Bacterial Growth Requirements PDF

Summary

This document provides an overview of bacterial growth and its requirements. It covers topics such as bacterial growth phases (lag, log, stationary, and death), physical requirements (water, temperature, pH, osmotic pressure, oxygen), chemical requirements (carbon, nitrogen, sulfur, phosphorus, inorganic ions), and methods of bacterial staining and culture media, including general purpose, enrichment, and selective media.

Full Transcript

BACTERIAL
GROWTH
REQUIREMENTS
TOPIC 4 : BACTERIAL GROWTH REQUIREMENTS

At the end of this topic, you must be able to:
∙ Define microbial growth;
∙ Discuss the various nutritional and
physical growth requirements; and
∙ Describe the different phases of
microbial growth
 MICROBIAL GROWTH
Growth involves an orderly and organized
increase in the sum of all components of the
organism which may entail replication of all
cellular structures, organelles, and
components.

Microbial growth – concerned with the
increase in number of cells and not increase
in the size of the organism.
 BINARY FISSION
The process by which organisms divide and reproduce.
 GENERATION TIME
Time required for a cell to divide and its population to
double.
GENERATION TIME
 GENERATION TIME
Time required for a cell to divide and its population to
double.
 BACTERIAL GROWTH
CURVE
Illustrates the phases in the growth of the population of bacteria
when they are grown in a culture of fixed volume. It reflects the
different stages in the growth of a bacterium.
 BACTERIAL GROWTH
PHASES OF GROWTH
LAG PHASE LOG PHASE
Bacteria are still adjusting to their Exponential or logarithmic phase
environment Rapid binary fission
Bacteria absorb nutrients, Number of cells grow exponentially
synthesize enzymes, and prepare Very susceptible to Gram Staining and
for cell division. cell wall inhibitors
Cells grow in size but not in number
STATIONARY PHASE DEATH PHASE
culture is at its greatest population aka logarithmic decline phase
density. Accumulation of toxic metabolites
Number of cells produced= number and autolytic enzymes
of cells dying culture may die completely, or a few
nutrients in the liquid medium are microorganisms or may continue to
used up survive for months
concentration of toxic waste formation of spores
products from the metabolizing Morphologic changes occur (Bacteria
bacteria build up assume different shapes)
 BACTERIAL GROWTH
PHYSICAL REQUIREMENTS
1. Water/Moisture
2. Temperature
3. pH
4. Osmotic pressure
5. Oxygen
 BACTERIAL GROWTH
PHYSICAL REQUIREMENTS
1. Water/Moisture
The bacterial cell is composed mainly of
water. All living organisms require water to carry
out their normal metabolic processes, and most
will die in environments containing too little
moisture.
 BACTERIAL GROWTH
PHYSICAL REQUIREMENTS
2. Temperature
a.Psychrophiles (0-20 oC)
✔live in the refrigerator
a.Mesophiles (21-45 oC)
✔ very pathogenic
b.Thermophiles (46 oC and higher)
✔ freeze at body temperature
 BACTERIAL GROWTH
PHYSICAL REQUIREMENTS
3. pH
a.Alkalophiles – pH 8.4 – 9.0
b.Neutrophiles – pH 6.5 – 7.5
c.Acidophiles – pH less than 6
 BACTERIAL GROWTH
PHYSICAL REQUIREMENTS
4. Osmotic pressure
a.Extreme halophiles – require very high salt
concentration for growth.
b.Obligate halophiles – require enough salt
concentration for growth
c.Facultative halophiles – do not require high
salt concentration but able to grow at salt
concentrations up to 2%.
BACTERIAL GROWTH
REQUIREMENTS
 BACTERIAL GROWTH
REQUIREMENTS
PHYSICAL REQUIREMENTS
5. Oxygen
 BACTERIAL GROWTH
PHYSICAL REQUIREMENTS
5. Oxygen
 BACTERIAL GROWTH
CHEMICAL REQUIREMENTS
1. Carbon
2. Nitrogen, Sulfur, Phosphorus
3. Inorganic Ions
4. Growth Factors
 BACTERIAL GROWTH
CHEMICAL REQUIREMENTS
1. Carbon
 BACTERIAL GROWTH
CHEMICAL REQUIREMENTS
2. Nitrogen, Sulfur, Phosphorus
- necessary for synthesis of proteins and nucleic
acids
 BACTERIAL GROWTH
CHEMICAL REQUIREMENTS
3. Inorganic Ions
a. Magnesium – stabilizes ribosomes, cell membranes,
and nucleic acids; also serves as co-factor in the
activity of enzymes
b. Potassium – for normal functioning and integrity of
ribosomes and enzyme activities
c. Calcium – important component of gram-positive
bacterial cell wall and contributes to the resistance of
bacterial endospores
d. Iron – component of cytochrome, a component of the
electron transport chain and co-factor for enzymatic
activities
 BACTERIAL GROWTH
CHEMICAL REQUIREMENTS
4. Growth Factors
Essential to promote the growth and
development of the bacterial cell. These include
Vitamin B Complex and amino acids.
TOPIC 5 : STAINING AND CULTURE MEDIA

At the end of this topic, you must be able to:
∙ Compare the various staining methods
used to visualize microorganisms; and
∙ Classify the different types of culture
media based on their constituents,
physical state, chemical composition,
and functional type.
 CULTURE MEDIA
A nutrient material prepared for the growth of
microorganisms.
Can be classified into three primary levels:
– Constituents
– Physical state
– Functional type
 ACCORDING TO CONSTITUENTS
Synthetic media
– Contain chemically-defined substances,
which are pure organic or inorganic
compounds.
Non-synthetic media
– Complex media that contain at least one
ingredient that is not chemically defined.
Most are extracts of animals, plants, or
yeasts.
 ACCORDING TO CONSTITUENTS
Synthetic media
– Contain chemically-defined substances

All components and
constituents and
concentrations are
known
Nutrients:
C, H, O, N, S, P,
K, Mg
 ACCORDING TO CONSTITUENTS

Non-synthetic media
– Complex media that contain at least one
ingredient that is not chemically defined.
ACCORDING TO PHYSICAL STATE
Liquid media
– Commonly called broths, milks, or infusions.
– Water-based solutions that do not solidify at
temperatures above freezing point.
Semi-solid media
– Exhibit a clot-like consistency at ordinary room
temperature and contains some amount of
solidifying agent (agar or gelatin) that thickens
the media but does not produce a firm
substance.
ACCORDING TO PHYSICAL STATE
Solid media
– Contain sufficient amounts of solidifying agent,
giving them a firm surface on which cells can
form discrete colonies.
– Two forms:
Liquefiable/Reversible solid media
Non-liquefiable/Non-reversible solid media
 ACCORDING TO FUNCTIONAL TYPE

1. General Purpose Media
– Designed to grow a broad spectrum of microbes
– Contain a mixture of nutrients that can support
the growth of both pathogens and non-
pathogens.
– Ex: peptone water, nutrient broth, nutrient agar
2. Enrichment Media
– Contain complex organic substances (blood,
serum, special growth factors)
– Increases the number of desired microbes
without stimulating the rest of bacterial
population.
 ACCORDING TO FUNCTIONAL TYPE

a. Blood Agar
Certain Gram + bacteria produce Exotoxins
which causes hemolysis of red blood cells
contained in the blood agar
Hemolytic reaction is categorized into three:
1. Beta-hemolysis – complete lysis of RBC
2. Alpha-hemolysis – incomplete lysis of RBC (greenish
discoloration)
3. Gamma-hemolysis – no hemolysis, no change in the
medium.
 ACCORDING TO FUNCTIONAL TYPE

a. Blood Agar
Certain Gram + bacteria produce Exotoxins
which causes hemolysis of red blood cells
contained in the blood agar
Hemolytic reaction is categorized into three:
1. Beta-hemolysis – complete lysis of RBC
2. Alpha-hemolysis – incomplete lysis of RBC (greenish
discoloration)
3. Gamma-hemolysis – no hemolysis, no change in the
medium.
 ACCORDING TO FUNCTIONAL TYPE

b. Chocolate Agar
Used for culturing fastidious organisms such as
Haemophilus sp. and Neisseria sp.
Heat is applied to lyse the red blood cells,
causing the medium to turn brown.
 ACCORDING TO FUNCTIONAL TYPE

3. Selective Media
– Contain one or more substances that
encourage the growth of only a specific target
microorganism and inhibit the growth of
others.
– Designed to prevent the growth of unwanted
contaminating bacteria or commensals so only
the target bacteria will grow.
– Agar-based solid media that allow isolation of
individual bacterial colonies.
 ACCORDING TO FUNCTIONAL TYPE

3. Selective Media
a. Thayer Martin Agar – contains antibiotics trimethoprim,
nystatin, vancomycin, and colistin. Used for isolation of
Neisseria
b. Mannitol Salt Agar – contains 10% NaCl and used for
the isolation of Staphylococcus aureus.
c. MacConkey’s Agar – promotes the growth of gram-
negative bacteria, and inhibits the growth of gram-positive
bacteria.
d. Lowenstein-Jensen Medium – for isolation of
Mycobacterium tuberculosis. Made by the incorporation of
malachite green.
e. Sabouraud’s Dextrose Agar – for isolation of fungi
SELECTIVE MEDIA
SELECTIVE MEDIA
Sabouraud’s Dextrose Agar
SELECTIVE MEDIA
Lowenstein-Jensen Medium
 ACCORDING TO FUNCTIONAL TYPE

4. Differential Media
– Allows the growth of several types of
microorganisms.
– Designed to show visible differences among
certain groups of microorganisms.
– Differences may be seen as variations in
colony size or color, changes in media color,
formation of precipitates or gas bubbles.
– Ex: MacConkey agar, Triple Sugar Iron Agar
 ACCORDING TO FUNCTIONAL TYPE

5. Transport Media
– Used for clinical specimens that need to be
transported to the laboratory immediately after
collection.
– This will prevent the drying of specimen and
inhibit overgrowth of commensals and
contaminating organisms.
Ex: Cary Blair Transport Medium (feces of
suspected cholera patients), Pike’s medium
(throat specimens of patients with
streptococcal infection)
 STAINING
Most microorganisms besides being very tiny
are also devoid of any color and are thus
difficult to see, even with the use of the
microscope.
To facilitate visualization, staining procedures
have been developed by various scientists
Staining procedures are meant to give color to
the organisms, making them easier to see
under the microscope.
Staining can be simple, differential, or special
 SIMPLE STAINING
Make use of a single dye which can either be
aqueous or alcohol-based.
A quick and easy way to visualize cell shape, size,
and arrangement of bacteria.
Uses basic dyes such as safranin, methylene blue,
or crystal violet.
 DIFFERENTIAL STAINING
Used to differentiate one group of
bacteria from another. Two types of
differential staining procedures:
– Gram stain
– Acid-fast stain
 DIFFERENTIAL STAINING
Gram stain
developed in 1884 by the Danish bacteriologist, Hans
Christian Gram.
one of the most useful staining procedures because it
classifies bacteria into two large groups:
– gram-positive
– gram-negative
Exceptions:
- Mycoplasma
- Spirochetes
- Mycobacteria
 DIFFERENTIAL STAINING
Gram stain
 DIFFERENTIAL STAINING
Gram Stain Result
REAGENT FUNCTION GRAM + GRAM -
Crystal violet Primary stain Purple or blue Purple or blue

Gram’s iodine Mordant Purple or blue Purple or blue

Acetone or 95% Decolorizer Purple or blue Colorless
alcohol
Safranin Counterstain/S Purple or blue Red or pink
econdary stain
 DIFFERENTIAL STAINING
Gram Stain Result
 DIFFERENTIAL STAINING
Gram Stain Result
 DIFFERENTIAL STAINING
Acid Fast Stain
Used for bacteria with high lipid content in
their cell wall, hence cannot be stained using
Gram stain.
Microbiologists use this stain to identify all
bacteria in the genus Mycobacterium and
pathogenic strains of the genus Nocardia.
 DIFFERENTIAL STAINING
Acid Fast Stain : Two Methods
Ziehl-Neelsen stain
– Also known as the “hot method” because it
requires steam-bathing the organism with aqueous
dye
– Developed by Franz Ziehl and Friedrich Neelsen
Kinyoun stain
– Also known as the “cold method”, as it does not
utilize heat for staining.
 DIFFERENTIAL STAINING
Acid Fast Stain Result
REAGENT FUNCTION RESULT

Ziehl-Neelsen Kinyoun Acid-fast Non Acid-fast
Carbolfuchsin Carbolfuchsin Primary stain Red or pink Red
Acid alcohol Acid alcohol Decolorizer Red Colorless
Methylene blue Malachite green Counterstain Ziehl Neelsen: Ziehl Neelsen:
or Secondary Red organism/ Blue organism/
stain Blue Blue
background background

Kinyoun: Kinyoun:
Red organism/ Green
Green organism/
background Green
background
 DIFFERENTIAL STAINING
Acid Fast Stain Result
 SPECIAL STAINING
Used to demonstrate specific structures in a
bacterial cell.
– Loeffler Alkaline Methylene Blue (LAMB) Stain
– metachromatic granules
– Hiss stain – capsule or slime layer
– Dyer stain – cell wall
– Fischer-Conn stain – flagella
– Dorner and Schaeffer Fulton stains – spores
– India ink or Nigrosine – capsule of the fungus
Cryptococcus neoformans
SPECIAL STAINING
END