Micro Lecture Set 4: Microbial Growth PDF

Summary

This document is a lecture set on microbial growth, covering various environmental factors like temperature, pH, and osmotic pressure, as well as the chemical requirements for bacterial growth. It details different categories of bacteria based on their temperature, pH, and salt preferences, along with the importance of these factors to various applications, such as food preservation.

Full Transcript

BACTERIAL
GROWTH
Objectives/ Study guide
Define minimal, optimal and maximum temperatures in terms of
bacterial growth
Define and between each of the thermal preference categories of
differentiate bacteria

Relate thermal preferences to 1) refrigeration 2) hot
springs/thermal vents in nature.
Define and
differentiate between the pH preference categories of bacteria
Define and
differentiate between the categories of salt preferences in bacteria

Explain how high salt concentration can kill bacteria, and why
this has been historically important to humans

Define
and Relate osmophiles, xenophiles and halophiles
 Objectives/ Study guide
the chemical requirements for bacteria include explanations for
List & Explain elements such as C, N, P, S, and trace elements and the roles
each play

Explain in general terms why oxygen can be toxic and possibly lethal to
bacteria?
how bacteria get rid of toxic oxygen compounds including: singlet
Describe oxygen/superoxide radicals (enzyme involved in this), Hydrogen
peroxide anions

Differentiate between the two broad categories of oxygen preferences in
bacteria.
the subcategories of oxygen preferences: obligate aerobes,
Differentiate facultative aerobes, microaerophilic aerobes, aerotolerant
anaerobes, and obligate anaerobes.

Describe
how you test for oxygen preferences in bacteria
Define and between the patterns of growth in a stab culture that would help
differentiate you identify the oxygen preferences of a bacteria.
Objectives/ Study guide
Define and
differentiate the two groups of bacteria based on growth factor requirements
Define combine and the terms : culture media, sterile, liquid, solid, agar, inoculum, inoculation, culture,
relate chemically defined media, Minimal, Chemically undefined media, complex media
what agar is and why it is useful in making media. What are 3 or 4 qualities that
Explain make it a good fit for bacteriological media?

Describe the 3 main shapes of solid media
Minimal media (chemically defined) and Complex media (chemically undefined).
What makes them different. Can you give an example of an ingredient that would
Compare and contrast be used in one but not the other
Define, combine and the following terms to one another capnophiles, CO2 , reducing media, Anaerobic,
relate methylene blue, indicator, candle jar, airlocks, Jar , chamber

Explain why we might use an animal or cell cultures for growing bacteria?
the differences between and processes of using selective, differentiating, and
Explain enriching media, provide an example of each media type.
Colony forming unit, bacterial colony, bacterial isolation, mixed culture , pure
Describe and relate culture, and plate streaking
the steps in order of how you would go from a mixed culture to a pure culture with
List individual colonies (suggestion- play the Bacterial isolation labster)
 Objectives/ Study guide
Describe and Colony forming unit, bacterial colony, bacterial isolation, mixed culture ,
relate pure culture

Differentiate between the items and requirements of the 4 BSL levels.
the two methods of long-term storage and why storing bacteria long term
Describe is important
the generation time(G), number of generation(n), incubation time frame
Calculate (t) or number of bacteria given if given at least 2 pieces of information.

Describe the 4 stages of bacterial growth
Plate counts, Spread plate method, pour plate method, Serial dilution,
Explain & CFU What is serial dilution and how is used with plate counts to determine
Relate # of bacteria in a culture?
If you did a direct plate count and on your 1:1000 dilution plate you got
Reason & 50 colonies , what does this mean about your starting (undiluted)
Calculate culture?

Describe What are the general pros and cons of direct PLATE count.
What are the methods for measuring growth indirectly. How is one of
Explain these ways related to turbidity and optical density?
What do bacteria require?
Just like us there are
constraints regarding
environmental qualities
Temperature
pH
Osmotic stresses
As well as nutrients
Carbon, Nitrogen, Sulfur,
and phosphorous
Trace elements
Oxygen
Organic growth factors
Temperature
When it comes to temperature
bacteria usually have an:
Minimum temperature-
Optimal temperature
where they grow the fastest
Maximum temperature
Slows growth
May kill

However, different bacteria have
different temperature
requirements/preferences.
 Three categories of bacteria based on
temperature

Psychrophi
les
cold-loving
Mesophiles
moderate-
temperatur
e-loving
Thermophil
es
heat-loving

We will go through these in detail one at a time
Psychrophiles: (mostly archaea)
Can grow at 0°C
optimum temperature ~ 15°C.
found in deep ocean or polar regions.

Psychrotrophs:
can grow (slowly) even at 0°C
optimum temperature of 20-30°C.
Some grow slowly inside
refrigerator and cause food
spoilage. (mostly Bacteria)
 Why do we
refrigerate food?
To stave off
spoilage/foodborne
illness- which is often
caused by bacteria
(mostly mesophiles)

Most bacteria (even
cold loving ones) do
not grow well below
4C (~39 F)

However, anything
above 15C(60F) is
Thermophiles Hyperthermophiles (extreme
Optimum growth thermophiles)
temperature of 50 to 60°C Most are archaea
Found in hot springs and Optimum growth temperature >
organic compost 80°C
many thermophiles cannot Found in hot springs and deep sea
grow at temperatures vents
below about 45°C. Sulfer is often integral in their
metabolism
Examples of hyper thermophiles- The MOST
extreme
Hyperthermophile
s in Yellowstone
National Park.
Immerse a glass
microslide into the
water (102 °C)
and let it sit for a
few days and this
is what you get: a
microcolony of
prokaryotes.

A hydrothermal vent is a geyser on the
seafloor. It continuously spews super-hot,
mineral-rich water that helps support a
diverse community of organisms.
Extreme ends of the spectrum In 1992, Methanococcoides
burtonii which lives and grows
at -2.5°C, was discovered in Ace
Strain 121. (Geogemma
Lake, Antarctica. Flexible cell
barossii):
walls and an ability to produce
- An Archaea (isolated from
‘antifreeze’ enable some
near deep-sea hydrothermal
bacteria to survive a chilling -
vents) that survives and
20°C.
reproduces at 121°C and
130°C (266 °F) is proven to
be only bacteriostatic.
 Alkaliphiles: prefer a high
pH and are found in regions
pH
with high carbonate
deposits (soda lakes)

Most bacteria are
neutrophiles however,
grow between pH 6.5 and
7.5
Molds and yeasts grow
between pH 5 and 6

Acidophiles grow in acidic
environments – Many
bacteria and archaea that
live in lakes near volcanic
sites or acidic hot springs
 Osmotic pressure
Halo=
The tonicitysalt
of an
environment can vary Halophiles
rather widely (halo tolerant)
Depending on
location/time of year.
Aside from normal
bacteria there are 3
categories of Facultative
halophiles Halophiles

let’s do a
refresher on
osmosis before Obligate
we talk more Extremehalophiles
about these
categories
 Osmolarity/
Tonicity
Hypotonic
solution:
solute concentration is
lower outside than inside
the cell; water moves
into cell
Isotonic
solution:
solute concentrations
equal inside and outside
of cell; water is at
equilibrium
Hypertonic
solution:
solute concentration is
higher outside of cell
than inside; water
moves out of cell
 Osmotic pressure and bacteria
Hypertonic environments (higher in solutes than inside the
cell) cause cells to plasmolysis

However…
Some
bacteria like
it
Salty!
 Facultative halophiles (=
halotolerant)
do not require high salt concentrations but can
grow at up to 2-15% salt concentrations
e.g., Staphylococcus aureus
3 Categories Facultative= they can take or leave it

of salt-loving Halophiles
bacteria grow optimally in salt concentrations equal to sea
(based on water (3% NaCl + many other minerals).
e.g., Alivibrio fischeri
salt
Extreme halophiles (= obligate
dependency halophiles)

) have adapted so well to high salt concentrations
that they actually require high osmotic pressure for
growth.
e.g., Halobacterium salinarum
Obligate= they are obligated or MUST have this
type of environment for survival
On the extreme halophile side….
Other osmotic oddities
Osmophiles: Organisms
that live in high sugar
concentrations.

Xerophiles: Organisms that
live in very dry
environments.
 pH less than 5
Check for understandingCold temperatures
Match up the terms with their
high temperatures
respective meanings regarding
environmental conditions pH between 6.5-
A. Halophile _______________ 7.5 than
pH greater
B. Acidophile _______________ High salt 8conditions
C. Alkeliphile _______________
D. Neutraphile _______________
E. Thermophile
_______________
F. Pychrophile _______________
 Chemical
requirements
The items that our own
bodies require are
pretty similar to what
bacteria need.
Can you think of some
of the essential
elements for life?
Carbon- for various
molecules
Nitrogen- DNA, RNA
proteins
Phosphorus- DNA, RNA
Sulfur – Amino acids
(proteins)
Oxygen- various molecules
Trace elements.

Let’s walk through
Carbon!
Structural backbone of organic molecules
Chemoheterotrophs use organic molecules
as energy
Autotrophs use CO2
fats
CO2
Nitrogen
Major component of proteins, DNA, and ATP
 Nitrogen
Although most
bacteria
decompose
protein material
for the nitrogen
source…
Nitrogen is an
essential
component of
DNA, RNA and
Some bacteria
use NH4+ or NO3-
from organic
Sulfur and Phosphorus
Sulfur
In amino acids, and vitamins such
as thiamine and biotin.
Most bacteria decompose proteins
and some bacteria use SO42– or
H2S.

Phosphorus
In DNA, RNA, ATP, and
membranes.
PO43– is a source of phosphorus.
Check for understanding
Explain why atoms like phosphorus are absolutely
necessary for bacterial survival when they are not used
for energy or needed to make proteins.

Phosphorus is a major component of DNA, thus it is
required for an organism to remain alive as well as for
reproducing
Trace elements
Inorganic elements required in small amounts
Include iron, copper, molybdenum, and zinc
These items most often serve as enzyme cofactors
Check for understanding
What role do micronutrients like zinc and iron play in in the
molecular needs of bacteria and other cells?

A. These metals hold onto oxygen so it does not leave the cell
B. These metals are necessary as they are integral parts of
nucleotides that make up the DNA and RNA
C. They often serve as cofactors and play a role in enzymatic
function
D. They are needed as they are integral parts in all amino acids
E. They often serve as sources of energy when they are broken
down
Oxygen
Oxygen is very useful
and necessary in most
cases.
Do you remember why
Eukaryotic cells need
oxygen?

What is oxygen’s roll in
Oxygen is the final
the cell respiration
process?
Electron acceptor!
 Unfortunately, with oxygen too much of a
good thing can be deadly especially if you
are a microbe

Oxygen can form radicals (loose
their electrons on accident)

Which causes them to go on a
rampage and start ripping electrons
off of other molecules willy-nilly.

This is very bad!

Microbes can be classified into
2 broad categories with a total of
5 total distinct categories based on their
oxygen preferences
 How can oxygen be toxic!?
1. Singlet oxygen (1O2−): normal O2 that has been boosted to a
higher-energy state.
(i.e. when you split an O2 you make a singlet oxygen)

2. Superoxide radicals or superoxide anions (O2 - ):
formed in small amounts when O2 accepts electrons during the respiration.
greatly unstable that they steal an electron from a neighboring molecule,
leading to a radical chain reaction.
All aerobes produce superoxide dismutase (SOD) to convert
the superoxide radical into molecular oxygen (O2) and hydrogen
peroxide (H2O2).
O2 + O2
  + 
2
SOD
+ 2HO +HOO 
+ O +
2 2 2 + 2H2 H2 O 2 + O 2
How can oxygen be toxic!?
3. H2O2 and Peroxide anion (O22– ):
hydrogen peroxide produced during normal aerobic
respiration.
Aerobes produce catalase (produce O2) and peroxidase to
neutralize it.

These radicals are thwarted by catalase and
peroxidase respectively
How can oxygen be toxic!? (4th of
the 4 ways)
4. Hydroxyl radical (OH )
Probably the most reactive and formed transiently in the cellular
cytoplasm by ionizing radiation.

It cannot be eliminated by an enzymatic reaction. It can be
eliminated by endogenous antioxidants such as
glutathione, and dietary Vitamin E.

Which is found naturally in many fruits and vegetables
How do these radicals form?
How are they dealt with?

Or it is handled by an
antioxidant
 Categories of oxygen preference in bacteria
Anaerobes-
Aerobes- Do NOT need
Need O2 O2
Obligate aerobes Aerotolerant
absolutely need O2 anaerobes
(Streptomyces coelicolor, M. growth same with or
tuberculosis..). without O2 (lactic
Facultative aerobes acid bacteria..).
not needed but grow better (E. coli..). Obligate
Microaerophilic aerobes anaerobes
killed by O2
needed but at concentrations below those
found in the atmosphere (Helicobacter pylori). (Clostridium).
Evaluating oxygen preference in
bacteria
To do this you perform a stab
1. Take a sterile vile containing an nutrient agar
mixture
2. Sterilize an inoculation wire
3. Rub the end of the wire on a colony from a plate
4. Flame the opening of the vial with the nutrient agar
5. Use the wire to make 1-3 deep stabs into the agar
6. Incubate the tube under normal oxygen conditions at
preferred temperature

Let’s look at the different results we can get
Effects of oxygen on bacterial growth
Expectation/check for
understanding
Given an image of one of those vials and the pattern
of bacterial growth you should be able to identify
/categorize the oxygen preference of the bacteria
Let’s do a check for understanding
What is the oxygen preference of the bacteria grown
in this vial:

microaerophile
 Organic compounds
obtained from the
environment because
they cannot be
synthesized
Organic
Vitamins,
Growth amino acids,
factors 3
Major Purines/
groups pyrimidines
(nitrogenous
bases for
DNA/RNA)
Grouping organisms based on their growth factor
requirements
2 groups
Prototroph:
principal C-source (usually glucose) is enough.

Auxotrophs:
require secondary organic nutrient (= growth factor)
in addition to the principal C-source.
trp- auxotroph (mutant) of E. coli requires tryptophan
in addition to glucose for survival.
Culture media basics

Culture media is used in various
way to culture/grow bacteria
We can enrich or select for
specific types of cellular
organisms by altering the
ingredients suspended in the
media of our choice
Media may be solid or liquid
Before we go too deep, let’s lay a
bit of terminology background.
Terminology
Culture medium:
nutrients prepared for microbial
growth either liquid or
suspended in a matrix of agar

Sterile:
no living microbes present

Inoculum/inoculation:
source of microbes to be used /
introduction of microbes into a
medium

Culture:
microbes growing in or on a
culture medium
The Requirements for growing specific organisms
1. it must contain the right nutrients for the
microbe we want to grow.

2. it should contain sufficient
moisture (free water), a
proper pH,
suitable level of oxygen.

3. it must initially be sterile (no living
microbes) so that the culture will contain
only the microbes we add to the medium.

4. it should be incubated at the proper
temperature.
Agar

Complex polysaccharide
derived from seaweed
used as a solidifying agent in
media
Is not metabolized by
microbes (won’t
disintegrate)
optimal choice when we
desire to grow bacteria on a
solid substrate.
 Agar

Autoclavable- Liquefies at 100°C
Solidifies at ~40°C
thus it will solidify
at room temperature ( ~25° C or 72° F)

Oh, and edible by the way…
Fun side note
Agar is widely popular in Japanese culture

Used in many Japanese artistic desserts called

wagashi
Shapes of Solid media
Petri plates

slants (1 and 2)
(shallow or steep)

deeps (3)
(for stabs and
growing bacteria
that
are not as tolerant of
oxygen)
 Microbial growth
Media, conditions &
cultures
When it comes to media
The goal is to support
microbial growth
a medium must provide an
energy source
as well as sources of C, N, S,
P, and..
any organic growth factors
the organism cannot
synthesize. ( signaling
molecules that trigger
growth and reproduction)

There are two big
categories:
1. Minimal/Chemically
defined media
Minimal /Chemically defined media
Chemically defined
media
(minimal/synthetic
media)
exact chemical
composition is known
Fastidious organisms
are those that require
many growth factors
provided in chemically
defined media
Chemically
Defined media
Complex media/chemically
undefined

Complex media/ undefined media:
exact chemical composition is not known
because at least one ingredient (e.g., beef
extract or yeast extract) is chemically
undefined.

Energy, C, N, and S requirements are provided
primarily by proteins that are a partially
digested by acids or enzymes to shorter chains
of amino acids called peptones.

Vitamins and other organic growth factors are
provided by meat extracts or yeast extracts.
Check for understanding
When making various solid media, what ingredient
provides the solidity?
A. Salts
B. Water
C. peptone
D. Agar
E. glucose
Check for understanding
Which of these ingredient would NEVER be used in a
chemically defined media? (select all that apply)

Glucose Beef extract
NaCl Magnesium Calcium
peptone chloride chloride
Agar Biotin
Water
Vitamin A
 Anaerobic bacteria –
low/no oxygen
environment
Growing
bacteria in
Capnophiles – high CO2
special environment
environme
nts
In or on hosts
Anaerobic (low or no oxygen) environments

To grow more anaerobic bacteria an
anaerobic jar can be used

Can use the same chemical
methods mentioned before but on a
larger scale

Methylene blue indicator strips are
used to verify oxygen free
environment
they turn blue when oxygen is
present
Anaerobic conditions
Alternatively a special
chamber can be used for
larger volumes of work
with anaerobes.

Anaerobic chamber is
usually filled with :
inert gas (typically about
85% N2, 10% H2,
5% CO2
equipped with air locks
to introduce cultures and
materials.
 Anaerobic conditions
Clostridium perfringens
Reducing media is used
Such as the “oxyplate” Used for the
cultivation of anaerobic bacteria
Each plate becomes an anaerobic chamber
Each plate has oxyrase , O2+ 4H→ 2water

Other methods:
chemicals (like sodium
thioglycolate)
that combine to O2 to deplete it
Heated to drive off O2
Capnophiles conditions
Capnophiles
Microbes that
require high CO2
conditions
Candle jar
CO2 packet or CO2 incubator
tanks!

Candal jar source:
https://www.jfmed.uniba.sk/fileadmin/jlf/Pracovi
ska/ustav-mikrobiologie-a-imunologie/
In or on a host
Mycobacterium leprae is
cultured on the feet of mice or
on nine banded armadillos due
to the inability to culture in
vitro.

Like viruses, the syphilis
spirochete (Treponema
pallidum) and the obligate
intracellular bacteria (e.g., the
Rickettsia and the Chlamydia)
Cell infected with Chlamydia CREDIT: Biomedical Imaging
can reproduce only in a living Unit, Southampton General Hospital/Science Source
 Culture media types overview
Type Purpose

Chemically Defined Growth of chemoautotrophs and photoautotrophs;
microbiological assays
Complex Growth of most chemoheterotrophic
organisms

Reducing Growth of obligate anaerobes

Selective Suppression of unwanted microbes; encouraging desired
microbes
Differential Differentiation of colonies of desired microbes from others

Enrichment Similar to selective media but designed to increase numbers
of desired microbes to detectable levels
Check for understanding
We have talked about a special media plate that
provides a low oxygen environment without need for a
fancy expensive piece of equipment. Which kind of
media serves this purpose?

A. Oxidation media
B. Chemically defined media
C. Reducing media
D. Complete media
E. Minimal media
Selective & differential culture
media

We can detect and identify bacteria through selection and
screening using a variety of media in conjunction with
biochemical tests.

For now we will just focus on the types of media used to
grow bacteria.
 Selective Media
Eosin methylene blue (EMB)
Encourages encourages growth of G-
growth desired bacteria while suppressing
G+ growth, it also
microbes, but… differentiates E. coli which
Contains produces a metallic green
hue S. typhi on bismuth sulfite agar
inhibitors to
suppress growth bismuth sulfite agar,
of unwanted suppresses G- and other
bacteria and bacteria from intestine, while
encouraging Salmonella typhi
encourage the growth
growth of the
desired
microbes.
Differential (screening) media
This type of media does not
inhibit any particular
growth

It does affect the
appearance of some
bacteria

Allowing for distinguishing
colonies of desired species
from others on the plate
 Differential combined with selective media
Isolation of the common bacterium Staphylococcus
aureus, found in the nasal passages.
S. aureus (as a genus of Staphylococcus) has high NaCl
tolerance + ferments mannitol to form acid (lowers pH)
We can isolate S. aureus plating
onto a Mannitol salt agar

Staphylococcus
containing 7.5% NaCl Staphylococcus aureus is resistant
(to select for high-salt epidermis is to high salt and
resistant S. aureus) resistant to high salt ferment mannitol
but does not into acids.
plus pH indicator ferment mannitol.
(phenol red; to screen
for
mannitol- fermenting
S. aureus).
Enrichment media
Enrichment culture can be used
when you want to increase very
small numbers of the desired
type of microbe to detectable
levels.

Example: To isolate a microbe
from a soil sample that can
grow on phenol and is present
in much smaller numbers than
other species.
 Use of enrichment media example
Inoculate the soil sample into phenol-containing
culture medium
(where phenol is the only source of carbon and energy) and incubate
for a few days.

Transfer 1 ml to another flask
of the same but fresh phenol medium, and incubate.

After a series of such transfers,
the surviving population will consist of bacteria capable of
metabolizing phenol.

When the last dilution is streaked onto a solid medium of the same
composition
only those colonies of organisms capable of using phenol should grow.
Check for understanding
How does selection media differ from differential media?
Can these types of media be used together. Provide an
example.

Differential media will help you tell apart different bacteria, but it does
not suppress any particular bacterial type. Selection media DOES
suppress the growth of certain bacterial types. You can combine the
two to make a selection/differentiation media

Example: Mannitol salt agar (high salt only allows salt tolerant
bacteria to grow); the pH indicator + mannitol sugar is the differential
part- allowing you to see which bacteria can ferment mannitol sugars.
Obtaining pure cultures
A pure culture contains
only one species or strain

A colony is a population of
cells arising from a single
cell or spore or from a
group of attached cells

Serratia marcescens
Obtaining pure cultures
A colony is often called a
colony-forming unit (CFU)
it is also a unit of measure
We can dilute bacteria and
spread it out over media
Each colony was formed by a
single bacteria (unit)
Allows us to quantify bacteria
from samples

When we plate we want
individual colonies.
Whether we are counting
Or isolating bacteria
Check for understanding and recall
If you had a mixed culture, how would you go about obtaining a
pure culture.

List ALL the steps, from obtaining a liquid sample of mixed
bacteria, to the final step of evaluating a plate that has a pure
culture.
Include all incubations , initial loop sterilization, loop flaming , as
well as the steps of streaking out the plate (between the
quadrants and flaming in between)

You SHOULD be able to list this out in 10-14 steps (be detailed!)
 Biosafety levels ,
bacterial
preservation/storage
and bacterial growth
 Biosafety-
BSL4
4 levels
BSL4 is the most
s

BSL3
rou

dangerous with the
ge
n

most stringency and
da

precaution.
st
Mo

BSL2 We will walk through
them one at a time.
t
fes

BSL1
Sa
 BSL
Biosafety-
1
BSL4
BSL-1: no special
precautions
s

BSL3
rou

basic teaching labs
ge
n

Many basic research
da
st

labs
Mo

BSL2
t
fes

BSL1
Sa
 BSL
Biosafety-
1
BSL4
s

BSL3
rou
ge
n
da
st
Mo

BSL2
t
fes

BSL1
Sa
 BSL
Biosafety-
2
BSL4 BSL-2: lab coat,
gloves, eye protection
s

BSL3 May include use of
rou
ge

fume hood (but it is
n
da

not required)
st
Mo

Moderate risk of
BSL2 infection.
Treatments or cures
t
fes

available
BSL1
Sa
 BSL
Biosafety-
2
BSL4
s

BSL3
rou
ge
n
da
st
Mo

BSL2
t
fes

BSL1
Sa
 BSL
Biosafety-
3
BSL4 biosafety cabinets
required to prevent
BSL airborne transmission
s

For highly infectious
rou

3 pathogens such as the
ge

tuberculosis or HIV.
n
da

The laboratory is
st

negatively pressurized
Mo

BSL2 and equipped with air
filters to prevent release
of the pathogen from the
laboratory.
All waste materials
t
fes

leaving the lab must be
BSL1
Sa

autoclaved
 BSL
Biosafety-
3
BSL4
BSL
s
rou

3
ge
n
da
st
Mo

BSL2
t
fes

BSL1
Sa
 BSL
Biosafety-
BSL 4
4 BSL-3 plus sealing of the
room, the exhaust air is
filtered twice.
s

BSL3
rou

For easily transmitted
ge
n

viral pathogens causing
da

fatal hemorrhagic fever
st
Mo

such as Ebola and
BSL2 Marburg viruses.
Very few BSL 4 labs exist
due to the nature of the
t
fes

pathogens dealt with in
BSL1
Sa

these labs
 BSL
Biosafety-
BSL 4
s
4
BSL3
rou
ge
n
da
st
Mo

BSL2
t
fes

BSL1
Sa
Other Comparison of BSL
differences – please review on your
own
Expectation

Explain how each
safety level is
different from the
one above or below
it
(i.e. What is BSL1
and how is it
different from
BSL2 , how is BSL2
different form BSL3
etc.)
Expectation / Check for understanding

Which of the following is true regarding the differences between
BSL2 and BSL 4

A. BSL4 is always under negative pressure, this is not required for
BSL2
B. There are more BSL4 labs than BSL2 labs in the USA
C. BSL4 PPE requires goggles, gloves and lab coats while BSL2 does
not require goggles or lab coats (only gloves)
D. BSL 2 labs deal with infectious pathogens that often have
treatments while BSL4 labs deal with pathogens that are much
more pathogenic and often lack treatments.
E. BSL2 labs are always under negative pressure while BSL 4 labs
are under positive pressure.
The 2 Major
bacteria 1. Deep-freezing
preservatio 2. Lyophiliyzation
n (freeze drying)
techniques
Both are used
for long-term
storage
 Bacteria are prepared in
Deep freezing a liquid culture
Then mixed with a
media that contains
glycerol
Before being frozen
down to and held at
−50° to −95°C

Deep-
freezers
Lyophilization (freeze drying)
frozen (−54° to
−72°C) and
dehydrated in a
vacuum
Why do we use long-
term storage
Imagine if your experiments
relied on bacteria that
stayed the same
How do you ensure that
your bacteria is the same
on day 1 of your experiment
versus Day 1000 (3 years
later)

Freezing down your strain
then pulling a fresh thaw for
a fresh culture regularly is
key!
Why do we need to
store bacteria for long
term
How do you ensure that
your bacteria is the
same between day 1 of
your experiment vs day
1000?

Long term storage of
many aliquots

Aliquots used to create
fresh cultures
Check for understanding
Given what we just talked about. If a hypothetical
disaster occurred on the space station where a hole was
ripped open on the station , it would get…very cold and
there would be a vacuumed.
What would likely happen to any bacterial samples
being studied?
The bacteria would just go dormant (nothing bad
would happen to them), since bacteria can survive
at -80 and they are just fine with being freeze dried
(dried under a vacuum) they would be just fine
 Cell replication : increases
numbers but not size of cells

Types of replication

Conidiospor
Fragmentat
Binary es
Budding ion of
fission (actinomyc
filaments
etes)
Binary fission –
bacterial
replication
1. Replicate
genome
2. Elongate cell
3. Form cell wall
and membrane
barrier
Example of binary fission
Generation time
Time required for a
cell to divide
20 minutes to 24
hours
Binary fission
doubles the number
of cells each
generation
Total number of
cells = 2number of
generations

Growth curves are
 Generation time
Generation time =
the time it takes for a cell to
divide
20 minutes
to 24 hours
Binary fission doubles the
number of cells each
generation
This is why 1 invisible bacteria
Turns into a visible colony overnight
 G=t/n
G = Generation time (time for the cells to divide)
t = Time interval in minutes or hours
n = Number of generations (number of times the
cell population doubles during the time
interval)

N = N0 x 2n
(growth by binary fission)
N0 =# of bacteria at the beginning of a time interval
N = #of bacteria at the end of the time interval
IF you are given the start and end # of bacteria,
you can always calculate how many replication
cycles.
 G=t/n
G = Generation time (time for the cells to divide)
t = Time interval in minutes or hours
n = Number of generations (number of times the
cell population doubles during the time
interval)

I will not ask you to calculate the
generation number (the equation from the
yellow box)

However, I will expect that you can use
the equation above,
G=t/n
As well as :
Total number of cells = 2number of generations
Generation time

n = number of generation
(or amount of division
cycles)
Growth curves are
represented
logarithmically

Simplified equation:
𝑛
¿ 𝑜𝑓 𝑐𝑒𝑙𝑙𝑠= 2
Generation time
Check for understanding
Let’s put things in perspective

If a bacteria has a generation time of 30 minutes (0.5h).
And you start off with 1 cell
How many cells do you have after 8 h (hours)

16
𝑡𝑜𝑡𝑎𝑙 ¿ 𝑜𝑓 𝑐𝑒𝑙𝑙𝑠=2
𝑛
¿ 2 =65 , 536
Check for understanding
What if a bacteria had a generation time of 20 minutes
(basically times per hour) and an incubation time of 10
hours? How many bacteria will we get at the end of 10
hours?
Check for understanding
What if a bacteria had a generation time of 20 minutes
(basically times per hour) and an incubation time of 10
hours? How many bacteria will we get at the end of 10
hours?
𝑛
𝑡𝑜𝑡𝑎𝑙 ¿ 𝑜𝑓 𝑐𝑒𝑙𝑙𝑠=2


30
¿ 2 =1 ,073 , 741 , 824
(b) Conversion of the number of cells in a population
into the logarithmic expression of this number. To arrive
at the numbers in the center column, use the yx key on your
calculator. Enter 2 on the calculator; press yx; enter 5; then
press the = sign. The calculator will show the number 32. Thus,
the fifth-generation population of bacteria will total 32 cells. To Number of bacteria increase
arrive at the numbers in the right-hand column, use the log key exponentially,
on your calculator. Enter the number 32; then press the log
key. The calculator will show, rounded off, that the log10 of 32
is 1.51. So a regular scale mask the amount
of growth at the beginning and the
y-axis is very odd since we are
dealing with very small and very big
 Generation time is
calculated only for the
bacterial culture that is at
the stage of
Exponential Growth in
which cell numbers double
within a specific time
interval.
This is why we call it
“log phase”
Bacterial growth stages

There are 4 distinct phases
of bacterial growth

Station
Lag Log Death
ary
phase phase phase
phase
 Phases of bacterial growth
Lag phase
slow growth as bacteria adapt to their new growth conditions

Log phase
exponential phase , cell number doubles regularly

Stationary phase
food running out, equilibrium of new division vs cell death

Death phase –
rate than they are dividing due to lack of nutrient resources.
Cells may or may not lyse. This stage will also be logarithmic
Check for understanding
Which of these statements are True and which are false

F
_____ The lag phase is when the bacteria are doubling
regularly.
T
_____ During the stationary phase the rate of cell death
is roughly equal to the number of new cells yielded by
F
binary fission

_____ In the log phase (exponential) bacterial death is
outpacing the number of new bacterial cells being
Measurements of bacterial growth

When it comes to Direct
measuring
bacteria, we have
two different
ways indirect
Measuring
bacterial
growth
 Measuring bacterial growth- Direct methods
Plate count – May require
counts only live diluting the
culture
cells

Concentrates
Direct Filtration the bacteria
Count from the
sample
microbial
measuremen Most probable
cells Relies on
ts number (MPN) statistical
probability ( We
method are not covering
this one)
Direct
microscopic count
Think about these question as
we proceed
Which of the methods discussed would you use for bacteria
that are heat-stable but require an environment with less
oxygen to grow well?

Which method would you use to quantify bacterial in
drinking water (where contaminants are pretty rare but may
occur)

Describe how the Most probable number is different than
the other 3 methods discus (plate counts filtration or direct
counting of cells on a slide)
 A frequently used
method
Direct- Plate counts Serial dilution of bacterial
culture is made
(several dilutions may be
tested)
Known volume of the
total solution is plated
Number of resulting CFU
(colony forming units)
can be counted
Must be feasible to count
but not too few
This may employ either
the pour-plate method
or spread plate
method
 Plate count pros and cons

Pros cons
Measures May not be
only viable perfectly
cells accurate if
cells
naturally
Is easy and clump or
quick to grow in
create chains

Is a common Takes time
method to incubate
Pour vs spread plate

Colonies will grow
1. within the nutrient agar, &
2. on the surface of the agar.

- Heat-sensitive microbes may be
damaged,
- Colonies formed inside agar may This method
not represent the bacterium’s positions all the
unique colony morphology. colonies on the
surface.
Direct- Filtration
- When the quantity of bacteria is very small (e.g., when test fecal contamination of water or
food), bacteria can be counted by filtration methods.

At least 100 ml of water The bacteria are This filter is then transferred
are passed through a thin filtered to a nutrient agar plate,
membrane filter whose out and retained on where colonies arise from
pores are too small to the surface of the the bacteria on the filter’s
allow bacteria to pass. filter surface.
Direct- Direct
microscopic count
Volume of a bacterial
suspension placed on a
slide
Average number of bacteria
per viewing field is
calculated
Uses a special Petroff-
Hausser cell counter (on
right)
Measuring bacterial growth- Indirect methods

Turbidity
Quality of bacterial
growth used to
estimate cell Metabolic activity
number

Dry weight

indirect
i.e. we are not observing bacterial
growth directly but rather the collective
Effects of their growth
 Two indirect methods

METABOLIC ACTIVITY DRY WEIGHT—
—AMOUNT OF BACTERIA ARE
METABOLIC PRODUCT IS FILTERED, DRIED, AND
PROPORTIONAL TO THE WEIGHED; USED FOR
NUMBER OF BACTERIA FILAMENTOUS
ORGANISMS
 Third Indirect method - Turbidity

Turbidity—
measurement of
cloudiness with a
spectrophotometer
Microbes scatter
light:
More microbes → less
light gets through
(higher turbidity)
 Third Indirect method - Turbidity

Spectrophotometer
detect measures light
getting through a sample
and deters how much
light was absorbed by the
sample
This is used to calculate
Optical Density (OD).
The higher OD value, the
more turbid the cell
suspension, the more
cells there are.
OD will increase over
time as the bacteria grow
in the culture.
 microscope Filtratio Turbidit
Check for understanding count
Serial Spread
n y

Pour plate
dilution+ plate
method
plate count method
Which of the methods discussed would
you use for bacteria that are heat-stable
but require an environment with less
oxygen to grow well?

Which method(s) would you use to
quantify bacterial in drinking water (where
contaminants are pretty rare but may
occur)

Which method(s) would you use if you had
a sample that you thought was heavily
contaminated and you wanted to quantify
the level of contamination.
Coming up next…
CONTROL of microbial growth
 Supplementary
Materials
Please review this material on your own as it may aid
your studies or show up on the exam.
 Question- how Final number of bacteria at

Answers to
many times per Time interval Number of end of incubation
Generation
Condition/ hour will the allows for generations that N
time
problem bacteria divide? incubation occurred

Guided notes
G
t n

practice 248 =
questions for
4 times per
1 15minutes 12 hours 48 generations
hour

2.8* 1014
calculating
bacterial growth 220 =
2 30 minutes 2 times 10 hours 20 generations
1.04*
106

3
20 minutes 3 times per
8 hours 24 generations
224 =
hour

1.7* 107

2 hours
Only ½ per hour
(or once every 2 30 hours 15 generations
215 =
4
hours)
32768
Check for understanding
Why is sulfur necessary for some bacteria, it is not
needed for DNA or for most energy processes, so why is
it needed at all?
Check for understanding
There were three forms of solid media that we
mentioned. Do you remember what they are?
Which of these is NOT one of them.

A. Petri dishes
B. spherical
C. Slant
D. Deep
Check for understanding
What are the 3 main categories of special conditions
that bacteria may need to be grown (provide the name
of the bacterial category if it applies)
Check for understanding (2/3)
Provide two example of how we can provide bacteria
with special conditions they need to survive if they
require low oxygen or high CO2 (explain how the system
you chose provides for the bacteria’s required
environment in basic terms)
Additional objectives
The objectives below should match to the objectives
already listed in previous lectures. However, you can
use these as an additional check for understanding.
Check for understanding
Explain what high turbidity is and how it relates to
bacterial number.

Explain how turbidity (an indirect form of bacterial
measurement) differs from any of the direct methods.

Turbidity = cloudiness of a liquid culture and is
dependent on how many cells are in the suspension.
More cells= higher turbidity. We can measure how much
light gets through a sample  less light =more bacteria
blocking the light and thus higher bacterial number.
Check for understanding
Which of the methods discussed
would you use for bacteria that are
heat-stable but require an
environment with less oxygen to
grow well?

Which method would you use to
quantify bacterial in drinking water
(where contaminants are pretty
rare but may occur)

Describe how the Most probable
number is different than the other
3 methods discus (plate counts
filtration or direct counting of cells
on a slide)
Check for understanding
What is the purpose of enrichment media as we have
discussed here? How does it achieve this purpose
(generally speaking)

Can you give an example of what would be an
‘enriching’ component in such media?