganisms
Lecture 15 – Microbiology in the Food Industry – The
Fungi
Lecture 16 – Microbiology in the Food Industry -
Fermenta#ons
Lecture 17 – The Nitrogen Cycle
Commercial as well as Health
Implicaons!
Transmission of Disease

Figure 14.6a, d
 Vehicle Transmission
Transmission by an inanimate reservoir
(food, water, air)

Figure 14.7b
Vectors

Figures 14.8, 12.30
 Nosocomial Infec#ons

Are acquired as a result of a hospital stay
A?ect 5–15% of all hospital pa#ents

Figure 14.6b
 Mechanisms of Pathogenicity

Pathogenicity: The ability to cause disease
Virulence: The extent of pathogenicity
Mechanisms of Pathogenicity

Figure 15.9
 Infec#on and Adherence
Adhesins/ligands bind to receptors on host cells
– Fimbriae: Escherichia coli
– M protein: Streptococcus pyogenes

Form biolms
Adherence

Figure 15.1
 Penetra#on into the Host Cell Cytoskeleton
Invasins
Salmonella
alters host ac#n to enter
a host cell

Listeria
Uses ac#n to move from
one cell to the next

Figure 15.2
 Direct Damage by bacteria
Disrupt host cell func#on
Produce waste products
Toxins
– Toxin: Substance that contributes to pathogenicity
– Toxigenicity: Ability to produce a toxin
– Toxemia: Presence of toxin in the host's blood

Figure 15.4
Exotoxin type
A-B toxin, Membrane disrup#ng toxin, Superan#gens

Exotoxin

Corynebacterium A-B toxin
diphtheriae

Membrane-disrupting
Streptococcus pyogenes
erythrogenic toxin

Clostridium botulinum A-B toxin; neurotoxin

C. tetani A-B toxin; neurotoxin

Vibrio cholerae A-B toxin; enterotoxin

Staphylococcus aureus Superantigen
 Endotoxins

Source Gram
Relation to Microbe Outer membrane
Chemistry Lipid A
Fever? Yes
Neutralized by Antitoxin? No
LD50 Relatively large

Figure 15.4b
The Stages of a Disease

Figure 14.5
Bacterial Diseases

Chronic vs Acute
 Pseudomonas and the Pseudomonads
Colony morphology
Rods or curved rods
with polar Eagellae
Burkholderia,
Pseudomonas etc.
A par#cular challenge
for those with Cys#c
Fibrosis
The Human Lung
 Developing Chronic Infec#on

Intermi$ent coloniza#on 6rst
Followed by a persistent chronic infec#on
Accompanied by a higher degree of
InEamma#on.
 B. Pertussis – An acute Infec#on
Also a gram-ve rod shaped
organism.
Thus a similar cell envelope
to that of P. aeruginosa.
Also infects the lungs but
this #me not opportunis#c…
Highly contagious due to
coughing spasms.
Uses an array of virulence
factors to cause disease.
Whooping Cough
 What is Happening
The bacterial infec#on is a?ec#ng the ability
of the lungs to clear mucus.

An inability of the cilia to clear the mucus
sends the host into a 6t of coughing.

This in itself allows the bacteria to be spread
rapidly by aerosol.
Huge array of virulence factors!
 The Symptoms
Paroxysmal cough, inspiratory “whoop”

Rib fractures, hernias, loss of conciousness

Infec#on in newborns can be par#cularly severe and
result in death in approx 1%

7-10 days incuba#on period followed by catarrhal
stage, then two weeks later uncontrollable 6ts set in.
 Treatment/Preven#on?
Vaccina#on with
pertussis toxin rela#vely
successful.

An e?ec#ve vaccine…
but…..

Uptake of vaccine
cri#cal.
 H. pylori– Commensal or Pathogen?
Also a gram-ve organism
but this #me spiral shaped
Thus a similar cell envelope
to that of the other Gram-
nega#ve organisms.
Only known to reside in the
human
stomach/duodenum.
Gastri#s in most individuals
More serious disease in
others….
 A Brief History
Discovered in 1982
Before this stomach
thought to be sterile
Ulcers thought to be
stress related.
A paradigm shiQ in
the treatment of
gastric disease.
 Pathology of Infec#on
The only known bacteria to colonize the
human gastric mucosa.
Gastri#s induced in all individuals colonized
but typically asymptoma#c.
Some can develop into more serious disease
such as
– Duodenal Ulcers, MALT Lymphoma, Gastric Cancer
A class 1 carcinogen?
Disease Progression
 Chlamydia – An intracellular pathogen

15-25 are most at risk.

Steady rise in Chlamydia cases
Phylum 5 - Chlamydia
 Phylum 5 : Chlamydia
Organisms are obligate parasites
– C. trachomas - STD and trachoma
– C. psiaci – Psi$acosis
– C. pneumoniae – Respiratory syndromes

Clearly limited metabolic pathways
Lack of some genes (QsZ)
Presence of some eukaryo#c-like genes
 Life Cycle of Chlamydia
Elementary and
Ri#culate bodies

Thus a more complex
life cycle.

Key is the obligate
intracellular life cycle.
 Di?erent Niches – Di?erent Outcomes
The male and female
reproduc#ve organs contain
very di?erent
environments.
Also di?erent epithelial
surface cell molecules.
This has a big e?ect on the
progression of disease.
Can cause permanent
damage to fallopian tubes
and sterility in women
 Bacterial Diseases of the Eye
Chlamydia trachomas
– Causes trachoma

– Leading cause of blindness worldwide
– Infec#on causes permanent scarring; scars abrade the
cornea leading to blindness
 Anthrax
Bacillus anthracis
Endospores enter through minor cut
– 20% mortality

Gastrointesnal anthrax
– Inges#on of undercooked, contaminated food
– 50% mortality
Inhalaonal (pulmonary) anthrax
– Inhala#on of endospores
– 100% mortality
 Biological Weapons
1346: Plague-ridden bodies used by Tartar army against
Ka?a
1937: Plague-carrying Eea bombs used in the Sino-
Japanese War
1979: Explosion of B. anthracis weapons plant in the
Soviet Union
1984: S. enterica used against the people of The Dalles
1996: S. dysenteriae used to contaminate food
2001: B. anthracis distributed in the United States
 Biological Weapons
Bacteria Viruses
“Eradicated” polio and
Bacillus anthracis
measles
Brucella spp. Encephalitis viruses
Chlamydophila psittaci Hermorrhagic fever viruses
Clostridium botulinum toxin Influenza A (1918 strain)
Coxiella burnetii Monkeypox
Francisella tularensis Nipah virus
Rickettsia prowazekii Smallpox
Shigella spp. Yellow fever
Vibrio cholerae
Yersinia pestis
 Typhoid Fever
Salmonella typhi
Bacteria spread throughout body in phagocytes
1–3% of recovered pa#ents become chronic
carriers
200,000 deaths/yr
The
Importance of
asymptomac
Infecon
 Next on MICR20010

Pathogenic Fungi and Viruses

Dr. Tadhg Ó Cróinín
 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
Metabolic diversity
Chemical basis of energy produc*on
Simpli+ed model of energy produc*on
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
ac*vi*es

Di/erent microorganisms have evolved every conceivable
means of obtaining carbon and energy

This results in signi+cant metabolic diversity

Hence microbes have been able to colonise environmental
habitats which are too extreme for other
life forms.
h2ps://www.teagasc.ie/news--events/daily/other/the-soil-microbiome-and-soil-health.php
 Chemical Basis of Energy Producon
1. Chemical reac*ons used to generate energy

2. Speci+cally chemical reac*ons 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. Oxida*on: atom or molecule loses one or more electrons
5. Reduc*on: 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
Oxida*on Is Loss of electrons
Reduc*on Is Gain of electrons
 Simpli!ed Model of Energy Producon

Light

e- e-
ATP
oxidised
Iron Enzymes e- e-
e-
e-
idised s
ox yme
Glucose Enz

Example of simple oxida*on reac*on:
Fe2+ ⇋ Fe3+ + e-
Ferrous iron Ferric iron
 ENERGY
Energy Storage:

Used to trap energy released from
chemical reac*ons
Energy stored as high-energy
phosphate bond
Inorganic phosphate group
a2ached to adenosine diphosphate
(ADP)
Adenosine triphosphate (ATP)
The energy currency of the cell

Energy Release:

Phosphate enzyma*cally 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 di/erent organic chemicals present on
Earth
ALL can be broken down by microorganisms to
derive energy
 How do chemoorganotrophs derive energy from
organic chemicals?

Answer:
Oxida*on of the compound releases electrons, which are
ul*mately used to generate ATP.
Electrons have stored energy and when an atom or molecule
loses that electron (becomes oxidized) that energy is released

Oxida*on: atom or molecule loses one or more electrons
Reduc*on: 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

Facultave anaerobes
Microbes that produce energy in the presence or
absence of oxygen
 Methanogens
Livestock produce signicant 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, bu alo, 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.
h2ps://www.agric.wa.gov.au/climate-change/carbon-farming-reducing-methane-
emissions-ca2le-using-feed-addi*ves#:~:text=Feed%20addi*ves%20or%20supplements%20can
 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 e ective 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.
 Ac*ve inhibitors
trihalomethanes, such as bromoform,
which is an active ingredient that
decreases methane emissions

Tannins
 Bene+ts:
The reduced volume of methane
formation may lead to better
e)ciency 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 Source of energy and electrons Respiraon electron acceptor

Iron bacteria Acidithiobacillus ferrooxidans Fe2+ (ferrous) → Fe3+ (ferric) + e- O2 → H2O

Nitrosifying bacteria Nitrosomonas NH3 (ammonia) → NO2- (nitrite) + e- O2 → H2O

Nitrifying bacteria Nitrobacter NO2- (nitrite) → NO3- (nitrate) + e- O2 → H2O

Chemotrophic purple sulfur S2 (sul+de) → S0 (sulfur) + e- O2 → H2O
bacteria Halothiobacillaceae

Sulfur-oxidizing bacteria Chemotrophic S0 (sulfur) → Sulfate (SO2−4) + e- O2 → H2O
Rhodobacteraceae

Aerobic hydrogen bacteria Cupriavidus metallidurans H2 (hydrogen) → H2O (water) + e- O2 → H2O

Thiobacillus denitri+cans Thiobacillus denitri+cans S0 (sulfur) → Sulfate (SO2−4) + e- NO3- (nitrate)

Sulfate-reducing bacteria: H2 (hydrogen) → H2O (water) + e- Sulfate (SO2−4)
Hydrogen bacteria

Sulfate-reducing bacteria: Desulfo*gnum PO3−3 (phosphite) → PO3−4
Sulfate (SO2−4)
Phosphite bacteria phosphitoxidans (phosphate) + e-

Methanogens Archaea H2 → H2O + e- CO2 (carbon dioxide)

Carboxydothermus carbon monoxide (CO) → carbon
Carboxydotrophic bacteria dioxide (CO2) + e- H2O (water) → H2 (hydrogen)
hydrogenoformans
 Chemolithotrophs
Chemolithotrophs obtain carbon from CO2 –
autotrophy

Ecological niche and compe**on

Lithotrophy is advantageous because organisms
deriving energy from inorganic compounds do not
have to compete with chemoorganotrophs.

In addi*on some of their energy sources (H2, 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 +xa*on or Calvin cycle
 Autotrophs
Autotrophs are called primary producers because
they produce organic ma2er from CO2 in the air.
Chemoorganotrophs and other organisms can
ul*mately use this organic ma2er by feeding on the
autotrophs or their waste products
All organic ma2er 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 reac*ons 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 photoprotec*ve role
Photosynthec Bacteria
 Further Reading

Brock Biology of Microorganisms
Chapter 5 “Nutri*on, Laboratory Culture and
Metabolism of Microorganisms”
 MICR20010

Agricultural Microbiology

Dr. Tadhg Ó Cróinín
 MICR20010 - remaining lectures
Lecture 10 – Microorganisms and Disease
Lecture 11 – The Immune System
Lecture 12 - Pathogenic Bacteria
Lecture 13 – Pathogenic Fungi and Viruses
Lecture 14 – An+bio+c Resistant Microorganisms
Lecture 15 – Microbiology in the Food Industry – The
Fungi
Lecture 16 – Microbiology in the Food Industry -
Fermenta+ons
Lecture 17 – The Nitrogen Cycle
Immune System vs Pathogens
 Immunity Concepts

Suscepbility: Lack of resistance to a disease

Immunity: Ability to ward o5 disease

Innate immunity: Defenses against any pathogen

Adapve immunity: Immunity, resistance to a speci8c
pathogen
 Pathogens, agents that cause disease, infect a wide range
of animals, including humans
The immune system recognizes foreign bodies and
responds with the produc+on of immune cells and
proteins
– All animals have innate immunity, a defense ac+ve immediately
upon infec+on
– Skin
– Chemical secre+ons that trap/kill microbe
Vertebrates also have adapve immunity/ acquired
immunity
Innate immunity is present before any exposure to
pathogens and is e5ec+ve from the +me of birth

It involves nonspeci8c responses to pathogens
Innate immunity consists of external barriers plus
internal cellular and chemical defenses

Microbiology an introducon
Skin Mucus membranes trap bacteria and move it away from lungs
Adapve immunity, or acquired immunity, develops
a=er exposure to agents such as microbes, toxins, or
other foreign substances
It involves a very speci8c response to pathogens
 Immune system: Microbes and Defenses

The immune system recognizes bacteria and fungi
by structures on their cell walls
Pathogens entering the mammalian body are
subject to phagocytosis
– Phagocy+c cells recognize groups of pathogens
by TLRs, Toll-like receptors
 Formed Elements in Blood

Red Blood Cells Transport O2 and CO2
(Corpuscles)

White Blood Cells:
Neutrophils Phagocytosis

Eosinophils Kill parasites

Microbiology an introducon
 Formed Elements in Blood

Monocytes Phagocytosis

Dendri+c cells Phagocytosis

Natural killer cells Destroy target cells

Microbiology an introducon
 Formed Elements in Blood

T cells Cell-mediated immunity

B cells Produce an+bodies

Platelets Blood cloBng

Microbiology an introducon
A white blood cell engulfs a microbe,
Phagocytosis
There are di5erent types of phagocy+c cells
– Neutrophils engulf and destroy pathogens
– Macrophages are found throughout the body
– Dendric cells s+mulate development of
adap+ve immunity
– Eosinophils discharge destruc+ve enzymes

Neutrophils
 Figure 43.3

Pathogen
Phagocytosis.

PHAGOCYTIC
Phago: From Greek, meaning CELL
eat
Cyte: From Greek, meaning
cell Vacuole
Lysosome
containing
enzymes
Extracellular killing by leukocytes
Eosinophiles… natural killer cells
Neutrophils… can carry out extracellular killing

Natural killer lymphocytes (NK cells)
Secret toxin onto surface of viral infected cells
But can distinguish normal from infected cells
via membrane proteins
 2nd line of defence
Neutrophils… can carry out extracellular killing..ways

Have enzymes that generate O2- and H2O2…
converted to hypochlorite
Produce nitric oxide.. Inflammation inducer
Can make NETS (neutrophil extracellular traps)..
Kill via immobilisation
 Bacterial Rod entrapped

Budding yeast entraped in NETS
Urban et al., Cellular microbiology (2006), 8, 1687.
 Figure 43.8-1

Pathogen Splinter

Macro-
Signaling
Mast molecules phage
cell
Capillary

Red Neutrophil
blood cells
 Figure 43.8-2

Pathogen Splinter

Macro- Movement
Signaling
phage of fluid
Mast molecules
cell
Capillary

Red Neutrophil
blood cells
 Figure 43.8-3

Pathogen Splinter

Macro- Movement
Signaling
phage of fluid
Mast molecules
cell
Capillary Phagocytosis

Red Neutrophil
blood cells
 Adapve immunity
receptors provide pathogen-speci8c recogni+on

The adap+ve response heavily relies on two types of
lymphocytes, or white blood cells

Lymphocytes that mature in the thymus above the
heart are called T cells, and those that mature in
bone marrow are called B cells

Angens elicit a response from a B or T cell
 Angens are substances that can elicit a response
from a B or T cell
Exposure to the pathogen ac+vates B and T cells
with angen receptors speci8c for parts of that
pathogen
The small accessible part of an an+gen that binds to
an an+gen receptor is called an epitope

Antigen
receptors

Mature B cell Mature T cell
 Binding of a B cell an+gen receptor to an an+gen
– an early step in B cell ac+va+on

This gives rise to cells that secrete a soluble form of the
protein called an anbody or immunoglobulin (Ig)

Secreted an+bodies are similar to B cell receptors
– but lack transmembrane regions that anchor receptors in the
plasma membrane
 Anbody Funcon
An+bodies do not kill pathogens; instead they mark pathogens for
destruc+on and/or phagocytosis - Opsonisa+on

In neutralizaon, an+bodies bind to viral surface proteins
preven+ng infec+on of a host cell

An+bodies may bind to toxins in body Euids and prevent them
entering cells

Figure 43.10a
 B cells can express 8ve di5erent forms (or classes)
of immunoglobulin (Ig) with similar an+gen-binding
speci8city but di5erent heavy chain C regions

– IgD: Membrane bound
– IgM: First soluble class produced
– IgG: Second soluble class; most abundant
– IgA and IgE: Remaining soluble classes
 Acve and Passive Immunizaon
Acve immunity develops naturally when memory
cells form clones in response to an infec+on, Passive
is when an+bodies are directly donated.
It can also develop following immunizaon, also
called vaccinaon
In immuniza+on, a nonpathogenic form of a
microbe or part of a microbe elicits an immune
response to an immunological memory
Figure 19.9
humans from pigs;
“swine :u”

1 m
(a) 2009 pandemic H1N1 (b) 2009 pandemic
influenza A virus screening

Killed 40 million, 1918

(c) 1918 flu pandemic
 Vaccines are harmless deriva+ves of pathogenic
microbes that s+mulate the immune system to mount
defenses against the harmful pathogen

Vaccines can prevent certain viral illnesses
Measles in the United States, 1960–2007

Microbiology an introduc+on Clinical Focus, p. 505
Vaccine hesitancy and e5ec+veness
A recent challenge
A brief History
Success?…
Next on MICR20010

Pathogenic Bacteria

Dr. Tadhg Ó Cróinín
 MICR20010 Lecture 5

Growth and Physiology

Dr. Jennifer Mitchell
Microbiology

School of Biomolecular and Biomedical Science
 Lecture 5
Prokaryo&c cell morphology
Bacterial cell structure
The gram stain
– Gram stain mechanism
Bacterial shapes
– Di)erent morphological shapes
Bacterial cell structure – G+ve G-ve Archaea
– Cell membrane
– Cell wall
– Outer membrane
– Cell appendages
 Learning Outcomes
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
Microbial growth and physiology
In the laboratory

Liquid broths and Nutrient Agar plates
 GROWTH OF BACTERIA:

ASEPTIC TECHNIQUE
STERILE GROWTH MEDIA
BOIL
– KILL ALL CELLS 100⁰C / 30 MIN
AUTOCLAVE
– KILL ALL CELLS & SPORES 120 ⁰ C / 30 MIN
DRY HEAT
– 150 ⁰ C / 120 MIN
 Bacteria divide by Binary Fission

Binary Fission

Chromosome divides to produce two iden&cal copies

These copies segregate to opposite ends of the cell

Cell wall is laid down the middle of the cell to
ul&mately produce two new cells which are iden&cal
Binary Fission
 Bacterial growth is Exponen'al
1->2->4->8->16->32->64->128->256->512 etc
Bacterial growth proceeds exponen&ally
Genera&on &mes (&me for bacterial mass to double)
can be as fast as 20 minutes
Contributes to the remarkable adaptability of
bacteria
Growth in a hos&le environment can create a
selec&ve pressure for mutant cells which can persist.
One mutant cell which can survive will rapidly grow
and take over.
GROWTH OF BACTERIA ON SOLID MEDIUM

AGAR: MELTS AT 100⁰C, SOLIDIFIES AT 40⁰C
STERILIZED BY AUTOCLAVING
BACTERIA GROW AS COLONIES
SINGLE COLONY PURIFICATION
GROWTH IN LIQUID MEDIUM

COTTON WOOL BUNG
GAS EXCHANGE
KEEP CONTENTS STERILE
INCUBATE STANDING OR AGITATED
TURBID CULTURE
~ 109 CELLS/ML
Growth Phases of a Bacterial Culture

1. Lag Phase
– Adapta&on
2. Logarithmic Phase
– Cells mul&ply at the maximum rate
3. Sta&onary Phase
– Lack of nutrients and build up of toxic metabolic
intermediates means mul&plica&on is balanced by cell
death
4. Phase of decline
 Genera'on Times of Bacteria
Bacterium Medium Genera'on Time (minutes)

Escherichia coli Glucose-salts 17

Bacillus megaterium Sucrose-salts 25

Streptococcus lac&s
Milk 26

Streptococcus lac&s
Lactose broth 48

Staphylococcus aureus Heart infusion broth 27-30

Lactobacillus acidophilus Milk 66-87

Rhizobium japonicum Mannitol-salts-yeast extract 344-461

Mycobacterium tuberculosis Synthe&c 792-932

Treponema pallidum Rabbit testes 1980
 Measurements of bacterial growth

Direct measurements of bacterial growth:
I. Total cell count. Using microscope and coun&ng chamber
II. Total viable count. Cells in culture are diluted and spread
on nutrient agar plates.

Only viable cells will reproduce to give rise to a
colony.
Direct measurements of bacterial growth:

Coun&ng chamber
Direct measurements of bacterial growth:

The area and volume under
each square is known.
Can determine the number
of cells in sample volume.
Total Viable Count

Serial 10-fold dilu&ons
 Total Viable Count:

Spread plate method and pour plate method
Indirect measurements of bacterial growth

Turbidity
(Cloudiness)
Measures live and dead cells
How a spectrophotometer measures turbidity
(cloudiness)
 Chemostat culture

1. Cell density
controlled by nutrient
conc.
2. Growth rate
controlled by Oow rate
of nutrient
 Growth requires

Energy,
The building blocks required for the
construc&on of cellular machinery
Appropriate environmental
condi&ons
 Growth Requirements

Nutrient Requirements
– Water
– Carbon (carbohydrate)
– Nitrogen (protein)
– Inorganic salts Iron -
siderophores
– Oxida&on of organic compounds
– (carbohydrates, lipids, proteins)
Temperature pH Atmosphere
20⁰C- 110 ⁰ C !! 4.0 - 9.0 O₂ / No
O₂
 Energy

Derived from the enzyma&c breakdown of organic
substrates (carbohydrates, lipids or proteins) in a
process called Catabolism

Energy generated from catabolism is used to
synthesise cellular cons&tuents in a process called
Anabolism

Catabolism + Anabolism = Metabolism
Bacterial growth in diverse environments

In addi&on to carbohydrates, lipids and proteins
bacteria can also derive energy from plas&c, rubber
and toxic compounds like phenol.

Important implica&ons for decontamina&on of
environmental pollu&on
Exxon Valdez Oil Spill in Alaska:
Engineered bacteria that “eat” hydrocarbons”
were fer&lised onto beaches contaminated
with oil.
Known as bioremedia&on, this method was
successful on several beaches where
the oil was not too thick.
 Auxotrophs

The ability of individual bacterial species to produce
their own cellular components will dictate its
nutri&onal requirements

E.g. some species can synthesis all essen&al amino
acids whereas others need amino acids to be added
to their growth media (auxotrophs).
 Oxygen

Obligate aerobes – grow only in presence of O2.

Obligate anaerobes – grow only in absence of O2,
killed by O2

Faculta&ve anaerobes – grow in presence & absence
of O2
 Temperature
Psychrophile - cold loving bacteria (10-20⁰C)

Mesophile (20-40 ⁰ C)
– human body temperature
– pathogens
– opportunists

Thermophile - heat loving (>60 ⁰ C)
 pH
Many bacteria grow best at neutral pH

Some can survive/grow
– acid
– alkali
 Extremophiles

Antar&ca

Hot geyser at Yellowstone Na&onal Park
 Further Reading
Brock, Biology of Microorganisms, Madigan,
Mar&nko and Parker 10th Ed.
Chapter 5 “Nutri&on, Laboratory Culture and
Metabolism of Microorganisms”
Chapter 6 “Microbial Growth”
 MICR20010

Agricultural Microbiology

Dr. Tadhg Ó Cróinín
Assessments
Praccal accounts for 30%

15% on the two Praccal reports to be submi#ed online a$er the
praccals. Note these include write ups on praccals as well as online
material.

15% on the Praccal Exam online to be held Friday Nov 22nd 2-3pm.

70% on an end of term MCQ exam in the RDS.
Microbiology
The study of microorganisms.

Bacteria/Viruses which cause
disease

Bacteria which help – anbiocs,
probiocs

Biotech Industry
Why is Microbiology Important?
Industrial Microbiology
Food and Beverage Industry
Health Industry

Environmental Microbiology
Bacteria and their role in the ecosystem
Polluon and Bioremediaon

Clinical Microbiology
Developing vaccines, anbiocs new treatments
Diagnoscs
MICR20010 - remaining lectures
Lecture 10 – Microorganisms and Disease
Lecture 11 – The Immune System
Lecture 12 - Pathogenic Bacteria
Lecture 13 – Pathogenic Fungi and Viruses
Lecture 14 – Anbioc Resistant Microorganisms
Lecture 15 – Microbiology in the Food Industry – The Fungi
Lecture 16 – Microbiology in the Food Industry - Fermentaons
Lecture 17 – The Nitrogen Cycle
Microorganisms and Disease
Microorganisms play a variety of di?erent roles in disease and we
have complex relaonships with these organisms.

Mutualism
Bene@cial associaons – bacteria providing vitamin precursors in gut
Commensalism
Passive associaons – non pathogenic Staphylococci
Parasism
Microorganism causes harm – pathogenic bacteria
Key is understanding the
relationship
How do we prove a pathogen
Koch’s postulates

1. The m/o must be present in the diseased and not in a healthy
animal
2. M/O must be cultivated in pure culture
3. Pure culture inoculated into 2nd animaldisease
4. Pure culture from 2nd animal should be same as 1st.
Koch’s Postulates
What about exceptions?
 Some pathogens difficult to culture.
 Some diseases are caused by combinations of
 Pathogens
 Physical, environmental
 Genetic factors
 Animal models and ethics: inoculation of healthy susceptible
host not always possible (the postulate could never be fully
applied to HIV)
Virulence Factors
A key di?erenal in pathogens is the presence of virulence factors
which help the organisms cause disease.

Evoluon allows these toxins to o$en be host speci@c
Toxins which have very speci@c targets
Adhesins which recognise speci@c receptors

Other less so – Endotoxins (e.g. LPS)
Virulence factors can thus de@ne host speci@city
 Extracellular Enzymes
Secreon of enzymes allows microorganisms to alter their
environment

Avoiding the Immune system–
Some blood borne pathogens have the ability to secrete coagulase which
leads to coagulaon allowing microorganisms to form clots which in turn can
provide a physical hiding place from the immune system.
Leukocidins can be used to destroy white blood cells.
Catalase can be used to protect from reacve oxygen species in the
Macrophage
 Toxins
 Exotoxins
1. Cytotoxins: kills or affects the functions of host
cells

2. Neurotoxins: interferes with nerve cells

3. Enterotoxins: affects cells lining gut tract
(clostridia, pathogenic strains of S.aureus and
E.coli)
Cytotoxins
Neurotoxins

Clostridum botulinum and Clostridium tetanii
secrete extremely potent neurotoxins which lead
to two very di?erent forms of fatal paralysis
Related toxins
Botulinum toxin inhibits the release of
acetylcholine which smulates
contracon therefore leading to
relaxaon

Tetanus toxin inhibits the release of
Glycine which induces relaxaon of a
contracted muscle which thus leads to
contracon.

Tetanus not a food poisoning toxin!
Enterotoxins

Clostridium perfringens
secretes an enterotoxin which
can induce gastroenters on
its own

Inoculaon with the toxin
alone has the same e?ect as
inoculang with the bacteria
Virulence vs Colonization factors
A virulence factor is directly involved in causing disease
Toxins etc

A colonizaon factor may be necessary for disease to progress but is
not directly involved
Adhesins and Jagella for molity

Clostridium perfringens entertoxin (CPE) clearly a virulence factor
Endotoxins
Primarily found in Gram
negave organisms
Key is the constuents of the
Outer membrane

Lipopolysaccharide (LPS)

Released on cell death or
through membrane blebbing
but has dramac e?ect on
Immune system
Anti-phagocytic factors
 Capsules: many are made of chemicals found in body : no
immune responses made

 Anti-phagocytic compounds: some m/o make compounds
that prevent fusion of lysosomes with phagocytic vesicles…
(Neisseria gonorrhea)

 Previously mentioned enzymes such as catalase
Immune Evasion

Phagocytosis blocked by capsule
Surviving phagocytosis
How is disease transmitted
Microorganisms do not simply appear

They can be already present and taking advantage of a change in
environment – Opportunisc pathogens
S. aureus commonly found on skin but pathogenic in blood infecons
C. dicile takes advantage of anbioc treatments changing microbiome

How are organisms transmi#ed - epidemiology
Modes of Transmission

A. Contact transmission
Direct contact-person to person
Indirect contact-needles, toothbrushes
Droplet transmission- spread via droplet nuclei
B. Vehicle transmission
Air, drinking water, food
C. Vector transmission
Biological and mechanical
Basic protections from infection
Skin: barrier…tight layer of packed cells…entrance through cuts

Mucous membranes: that line the body cavities open to the
outside world (nose etc..)

To infect: adherence of parasite to cells to allow for establishment
of colonies
Adaptive immunity
Acquired immunity
Develops from birth, as we encounter various pathogens
Antigens trigger specific response
Components of bacterial cells
Cell walls, capsules
Flagella
Proteins (internal + external)
Toxins
Food may have antigens that provoke allergic reactions
What are Antigens?
Properties of antigens
Antigens recognised by antigenic determinants (epitopes)

>5-100KDa better than smaller antigens
Proteins, glycoproteins etc…

500 different media for growing bacteria – reflects
bacterial diversity
COLONIES OF
BACTERIA
 Inspection

Examination of colonies to determine if culture is pure
– Each colony forms from a single cell – therefore the colony is an
isolated population of an individual bacterial species
The appearance of the colony is useful in identifying the
bacterial species
– Therefore in isolating a bacterial species, it is important that all
the colonies appear the same
Different colony type means that the culture is not pure
or is mixed.
– If culture is contaminated or mixed, a single colony of the
desired species is subcultured

In broth culture, not possible to determine if growth
of more than one bacterial species has occurred.
 Identification
Macroscopic or colony morphology

Microscopic morphology

Biochemical characteristics

Genetic characteristics
 Disposal of cultures
Sterilisation: Removal and destruction of all
microbes in or on an object
Physical Methods:
Heat
- Moist Heat. Boiling water, flowing steam.
- Cells & most viruses. Not spores
(Tyndallisation –intermittent boiling)
– Steam (Autoclaving) 121oC - 15-30min.
All spores/viruses/cells. Media & equipment
- Dry Heat (Hot air), 1 hour at 171oC,
– Incineration (burning) 1 sec or more at 1000oC)
How an autoclave works
 Disposal of cultures

Radiation
– Ionising e.g. X rays, gamma rays, secs-hrs. OH-
radicals, damage to DNA.

– Sterilize pharmaceuticals, medical supplies

– Nonionising e.g. UV light. DNA damage. Operating
theatres, kitchens
 Disinfection
Related process
Reduction in bioload including the removal of
pathogens
Methods
– Chemical
– heat, e.g. pasteurisation
– filtration

Often easier to achieve than sterilisation and
adequate for instruments in contact with mucous
membranes, e.g. endoscopes
Pasteurisation:

Use of heat (e.g. 75°C, 15 seconds) to kill pathogens and
reduce the number of spoilage micro-organisms in food and
beverages (milk, fruit juice, wine, beer).

Balance between removing microbes and affecting taste or
quality of product
 Antiseptics and disinfectants

Antiseptics: microbicidal agents harmless
enough to be applied to the skin and mucous
membrane
– should not be taken internally.

Examples: mercurials, silver nitrate, iodine
solution, alcohols, detergents.
 Antiseptics and disinfectants

Disinfectants: Agents that kill microorganisms,
but not necessarily their spores, not safe for
application to living tissues; they are used on
inanimate objects such as tables, floors,
utensils, etc.

Examples: chlorine, hypochlorites, chlorine
compounds, copper sulfate, quaternary
ammonium compounds.
 Antiseptics and disinfectants

Note: disinfectants and antiseptics are
distinguished on the basis of whether they are
safe for application to mucous membranes.
Often, safety depends on the concentration of
the compound. For example, sodium
hypochlorite (chlorine), as added to water is safe
for drinking, but "chlorox" (5% hypochlorite), an
excellent disinfectant, is hardly safe to drink.
 Appropriate
handwashing
facilities

Antiseptic hand
wash
 Further Reading
Microbiology an Introduction, Tortora,
Funke and Case 12th Ed.
Chapter 6 “Microbial Growth”
Chapter 7 “The control of Microbial Growth”
 MICR20010

Agricultural Microbiology

Dr. Tadhg Ó Cróinín
Important Cycles for life on earth

Carbon cycle

Oxygen Cycle

Nitrogen Cycle

Others are “minor” but sll crical

Microorganisms play key roles in all

2
Carbon Cycle

3
Oxygen Cycle

4
Importance of Microorganisms

Microorganisms such as Prochlorococcus account for a huge
percentage (20% by some esmates) of photosynthec oxygen
producon on the planet

This is more than all the tropical rain forests combined.

Other organisms such as marine Algae play a crical role

Need to also remember the historical context and endsymbiosis.

5
The arrival of Oxygen based
metabolism
Iron oxide bands from
cyanobacterial photosynthesis

Makes a huge di*erence to
energy producon and evoluon
of life
Time Line

Oxygen available as an
electron carrier

Much greater potenal
for energy than in the
anoxic environment

Ozone layer protects
from UV allowing for
more stable DNA
From Prokaryote to Eukaryote
So what about
Nitrogen?

9
Micro-organisms and the Nitrogen
cycle.

Healthy/normal

Phosphate-deficient

Potassium-deficient

Nitrogen-deficient
Nitrogen:

Basic element for life- proteins, nucleic acids

An element that is plenful in the atmosphere (78%)

However, we and most other life forms cannot use this form of Nitrogen.

Micro-organisms play a key role in providing us access to usable nitrogen
sources.
Brock 10th ed,
Fig 19.29
Nitrogen:

Brock 10th ed,
Fig 17.36
Nitrogen:

Brock 10th ed,
Fig 17.36
Nitrogen:

Brock 10th ed,
Fig 17.36
Nitrogen:

Brock 10th ed,
Fig 17.36
Nitrogen:

Brock 10th ed,
Fig 17.36
Nitrogen:
3 major processes of m/o transformaon

1. Nitrogen