Unit 1 Lessons 1-4 PDF

Summary

This document details the functional anatomy of prokaryotic and eukaryotic cells, as well as microorganisms, including their structure and functions, different types, and growth phases. It covers topics such as bacteria, archaea, fungi, and viruses.

Full Transcript

LESSON 1: FUNCTIONAL ANATOMY 2. Eukaryotic
OF PROKARYOTIC AND EUKARYOTIC - Eukarya: algae, protozoa, fungi
CELLS - Contains organelles

Microorganism 2 microbial cells:
- Aka microbes Prokaryotes
- Inhabit environment that supports - Evolved first due to the presence
life – microbial communities of RNA first in the planet
- Undifferentiated, single celled or - Lacks organelles
multicellular - Circular DNA
- Essential in sustaining life: - No cationic proteins called
provides oxygen histones
- Pathogens - microbes causing - No nucleus
diseases - Archaea, cyanobacteria,
- Bacteria, archaea, algae eubacteria
- Microbiology is the study of the - Divides faster:
dominant form of life on Earth surface area > volume
- Microbial culture - collection of - Horizontal transfers (share to the
cells that have been grown on a same generation): conjugation,
nutrient medium another bacteria. Then undergoes
- Liquid or solid mixture that recombination giving rise to new
contains all the nutrients phenotypes
needed for a microbe to - Transduction - transfer by
grow bacteriophage (a virus) which
- Growth refers to increase in cell could be generalized or specialized
number and not in cell mass - Conjugation - cell to cell contact
forming a colony thru plasmids (circular DNA that
- Viruses are not cells, survived only are self replicating) or transposons
with the hosts (jumping genes, motile)
- No meiosis, only conjugation
Microbial Cells
- Cytoplasmic membrane -
permeability barrier, separates
cytoplasm from outside
- Cytoplasm - mixture of
macromolecules, small organic
molecules, inorganic ions,
ribosomes Eukaryotes
- Ribosomes - protein synthesis - Contain organelles
- Cell wall - structural strength - Linear DNA
- DNA genome - full set of genes in - Divides slower :
a cell// living blueprint surface area < volume
(chromosomes) - Animals and plants
- Genes - segments of DNA that - Plants and fungi are the only ones
encode protein or RNA molecule that have cell wall
2 fundamental cell types:
1. Prokaryotic
- Bacteria & Archaea 3 Domain Systems of Classification
 1. Domain Archaea - Some are commensals (gets
- Prokaryotes, single celled energy from host but does not
- Thrive areas with high salinity, affect the host at all)
temperature, pressure - Nucleus is vesicular (active
(extremophiles) transcription)
- Heterotrophs (energy from other
organisms) or autotrophs (make Slime molds
their own food) - Aka myxomycetes
- Composed of acellular mass of
2. Domain Bacteria naked protoplasm
- Aka Eubacteria - Saprophytic (feeds on dead
- Prokaryotes, single celled animals// recyclers)
- Heterotrophs - Lack chitin in cell wall
- Most abundant - Unicellular
- Cell walls have peptidoglycan: - Vegetative stage has no cell walls
- N-acetylmuramic acid
and N-acetylglucosamine Water molds
linked by short peptides - Diploid nuclei
- Oogamous - immobile egg +
3. Domain Eukarya motile sperm
- Major groups: fungi and protista - Saprotrophic
- Flagellated reproductive cells
Fungi - Most thrive in water or moist areas
- Unicellular - yeast
- Multicellular - lichens (symbiotic Viruses
partnership of alga and fungus), - Noncellular
mushrooms - Have RNA or DNA
- Heterotrophic - Nucleic acid enclosed in protein
- Lack motility coat or capsid// could be single or
- Cell walls have chitin double stranded
- Most fungi have hyphae (feathery
filaments for vegetative growth)

Protista
Algae - Seen using scanning and
- Polyphyletic (more than one transmission electron microscope
common evolutionary ancestor) - Cannot reproduce by itself
- Photoautotrophic (from sunlight) (dependent to host)
- Primarily aquatic
- Unicellular Archaea vs Bacteria
- Thallophytic: No vascular system, - Archaea: least characterized and
did not undergo cell differentiation plays major role in recycling
- Some are motile (flagella) nitrogen
- Component of membranes:
Protozoans - ether lipids (archaea)
- Unicellular, motile - ester lipids (bacteria)
- Free-living - Archaea and bacteria influenced
the evolution of eukaryotes
Cell morphology gram negative - thin
Spherical peptidoglycan, fuchsia pink
- Coccus = 1
- Diplococcus = 2 Gram Positive Cell Wall
- Streptococcus = straight line - Thick and rigid layers of
- Tetracoccus = 4 peptidoglycan
- Sarcina = 2 tetra together Teichoic acids:
- Staphylococcus = fusion (-) charged, regulate movement of
Spiral cations
- Vibrio Regulate growth and prevent lysis
- Spirillum Used to identify bacteria
- Spirochetes Types:
Rod-shaped - Lipoteichoic acids - linked to cell
- Single bacillus membrane, spans the cell wall
- Diplobacilli - Wall teichoic acids - linked to
- Streptobacilli peptidoglycan layer
- Palisades - Susceptible to antibiotics due to no
Other shapes outer membrane
- Filamentous
- Star shaped
- Rectangular
- Hyphae

BACTERIA
Cytoplasmic membrane
- Selective permeability
- Maintains integrity - separations of
inside and outside environment
- Hypothetical absence: loss of
control, disrupted homeostasis =
cell death

Cell wall (Cell envelope)
- Prevent lysis: protection against
Gram Negative Cell Wall
osmotic pressure
- Thin and complex of peptidoglycan
- Shape and rigidity
- Has an outer membrane:
- Peptidoglycan and LPS - unique
- Bonds to lipoproteins:
to bacteria structure
linked to outer membrane
- Sterols in cell wall-less bacteria
and periplasmic space
(mycoplasma, ureaplasma)
- Periplasmic space:
- D-type = dextro
contains degradative
enzymes and transport
proteins
Gram Staining
- Hans Christian Gram
Structure of Cell Wall
- to differentiate bacteria:
1. Outer membrane
gram positive - thick
2. Periplasmic space
peptidoglycan, dark purple
 3. Peptidoglycan Unique archaeal cell wall compositions
4. Periplasmic space Examples:
5. Cytoplasmic Membrane Methanosarcina sp. -
non-sulfated polysaccharides
Components of Outer Membrane (OM) Halococcus sp. - sulfated
- Phospholipid bilayer Halobacterium sp. - negatively
- Porins - membrane protein// charged acidic amino acids to
allows passage of small molecules counteract high Na+ environment,
- Lipoproteins - structural stability lying at NaCl concentrations below
- Lipopolysaccharides (LPS) : 5%
Polysaccharides: acts as antigens Methanomicrobium sp. and
Lipid A - endotoxin causing fever methanococcus sp. - cell walls
and shock made of protein subunits
- It is for protection such as evasion
and barrier (against antibiotics) Cytoplasmic membrane
- Selective permeability
Structure of bacterial - Lipid bilayer
lipopolysaccharide hydrophobic tail - fatty acid
1. O-specific polysaccharide hydrophilic head - phosphate
- O-antigen - present in antibiotics to - Phospholipid molecule - phosphate
avoid the host’s immune system group and lipid
2. Core polysaccharide - Hepanoids : prokaryotes
- Kdo - for structural support - Sterols : eukaryotes (pentacylic
3. Lipid A sterol-like molecules)
- Anchors LPS to membrane
- 2 glucosamine Function of prokaryotic cytoplasmic
(N-acetylglucosamine) sugar membrane:
backbone connected by phosphate 1. Osmotic or permeability barrier
groups 2. Transport systems - specific
solutes (nutrients and ions)
ARCHAEA 3. Energy generation - respiratory
Cell walls and photosynthetic electron
- No peptidoglycan transport systems, proton motive
- Structure: force, transmembranous
Pseudomurein in methanogens ATP-synthesizing ATPase
(similar to peptidoglycan) 4. Synthesis of membrane lipids and
S-layer - paracrystalline, the murein
outermost layer 5. Assembly and secretion
Structure: glycan composition 6. Specialized enzyme
(arrangement of sugar molecules) 7. Coordination
- NAT or T : 8. Chemotaxis - movement of cell to
N-acetyl-D-galactosamine chemical gradient such as
- NAG or G : nutrients and water
N-acetyl-D-glucosamine
- L-type = levo
LESSON: 2 CELL SURFACE Fimbriae, Pili, and Hami
STRUCTURES AND INCLUSIONS - Pili
Capsules and Slime Layers - Thin filamentous structures
- Sticky coat of polysaccharide made of protein extend
formed outside the cell envelope from surface of cell
- Mediate attachment, protection, - Enable bacterial cells to
alter diffusive environment stick to surfaces
- When binding to solid surfaces, - Form pellicles in liquid
they form a thick layer = biofilm surfaces
- Capsule - Form biofilms in solid
- organized in tight matrix, surfaces
excludes small particles, - All gram-negative bacteria
tightly attached to cell produce pili
- Visible in light microscopy, Types of Pili:
treated with India ink - Conjugative pili - facilitate
(stains only the genetic exchange during
background, cannot conjugation (cell-to-cell
penetrate the capsule) attachment)
- Also seen in electron - Electrically conductive
microscopy pili - conduct electrons
toward or away the cell,
plays role in metabolism
- Type IV pili - facilitate
adhesion, support twitching
motility (allows cells to
move along solid surface)//
assist in infectivity of some
pathogens: cholera,
gonorrhea, strep throat,
scarlet fever
- F pilus (sex pilus) - path
of entry of genetic material
- Microcapsule - if the layer during mating
is too thin to be seen by
light microscope - Fimbriae
- Short pili that mediate
- Slime layer attachment
- Easily deformed, loosely
attached, include particles,
more difficult to see, easily
detected in colonies,
abundant and embedded in
common matrix (ex: lactic
acid Leuconostoc)
- Also stained by india ink
 - Hami/ Hamus Polyphosphate, Sulfur, and
- Resembles a tiny grappling Carbonate Minerals
hook - Polyphosphate
- Present in SM1 group - Granules in accumulation
(Archaea) of inorganic phosphate
- Attach cells to surfaces to - Formed when phosphate is
form a networked biofilm in excess
(more efficient trap for - Can be a source of
scarce nutrients present) phosphate for nucleic acid
and to each other and phospholipid
biosynthesis

CELL INCLUSIONS - Sulfur
- Often visible with light microscope - Sulfur bacterias: organisms
Carbon Storage Polymers that oxidize reduced sulfur
- Poly-β-hydroxybutyric acid compounds
(PHB) - Discovered by Sergei
- most common inclusion Winogradsky
body in prokaryotes, - Also used for energy
monomer polymerized by metabolism
ester linkage - Carbonate materials
- Monomers are usually - Formed by filamentous
hydroxybutyrate (C4) cyanobacteria on external
- poly-β-hydroxyalkanoate & internal surface of cell
(PHA) - more generic term, - Gloeomargarita : forms
synthesized when there is granules of bentonite
an excess carbon// broken (carbonate material)
down for energy (carbon) containing barium,
- Glycogen strontium, magnesium
- Polymer of glucose - Biomineralization -
- Reservoir of carbon and microbiological process of
energy forming minerals
- Also produced when there
is an excess carbon
- Resembles starch (storage
reserve of plants)
 Gas Vesicles - They only grow when conditions
- Confer buoyancy allows floating become favorable (high alanine
- Allow cells to position themselves and nutrients)
in regions of water column best - Easily dispersed by wind, water,
suited for their metabolism animal gut (widely distributed)
- Conical-shaped - Produced only by 2 groups:
- Impermeable to water and solutes, (1) Bacillales (2) Clostridiales
permeable to gases - Both are gram positive
- Gas vacuoles - clusters of - Causes food spoilage and
vesicles foodborne diseases +
- Blooms tetanus & botulism
- Gas-vesiculate microbes
that form massive Formation and Germination
accumulations - Sporulation
- Common on near lake - process of cellular
surfaces where sunlight is differentiation that results in
intense endospore formation
- Triggered when nutrient
Magnetosomes becomes limiting
- Allows bacteria to orient - Germination
themselves in a magnetic field thru - Conversion of endospore
magnetic dipole back to a vegetative cell
- Biomineralized particles of: - Triggered by availability of
- magnetic iron oxides nutrients like amino acids
magnetite or greigite and sugars
- Magnetotaxis - process of - Occurs in 3 steps:
migrating along Earth's magnetic activation, germination,
field lines outgrowth
- Spiked-shaped - most common
- Could also be square/rectangular Structure and Features
- Visible by light microscope as
ENDOSPORES strongly refractile structures
- Specialized spores - Impermeable to most dyes
- Endo = within - Malachite green stain - used
- Highly differentiated dormant cells infused to spore with steam
that can tolerate harsh conditions - Contains many layers absent from
- Dormant stage of bacteria life vegetative cell (seen in electron):
cycle: vegetative cell -> endospore - Core - innermost, contains
-> vegetative cell DNA and ribosomes, from
cytoplasm of vegetative cell
- Inner membrane - from
cyto membrane of vege cell
- Cortex - 2 peptidoglycan
layers
- Outer membrane - special
membrane formed during
sporulation
 - Endospore coat - Flagellum / Flagella
composed of layers of - Provides swimming motility for
spore-specific proteins bacterias
- Exosporium (not all) - - Long, thin appendages
outer proteinaceous layer - Observed by light microscopy or
- Dehydration of the core - ultimate electron microscopy
reason for endospore toughness// - Tuft - group of flagella
caused by accumulation on - Do not rotate in constant speed, it
calcium-dipicolinic acid depends on the proton motive
- Small acid-soluble spore force
proteins (SASPs) - Fastest speed - 60 cell-lengths/s
- made during sporulation - Not straight but helical
- 2 functions: - In order to change direction, they
1. Bind tightly to DNA also need to change the direction
in the core of their rotation (ex: CW - CCW)
2. Protect from - Can be anchored to a cell in
damage of UV different locations:
radiation, dry heat, Polar flagellation
desiccation - attached at one or both ends
- they spin around moving from
The Sporulation Cycle place to place
- tuft at one end is called
lophotrichous seen by dark-field
or phase contrast microscopy
- tuft at both ends is called
amphitrichous

Peritrichous flagellation
- flagella inserted around cell
surface
- move slowly in a straight line

CELL LOCOMOTION Structure of Flagella
Motility -Filament
- allows cell to reach different parts - composed of many copies of
of their environment proteins called flagellin
- 2 major types of prokaryotic - hook - wider region at the base,
movement: swimming & gliding single type of protein, connects the
- Taxis - how motile cells are able to filament to the flagellum motor
move towards or away from stimuli - flagellum motor - reversible
- Flagella & Archaella - tiny rotating rotating machine, anchored in
machines that function to push or cytoplasmic membrane and cell
pull the cell through a liquid wall
 - Rotor - consists of central rod, L,
P, C, MS rings// make up the
flagellar basal body
- Stator - consists of the mot
proteins that surround the rotor
and function to generate torque

Flagellar Synthesis
- Filament grows from tip
- MS & C rings are synthesized ->
inserted to cyto membrane ->
followed by other rings -> early
hook -> cap -> late hook ->
filament synthesis

Central rod - passes thru a series
of rings
L-ring - outer ring in outer
membrane
P-ring - in peptidoglycan layer - Flagellin flows through the hook to
MS and C Rings - third set of form filament
rings, within cytoplasmic - Cap - a protein present at the end
membrane and cytoplasm of growing flagellum to guide them
Mot proteins - series if proteins into position
that surrounds the inner rings, in
cyto membrane and Archaellum / Archaella
peptidoglycan// sets the proton - Present in archaea
flow rate - Rotate same as flagella
Fli proteins - set of proteins, - 7-12 genes encode the major
functions as motor switch, proteins that make up it
reversing the direction of rotation - Usually studied in Halobacterium
of the flagella (salt-loving)
- The speed is slow due to smaller
diameter than flagella (smaller
diameter = reduced torque)
- Methanocaldococcus can swim at
500 cell lengths per sec
- Embedded in archaeal cell wall
and cyto membrane
- Hydrolysis of ATP drives the
rotation (not proton motive force)

Flagellum motor has 2 components:
 MICROBIAL LOCOMOTION
Internal Movement (Cytoplasmic
Streaming)
- Organelles move within cytoplasm
- Governed by actin filaments and
cytoskeleton
- Facilitates distribution of nutrients
and materials inside the cell

External Movement (Motility)
- Involves specialized organelles for
locomotion
- Capable of CW and CCW rotations
- Pseudopodia - temporary
extensions of the cell body
CILIA
- Cilia - short, haiir-like structures
- For cell motility and sweeping food
- Flagella - long, whip-like
organisms into oral cavity
- Energy from ATP
- Beating caused by intraciliary
SURFACE MOTILITY
excitation followed by interciliary
- All surface motility are
conduction
considerably slower than
4 types of ciliary movements
swimming motility
1. Pendulus ciliary movement
- Carried out in single plane
Twitching motility
- Occurs in paramecium (those who
- Requires type IV pili which extend
have rigid cilia)
from one pole of the cell, attach to
2. Unciform ciliary movement
the surface, then retract to pull the
- Hook-like movement
cell forward
- Metazoan cells
- Energy is from ATP hydrolysis
3. Infundibuliform ciliary
- Allows cells to move in groups
movement
- Facilitated by type IV pili and
- Occurs due to rotary movement of
secretion of extracellular
cilium and flagellum
polysaccharides
4. Undulant movement
- Observed in Pseudomonas &
- Waves of contraction
myxobacteria
- Myxobacteria exhibit 2 forms:
CYTOSKELETAL COMPONENTS
social motility (caused by
Intermediate filaments
twitching) & adventurous motility
- Rope-like assemblies of fibrous
(gliding)
polypeptides
- Support the nuclear envelope and
plasma membrane
Microtubules
- Small, hollow cylinders made of
tubulin protein
- Composed of a-tubulin and
b-tubulin
 Gliding motility Chemotaxis in Polarly
- Smooth motion along the axis of Flagellated Bacteria
the cell without the aid of external - Similar to peritrichously flagellated
propulsive structures cells but they do not tumble but
- Continuous form of movement in a instead they swim backwards
helical track - Biased random walk - can
- Gliding bacterias are typically navigate effectively through their
filamentous or rod shaped environments toward conditions
- No gliding archaea known that favor growth and away from
- Best observed in myxococcus and those that could inhibit growth or
flavobacterium otherwise cause harm
- Gliding motors - rotary motors
driven by proton motive force
which are operationally similar to Other Forms of Taxis
flagellar motors - Phototaxis - response to light
- Observed in filamentous
cyanobacteria
CHEMOTAXIS - Photoreceptor - senses light
- Taxis - directed movement toward - Scotophobotaxis occurs when a
a stimuli phototrophic bacterium happens to
- Chemotaxis - response to swim into darkness outside the
chemicals illuminated field of view of the
- Observed in swimming bacterias microscope
(E. coli) by observing altering of - mechanism to prevent
rotations of flagellum phototrophic cells from
swimming away from a
Chemotaxis in Peritrichously lighted zone into darkness
Flagellated Bacteria
- Runs & tumble
- Runs - cell is swimming - Osmotaxis - response to ionic
forward in a smooth fashion strength
- Tumble - when the cell stops and - Hydrotaxis - response to available
jiggles about randomly water
- In the absence of attractant, the - Aerotaxis - response to O2, ex:
cell moves about its environment in Microaerophiles
random fashion through a series of - Magnetotaxis - magnetotactic
runs and tumbles bacteria found where O2 are low
- In the present of attractant, the cell - do not actually exhibit
moves toward the attractant but directed motility toward
not DIRECTLY but thru a biased magnetic fields but instead
random walk are exhibiting aerotaxis
- Chemoreceptors - sense
attractants and repellents
LESSON 3: MICROBIAL NUTRITION Energy Sources
- Phototrophs - use light as energy
Macronutrients / Macroelements source
- required by microorganism in - Chemotrophs - obtain energy
relatively large amount from the oxidation of chemical
- C, H, O, N, S, Ca, P, Fe, K, Mg compounds (organic / inorganic)
- Cations: K, Ca, Mg, Fe
- K - required for the activity of Electron Sources
enzymes, osmoregulation, pH - Lithotrophs - use reduced
homeostasis, protein synthesis inorganic substances as electron
- Ca - for heat resistance, required source
in cell division and cell membrane - Organotrophs - extract electrons
- Mg - stabilizing ribosomes and from organic compounds
membrane
Note: They could be combined. Ex:
Micronutrients / Trace Elements - Photolitotrophs - photo + litho
- Required by microorganism in - Photolithotrophic autotrophs -
relatively small amount photo + litho + autotrophs
- Normally part of enzymes and - Chemoorganotrophic
cofactors, aid in catalysis of heterotrophs - chemo + organo +
reactions and maintenance of heterotrophs
protein structure - etc.
- Fe2+ & Fe3+ - cofactor of
enzymes and electron carrying Requirements for Nitrogen,
proteins, part of cytochromes Phosphorus, and Sulfur
- Vitamins - functions as - Nitrogen
coenzymes, required growth factor - Needed for the synthesis of amino
- Manganese - aids enzymes acids, purines, pyramidines, some
catalyzing the transfer of carbohydrates and lipids, enzyme
phosphate groups cofactors
- Zinc - present at the active site of - In most autotrophs and many non
some enzyme, catalytic subunits of photosynthetic microbes
E. coli aspartate carbomoyl (Cyanobacteria Rhizobium) :
transferase - Reduce nitrate to ammonia
- Molybdenum, nickel, copper - Incorporate ammonia in
assimilatory nitrate
Nutritional Types of reduction
Microorganisms - Phosphorus
Carbon Sources - Present in nucleic acids,
- Autotrophs - use CO2 as sole or phospholipids, ATP, several
principal source of carbon, uses cofactors, some proteins and cell
light as energy source components
- Heterotrophs - use reduced - Used by ALL microbes
pre-formed organic molecules as - Sulfur
carbon sources - Needed for synthesis of amino
acids (cysteine, methionine), some
carbohydrates (biotin, thiamine)
- Some microbes require reduced Temperature Requirements
form of sulfur such as cysteine - Most important factor that can
affect growth of microorganisms
Growth Factors - Temperature range - must not be
- Used by microbes that lack one or above the maximum or below the
more enzymes needed for the cell minimum as it can affect growth
components or precursors of the - Optimum - growth occurs
mentioned components best (ex: pathogenic
Major Classes: bacteria, -37 degrees C)
- Amino acids Temperature classes (in degrees C):
- for protein synthesis - Psychrophiles
- Purines & Pyrimidines - 15 or lower
- For nucleic acid synthesis - max: -10
- Vitamins - Psychrotrophs / Facultative
- Small organic molecules Psychrophiles
that make up all or part of - 20 - 30
enzymes cofactors, only - max: 35
very small amounts sustain - Mesophiles
growth - 25 - 40
- min: 15-20,
Growth Requirements max: 45
Gaseous Requirements - Thermophiles
- Aerobic Bacteria - 55 - 60
- require oxygen for growth - min: 45
- Obligate aerobes to grow only in
the presence of oxygen Other Requirements:
(Pseudomonas aeruginosa) - Moisture and drying
- Anaerobic Bacteria - Hydrogen ion concentration
- Grow in absence of oxygen - Light
(Clostridium tetani) - Osmotic effect
- Obligate anaerobes - may - Mechanical and sonic stress
die on exposure to oxygen
- Facultative anaerobes - Growth Media
can grow in presence of Culture Media
oxygen & survive without - Nutrient solutions tailored to the
oxygen via anaerobic particular organism to be grown
respiration or fermentation - It must be sterilized before use thru
- Microaerophilic Bacteria heating of medium under pressure
- Proliferate (increase in #) in the in an autoclave
presence of low oxygen tension - Prepared selectively or
differentially or both
2 classes:
- Defined media - exact
composition of a defines medium
(quali and quanti sense) is known,
prepared by adding precise
amounts of pure inorganic or
organic chemicals to distilled water
 - Complex media - made from - Meat extract - aqueous
digests of microbial, animal, plant extracts from lean beef and
products like milk protein (casein), contain amino acids,
beef extract, soybeans (tryptic soy peptides, nucleotides,
broth), yeast cells (yeast extract) organic acids, minerals,
vitamins
Based on Consistency - Yeast extract - from
- Solid medium brewer’s yeast and contain
- Contains 2% agar an excellent source of vit B,
- Used for colony morphology, nitrogen, carbon
pigmentation, hemolysis compounds
- Ex: nutrient agar, blood agar
Based on Functional Use / Application
- Liquid medium 1. Enriched medium
- No agar - Broth or solid medium containing a
- Used for inoculum preparation, rich supply of special nutrients
blood culture, isolation of - Used for fastidious microbes
pathogens from a mixture - Ex: blood agar, chocolate agar
- Becomes cloudy as indication of 2. Indicator media
growth - Contain an indicator which
- Ex: nutrient broth changes color when a bacterium
grows in them
- Semi solid medium - Ex: Christensen’s urease medium
- For checking motility 3. Transport media
- Used for transporting the samples
Based on Nutritional Component - Delicate organisms may not
1. Simple media survive the time taken for
- Aka basal media transporting specimen w/o it
- Used for non-fastidious (not having - Ex: buffered glycerol saline
complex nutritional requirements) 4. Anaerobic media
bacteria - Used to grow anaerobic organisms
- Ex: nutrient agar and broth - Ex: Robertson’s cooked meat
2. Defined media medium
- All the ingredients are known 5. Differential medium
(quali and quanti) - One to which an indicator (typically
3. Complex media a dye) is added, which reveals by a
- Contain undefined ingredients and color change whether a particular
the exact contents are known metabolic reaction has occurred
- Ex: nutrient broth, tryptic soya during growth
broth, MacConkey agar (for - Ex: MacConkey agar (for lactose
Lactobacillus) fermentation)
- May contain undefined 6. Selective media
components: - Contain compounds that inhibit the
- Peptones - prepared by growth of some microbes but not
partial proteolytic digestion others
of meat, casein, soyameal, - Ex: Eosin Methylene Blue (EMB) -
gelatin, and other protein contains dyes that are not for gram
sources positive bacteria and allows growth
 of gram negative bacilli and enteric Laboratory Culture of
bacilli - coliforms and faccal Microorganisms
coliforms 1. Agar
- Used to solidify the culture media
Isolation of Pure Cultures - An algal polysaccharide first used
- A pure culture is needed to in the classical studies of Robert
characterize and identify an Koch
individual species - Solid media immobilize cells so
- Culture methods include: that as they grow, they accumulate
1. Stab culture in a pile to form visible, isolated
- Prepared by puncturing a suitable cell masses called colonies
medium - with a long, straight wire 2. Colony morphology
- Used to study oxygen - Visible characteristics of a colony
requirements - Used to identify microbes but is
2. Pour plate method routinely used to determine if
- Gives an estimate of the viable culture is:
bacterial count in a suspension - Pure - only one microbe
- Used for quantitative urine cultures - Contaminated - undesired
- Should be avoided when trying to organisms co-occur
determine viable cell counts of - Mixed - many microbes
heat-sensitive bacteria isolate present
3. Liquid culture 3. Aseptic technique
- Inoculated by touching with a - Series of steps by which microbes
charged loop or by adding are transferred between growth
inoculum with pipettes or syringes media without contamination
- Used for blood culture, sterility
tests & continuous culture methods
4. Anaerobic culture methods
5. Streak culture
- Isolation of bacteria in pure culture
from clinical specimens
6. Lawn culture
- Provides a uniform surface growth
of the bacterium - Contamination can be introduced
- Can be used for bacteriophage from microbes in the air, in liquid
typing, antibiotic sensitivity testing, droplets, or on surfaces
preparation of bacterial antigens - Streak plate technique - method
and vaccines for obtaining pure cultures that
- Prepared by flooding the surface of contain a single microbe, and of
the plate with a liquid suspension verifying culture purity using
of the bacterium inoculating loop
7. Stroke culture
- Made in tubes containing agar Microbial Growth
slope or slant provide a pure Growth
growth of bacterium for slide - Increase in number of cells (binary
agglutination and other diagnostic fission)
tests - Cell division following enlargement
of a cell to twice its minimum size
 - During cell division, each daughter N - final cell number
cell receives a chromosomes and No - initial cell number
sufficient copies of all other cell N - number of generations during the
constituents to exist as an period of exponential growth
independent cell

Four Phases of Microbial Growth
1. Lag phase
- Initial phase, bacteria are
metabolically active but not
dividing
2. Log phase (exponential phase)
- Time of exponential growth
- Period when the growing cell
population doubles at regular
intervals (balanced growth)
3. Stationary phase
- Growth reaches plateau as the
number of dying cells equals the
number of dividing cells
- Not net increase or decrease in Synchronous Growth
cell number, thus growth rate=0 - Microbiological culture or a cell
- Cell prepares for maintenance and culture that contains cells that are
survival all in the same growth stage
4. Death phase - Information about growth
- Exponential decrease in number of behaviour of individual bacteria
living cells can be obtained by synchronous
- Decline phase - total number of cultures
cells decreases due to cell death - Synchronized cultures must be
composed of cells which are all at
Generation time = time per generation/ the same stage of the bacterial cell
number of generations cycle
(aka doubling time) - time required for
cell to separate Continuous Culture
- The cultures so far discussed for
growth of bacterial populations are
called batch cultures (describes
the growth of microbes in a fixed
 volume of liquid enclosed within a A. Direct Microscopic Count
container such as a test tube or a - A counting chamber consisting of a
flask) ruled slide and a coverslip is
- Since the nutrients are not employed
renewed, exponential growth is - Constructed in a manner that the
limited to a few generations coverslip, slide, and ruled lines
- Chemostat - most common type of delimit a known value
continuous culture device - The number of bacteria in a small
- An open system aiming to attain known volume is directly counted
steady state microscopically
- The number of bacteria in the
Diauxic Growth larger original sample is
- Used to describe the growth determined by extrapolation
phases of a microbes in batch
culture as it metabolizes a mixture B. Electronic Enumeration of Cells
of 2 sugars - The microbial suspension is forced
- Resulting in 2 separate growth through a small hole or orifice in
phases the coulter chamber
- An electrical current flow through
the hole and electrodes placed on
both sides of the orifice measure
its electrical resistance

C. Plate Count Method
- Standard Plate Count (SPC) -
number of bacterial colonies that
develop on a medium in a petri
dish seeded with a known amount
of inoculum
- Volume (usually 0.1–1.0 ml) of
Methods for Measurement of Cell Mass culture is pipetted into an empty
Microscopic cell count - total count of sterile Petri plate. Molten agar
microbial numbers can be observed and medium, tempered to just above
enumerated here gelling temperature (50°C), is then
Viable cell - one that is alive and able to added and gently mixed before
grow allowing the agar to solidify.
Viable count - performed by spreading
microbes on solid media and counting D. Membrane Filter Technique
colonies, aka plate count (requiring agar - The number of bacterial in aquatic
plates) sample can be determined from
Spread-plate & Pour-plate - 2 ways in direct counts after the bacteria
performing plate count have been trapped on special
Colony-forming units (CFU) - expressed membrane filters such as
as the number data from viable counts nitrocellulose more size filter or a
black polycarbonate membrane
filter
E. Turbidimetric Methods
- When bacteria growing in a liquid
medium are mixed, the culture
appears turbid due to bacterial
culture acting as a colloidal
suspension that blocks and reflects
light passing through the culture

F. Determination of Nitrogen
Content
- The major constituent of cell
material is protein, and since
nitrogen is a characteristic part of
proteins, one can measure a
bacterial populations or cell crop in
terms of bacterial nitrogen

G. Determination of Dry Weight
- Measure some quantifiable cell
property that increases as a direct
result of microbial growth
- Simplest technique is to measure
the weight of cells in a sample

H. Measurement of Specific
Chemical Changes
- Detects specific changes caused in
growth medium as a result of
multiplication of cells
- Includes detecting activity cell
products such as acid and gas
production

I. Spread-plate Method
- A volume of an appropriately
diluted culture is spread over the
surface of an agar plate using
sterile glass spreader