Bacterial Structure & Growth PDF

Summary

This document provides an overview of bacterial structure and growth. It covers topics such as endospores, bacteria domains, and other relevant concepts in microbiology. It is intended as study material for students in this subject.

Full Transcript

Enclonar, Kimberly / MLS 3A
o Mycobacterium tuberculosis: much
Bacterial Structure & Growth granules
October 15, 2020 o Corynebacterium diptheriae: BABES ERNST
Marx P. Catalan, RMT, MSMT GRANULES
o Nocardia spp.: Sulfur Granules
Bacteria
Unicellular bacteria Endospores
Prokaryotic small, dormant, asexual spores that developed
Average size: 0.5-2 um in diameter; 2-8 um in length inside bacterial cells
Mode of replication: binary fission Produced by: Bacillus & Clostridium
o Asexual reproduction
Produced in response to harsh environmental
o Organism duplicates its genetic materials
conditions
(DNA)
In favorable conditions, the bacteria will be in its
o Divides into two parts (cytokinesis)
vegetative stage
▪ Each receiving on copy of DNA
Mother cell will die and endospore will be released
in the environment. They remain dormant.
Smallpox virus - smallest virus
Thick Protein Coat: makes them highly resistant to:
Microscope for viruses - electron microscope o Chemical changes
o Temperature changes
Bacterial Domains o Starvation and dehydration
Archaebacteria o UV and Gamma radiation
o Lack peptidoglycan (murein) o Desiccation
o Extremophiles
Calcium dipicolinate: Found within the core. Makes
▪ Halophiles - loves extreme salt
up 10-20% of the spore's dry weight. It maintains
concentration the spores: DORMANT STAGE
▪ Thermophiles - loves extreme o Small acid soluble proteins (SASPs): Tightly
heat bind and condense the DNA. Responsible
▪ Anaerobic methanogens - loves
for resistance to: UV and radiation
methane o Can survive for 100 years or more. It is
o Not encountered clinical microbiology
important in the perpetuation of the
Eubacteria species
o Includes pathogenic bacteria
▪ Continuity of species
o Has tropism to eukaryotic cells o Endospores: Not for reproduction
▪ Tropism - ability of a certain o Fungal spores - used by fungal organisms
organism to infect a particular to replicate sexually and asexually
type of cell
One of the potent virulence factors of organisms.
▪ Proteobacteria o Virulence Factor - components of the
Thin gram negative cell organism that contributes to its virulence.
wall o Virulence - ability of the organism to cause
Includes: Photosynthetic, disease.
anaerobic photosynthetic
Endospores can germinate in the human body.
bacteria and
Gram stain: Endospores are colorless (endospore
cyanobacteria wall is impermeable to stains and dyes)
▪ Firmicutes
Moeller and Schaefer-Fulton stains: Endospores
Thick gram positive cell stains
wall
Used to identify organisms:
Includes rods, cocci, o Terminal spores
Actinomyctes and ▪ Clostridium tetani
Mycoplasma (wall-less o Central spores
bacteria) ▪ Bacillus cereus
o Subterminal spores
Cytoplasmic Structures ▪ Clostridium defficile
Do not contain: membrane bound nucleus Starvation initiates sporulation.
Genome: single circular chromosome o 0: Decision to use one of two potential
Ribosomes: consists of RNA and protein - floating in polar division sites for septum formation
the cytoplasm. o 1: Replication and formation of axial
o Site of protein synthesis filament
o Svedberg unit - sedimentation speed o 2: Septation, 2 unequal compartment
Prokaryotic Eukaryotic (forespore and mother cell)
o 3: Mother cell membrane engulfs
Ribosomes 80S → 60S & 70S → 50S
forespore
40S & 30S
o 4: Mother cell chromosome destruction.
Genome Single linear Cortex is formed.
circular o 5: Deposition of coat proteins
o 6: Maturation: completing development.
Cytoplasmic granules Synthesis of dipicolinic acid.
storage deposits and consist of polysaccharides o 7: Mother cell (sporangium) releases spore
such as glycogen and lipids such as poly-B-
hydroxybutyrate, polyphosphates Cell envelope Structures
 Enclonar, Kimberly / MLS 3A
Cell (Plasma) membrane o Sieve for water soluble substances to pass
Phospholipid bilayer with embedded proteins, does through protein channels called: PORINS
not contain: STEROL, except: Mycoplasma spp. ▪ Only allows small molecular
o Mycoplasma spp. Does not have cell wall substances to pass through
Acts as an osmotic and permeability barrier and ▪ Gram neg are innately resistant to
location of the electron transport chain vancomycin
Inhibits peptidoglycan
Cell Wall Structures layer
Humans do not have cell walls Vancomycin cannot pass
Rigid structure, provides shape and rigidity through porins and
Two major types: cannot reach the thin
o Gram positive cell wall peptidoglycan layer in
o Gram negative cell wall periplasmic space
Prevents bursting of cells from the high osmotic o Attachment sites to host cells
pressure inside Periplasmic space: contains the thin peptidoglycan
o Has a gel-like matrix containing nutrient
Gram Positive cell Wall binding proteins and degradative and
Thick peptidoglycan (murine) layer. detoxifying enzymes
Does not have inner and outer membrane o Contains amino acids, sugars, vitamins,
Each layer consists of 2 alternating polysaccharides: enzymes, irons, and essential nutrients
o N-acetyl d-muramic acid (NAM)
o N-acetyl d-glucosamine (NAG) Acid fast Cell Wall
Each layer is cross-linked (peptide bridge) with short Acid fast organisms are generally: gram positive cell
amino acids peptides consisting of 4 amino acid wall
residues. Contain a waxy layer of glycolipids and fatty acids
o L-alanine known as: MYCOLIC ACID, bound to the exterior of
o D-alanine the cell wall
o D-glutamate o 60% of the cell wall is lipid
o Meso-diaminopimelate o Strong hydrophobic molecule, making the
Teichoic acid: anchored to peptidoglycan organism difficult to gram stain
(horizontal) ▪ Gram ghost
Lipoteichoic acid (LTA): anchored to cell membrane o Resistant to: acids thus the name acid fast
Present in acid fast bacteria such as:
Gram Negative cell wall o Mycobacteria spp. & Nocardia spp.
Two layers: Inner and outer membrane
Outer membrane contains: proteins, phospholipids Cell Wall Deficient bacteria
and lipopolysaccharide (LPS) Mycoplasma spp.
o LPS: main component of gram neg cell wall Ureaplasma spp.
o LPS has 3 regions: o Contain sterol in their cell membrane
▪ Antigen O polysaccharide o Pleomorphic
It can bind to antibodies
▪ Core polysaccharide Surface Polymers
▪ Inner lipid A known as the: Glycocalyx
ENDOTOXIN Network of polysaccharide that project from the
Responsible for: fever cellular surfaces of bacteria
and shock conditions Found external to the cell wall of the organism
For it to function: cell Not common to all
should be lysed, and once Capsule
it is liberated, it o Made of polysaccharide polymers or
stimulates the immune polypeptides
response of the host o Compact & tightly associated in the cell
Causes uncontrolled o Role in virulence - evasion of phagocytosis
inflammation o Can be removed by boiling bacterial
There could be suspension
hemorrhage o Hydrophilic
Reduced RBCs circulating o Gram stain - appears as clear halo
to organs → reduced o Capsular staining - Hiss & Anthony's stain
oxygen → shock Slime layer
Even if the organism is o Similar to capsules but are more diffuse
dead, endotoxin still layers surrounding the cells
functions o Made up of polysaccharides
o Dosage of antibiotic is important to o Role in virulence - evasion of phagocytosis
prevent endotoxemia o Used by organisms to attach with each
o Test to detect endotoxins in medical other or to attach to host tissues
equipment: limulus amebocyte lysate Mechanisms of Phagocyte Evasion
(LAL) test o Masks attachment sites of phagocytes and
▪ Horseshoe crab, Limulus other components of the immune
polyphemus response
o Barrier for hydrophobic compound
 Enclonar, Kimberly / MLS 3A
▪ Pathogen-associated molecular ▪ Flagella surrounding the entire cell
patterns (PAMPs) - components in o Amphitrichous
the cell wall of the organism that ▪ Taft, or bundles of flagella at both
can be recognized by the poles
phagocyte o Atrichous
Unique to bacterial cells ▪ Absence of flagella
Danger signals
▪ Endocytic pattern-recognition
receptors (PRR) - attachment sites
of PAMPs
▪ Direct interaction - direct
interaction between PAMPs and
PRR
▪ Indirect interaction - PAMPs and
antibody + PRR
▪ Capsules are weak PAMP
o Molecular mimicry.
▪ Components of capsule that are Flagellar stains
similar to host's "self" o Fisher & conn
components o Leifson & Gray
▪ S. pyogenes has a hyaluronic acid
capsule similar to human Pilus/Pili
connective tissue Non-motile, long, hollow protein tubes that
o Difference in the nature of the phagocyte's connects two bacterial cells
membrane and the bacterial capsules. Also known as: conjugation pili
Bacteria must be more hydrophobic than Role on virulence: mediate DNA exchange (i.e, DNA
the phagocyte. containing antimicrobial resistant genes)
Some Killers Have Pretty Nice Capsule
o Streptococcus pneumoniae (and group B Fimbria/Fimbriae
Strep) Non-flagellar, sticky, proteinaceous appendages
o Klebsiella pneumoniae Use by organisms to adhere to one another and to
o Haemophilus influenzae the environment
o Pseudomonas aeruginosa Role in virulence: Adherence to host tissues
o Neisseria meningitidis
o Crytococcus neoformans - not a bacterium, Fundamental shapes
it is a fungus Bacilli (bacillus) - rod shaped organisms
Mucoid colonies on culture media indicate presence Cocci (coccus) - spherical or round organisms
of encapsulated bacteria Spirilla (spirillum) - spiraled or comma shaped

Bacterial Arrangements
Two factors that affect bacterial arrangements:
o Plane of division
o Position taken after cell division
▪ Depends on plane of division
Sagittal plane
o Diplococci or cocci impair
o Streptococci
Sagittal and frontal
o Tetrad
Flagellum/Flagella Sagittal, frontal, and transverse
Organ of locomotion o Sarcinae
Made up of flagellin proteins
Variation in the possession of flagella
Chemotactic agents - promotes chemotaxis
Responds to chemotaxis
o Positive chemotaxis
▪ Movement of organisms towards
the source of the signals
▪ Favorable conditions
o Negative chemotaxis
▪ Movement of organisms away
from the source of signals
▪ Harmful conditions
Location of flagella
o Monotrichous
▪ 1 flagellum at 1 pole
o Lophotrichous
▪ Bundle of flagella at 1 pole
o Peritrichous
 Enclonar, Kimberly / MLS 3A
Pairs o Nitrite
o Diplococci - N. Gonorrheae o Ammonium (NH4+)
o Diplobacilli - MTB Most microorganisms use NH4+ as a sole nitrogen
Chains source
o Streptococci Many organisms possess the ability to produce it
o Streptobacilli from amines
Grapelike clusters
o Staphylococci Growth Factors
Groups of 4 - tetrads Organic compounds needed by bacteria in order to
o Peptococcus grow. In bacterial culture, these substances are
Packets of 8 - cuboidal usually provided in the culture medium.
o Sarcinae o Prototrophic - do not require an exogenous
Palisades source of growth factor since they
o Organisms tend to place themselves side synthesize their own
by side (Corynebacterium) o Auxotrophics - require the addition of
growth factor to culture media for growth
Growth to occur.
Orderly increase of all chemical constituents of the Fastidious organisms - requires additional nutrients
cell Examples:
A process which entails the replication of all cellular o B-complex vitamins
structures, organelles and protoplasmic o Amino acids
components from the nutrients present in the o Purines
surrounding environment o Pyrimidines
Under favorable conditions, almost all bacteria are o Pentoses
able to produce very rapidly o Fatty acids
Generation time/doubling time
o The average time required for an organism Inorganic salts
to double its number Salt in small amount stimulates the growth of some
▪ E coli - 20 mins organisms
Organisms requiring concentration are called
3 Major Nutritional Needs halophilic
Source of Carbon 2-30% NaCl
o For making cellular constituents
o Carbon represents 50% of the dry weight Oxygen Requirement
of a bacterium Aerobes - grow in the presence of atmospheric
A source of nitrogen (free) oxygen
o For making proteins o Obligate aerobes: grow only in the
o Nitrogen makes up the 14% of the dry presence of oxygen (15-21% O2, 1% CO2)
weight ▪ Makes ATP in the presence of
Source of energy (ATP) Oxygen
o For carrying out cellular functions o Facultative anaerobes: fundamentally
aerobes, but can grow in the absence of
Carbon Requirement oxygen
Classification of organisms ▪ Makes ATP aerobically with
o Autotrophs (lithotrophs) - use CO2 as Oxygen, but can switch to
carbon source, with only water and fermentation if oxygen is absent
inorganic salts as substrates o Microaerophiles: grow best at low or
▪ Phototrophs - obtain energy reduced oxygen tensions (2-10% O2)
photosynthetically Anaerobes - grow in the absence of atmospheric
▪ Chemilithotrophs - oxidation of oxygen
inorganic compounds o Obligate anaerobes: grow only in the
o Heterotrophs (organotrophs) - require an absence of O2.
organic source of carbon (ex. Glucose) and o Aerotolerant anaerobes: do not grow well
obtain energy by either oxidation or but do survive in the presence of O2
fermentation however, they cannot perform metabolic
▪ All bacteria that inhabit the processes unless they are place in an
human body belong to this oxygen-free environment
category Why are some organisms anaerobic?
o These are toxic end-products
Nitrogen Requirement
Major component of proteins and nucleic acids of a
typical bacterial cell
Nitrogen fixing bacteria - organisms that can directly
use atmospheric Nitrogen gas (N2)
Nitrogen assimilation - formation organic nitrogen
compounds like AA from inorganic nitrogen However, aerobic organisms have the enzyme
compounds in the environment superoxide dismutase and catalase
o N2
o Nitrate
 Enclonar, Kimberly / MLS 3A
CO2
Some organisms require a higher concentration (5-
10%) of CO2 for growth
Capnophiles

Moisture
This is indispensable for bacterial growth. It serves
as a solvent for food and forms the major portion of
the protoplasm.
Organisms requiring increased moisture content are
termed humidophiles.

Temperature
Determination of Cell Numbers
Every bacterium has an optimal temperature: the Direct Counting Using the Microscope
temperature at which the organism grows best
Used to estimate the number of bacteria in a
Psychrophilic (cold loving) - grows at 1C-20C
suspension
Mesophilic - grows at 20-40C (most pathogens grow
Cannot distinguish live and dead cells
at 37C)
Uses: Petroff-Hausser Counting Chambers
Thermophilic (heat loving) - grows at 50-60%

pH
Most pathogenic bacteria have an optimal pH of
7.2-7.6
Acidophiles - grows at pH 6.5-7.0
Neutrophiles - grows at pH 7.5-8.0
Alkalophiles - grows at pH 8.4-9.0

Osmotic pressure
Organism requiring high osmotic pressures are
called osmophiles.

Bacterial Growth curve
Refers to the increase in number of organisms
Is obtained by plotting the logarithm of the number
of cells against the time of growth Direct Plate Count/Serial Dilution
Lag phase/period of rejuvention/Physiologic youth Growing dilution of bacteria on agar plate to
o The period of adaptation of the organisms determine the colony forming units per ml (cfu/mL)
to their new environment characterized by Provides a count of viable organisms only
little or no multiplication
o Best observed: after 6 hours of incubation
▪ Required incubation period: 18-24
hours
o The cell sin this phase are very active
metabolically. Active synthesis of enzymes
and other essential constituents occurs.
Exponential/Logarithmic Phase
o 18-24 hours after incubation
o The period at which the cells are in a state
of balanced growth characterized by
maximal rates of cell division and mass
increase.
o It is during this phase that the generation Density Measurement
time is constant. Testing for turbidity for bacterial suspension
Stationary/Plateau/Equilibrium phase McFarlan Standard
o 48hrs Measured using Optical Density (OD)
o The period at which the rate of cell o OD at 600nm or short OD600
production equals the rate of cell death.
o Growth ceases due to: Bacterial Cultivation
▪ Accumulation of waste products The process of growing microorganisms in culture
▪ Exhaustion of nutrients by taking bacteria from the infection site (in vivo
▪ Change in pH and other factors environment)
Death/Decline Phase Growing them in an artificial environment in the
o 72hrs or more
laboratory (in vitro)
o The period at which complete cessation of
multiplication occurs such that the death Agar
rate in the medium increase rapidly.
Agar or agar-agar is a gelatinous substance derived
from a polysaccharide that accumulates in the cell
walls of agarophyte red algae: Gelidium amansii
Makes culture medium solid
 Enclonar, Kimberly / MLS 3A
Microbial growth does not destroy the gel structure ▪ Alkaline Peptone water (APW)
because most microorganisms are unable to digest ▪ Selenite F broth
agar ▪ Tetrathionate broth
o Stool samples
Basic Ingredients of Culture Media Enriched Media
Beef Extract o Addition of extra nutrients such as blood,
o Beef is boiled and the resulting broth is serum, egg yolk, vitamins and growth
concentrated into a paste or dried to a factors to basal medium
powder. It contains amino acids, vitamins o To promote the growth of fastidious
and minerals. bacteria
Peptone ▪ Blood agar
o Protein is converted into proteoses, ▪ Chocolate agar
peptides and amino acids by means of ▪ Modified Thayer Martin Agar
enzymatic hydrolysis. o How many percent of blood agar or
o Source of energy for those that cannot chocolate agar are usually prepared in the
utilize CHO laboratory? 5-10% blood
Yeast Extract o What are the sources of blood used in the
o This is the water soluble portion of preparation of BA and CA? Most common
autolyzed yeast and contains amino acids, is sheep's blood. Can also use rabbit,
nucleic acids, vitamins and other growth horse or human blood, or reagents such as
factors. 2% Hgb.
o How to prepare? CHOC is heated to lyse
Culture Media: Classification RBCs. Therefore, hemolytic patterns
According to Consistency or Physical State cannot be observed,
Liquid/Broth Media Selective Media
o No agar/solidifying substances o Inhibits commensal and contaminants to
▪ Tryptone Soy Broth (TSB) promote growth of a particular organism
▪ Thioglycolate Broth o Contains inhibitors
▪ Nutrient Broth o What is swarming of proteus? Cocentric
o Indication of growth: turbidity rings of growth that are formed as cyclic
Solid Media events of swarmer cells.
o Contains 2-3% agar to solidify
▪ Plate Media
BA, CA, MAC
▪ Tubed media
TSI, LIA, citrate tube
Semi-Solid Media
o Contains 0.2-0.5% agar
▪ SIM (sulfide, indole, and motility
medium)
Biphasic Media
o Comprise both solid and liquid medium in
the same bottle
▪ Castaneda biphasic system -
Brucella

According to Composition
Synthetic Media
o Chemically defined
Non-synthetic media
o Not chemically defined
o Example: BA
Tissue Culture Media
o With living cells
o For viruses
o Intracellular bacteria

According to Use Selective & Differential Media
Basal/Simple Media o Selective media & differential media -
o Allows most non-fastidious organism to grows particular organisms and
grow differentiates its biochemical
▪ Nutrient Agar characteristics
▪ Nutrient Broth o Contains:
Enrichment Medium ▪ Inhibitors
o Liquid media that inhibit commensals and ▪ Carbohydrates
promote the growth of a particular ▪ pH indicators
organism o Blood Agar for Hemolytic Patterns
o Used to recover pathogens in an
anatomical site rich with flora
 Enclonar, Kimberly / MLS 3A
▪ Beta hemolysis: Complete Distribution
hemolysis characterized by a clear o Distribute in test tubes
zone around the colonies Sterilization
Although generally, non- o Autoclave/Oven
selective but can be Note: Plated medium - sterilized first before distribution
enriched with Colistin-
Nalidixic acid for Inoculation of Culture Media
inhibition of gran Liquid Media
negative bacteria o With the use of a sterile Pasteur pipette
▪ Alpha hemolysis: incomplete o Inoculate by shaking a previously heated
hemolysis characterized by wire loop or needle.
greenish pigmentation of the Slant Media
colonies o Zig-sagging manner across the entire
▪ Gamma hemolysis: no hemolysis surface toward the mouth of the tube
o Basic Principle: CHO utilization media as Slant & Butt Media
example o Inoculate the butt first by stabbing the
▪ Inhibitor needle to the bottom of the medium and
then streak the surface in a zigzagging
manner toward the mouth of the tube.
Butt Media
o Stab the medium with an inoculating
needle

Plated Media
General purpose Isolation Streak
1. To yield a semi-quantitative grow
2. Specimen is applied by rolling a swab or placing a
drop of liquid on a small area at the edge of the plate
3. Inoculating loop is sterilized and allowed to cool
thoroughly before streaking
4. Cooled loop is passed back and forth through the
inoculum in the first quadrant several times
5. First quadrant should be at least a quarter of the
plate, and the streak line should be closed together
6. The plate is turned, and quadrant 2 is streaked by
passing the loop through the edge of the first
quadrant a few times and then streaking the whole
2nd quadrant
7. Repeat step 2 but now in the 3rd down to the 4th
quadrant

Blood agar - non-selective. But can add nutrients to become
selective.

Special Culture Media
o Specially prepared to support the growth Quantitative Isolation Technique
of specific microorganisms To determine the number of bacteria present and
decide if the isolate is a true infection or a
contaminant
Used for urine specimens
1. Urine is mixed well, and a calibrated loop (0.1 or
0.001 mL) inserted in the urine and transferred to
the culture medium by making a single streak
down of the center of the plate
2. Without flaming, the loop is streaked back and
General Steps in the Preparation of Culture Media forth into the original inoculum
Weighing Formula
o Weigh the different ingredients and then Colony count = # colonies x factor
place in a clean, dry containers. o 1ul (0.001ml); factor 1000
Dissolving o 10ul (0.01ml); factor 100
o Add the exact amount of solvent to the If a 1ul is calibrated loop yields 145 colonies, the
ingredients and then dissolve by heating colony count is 145,000 colonies/ml urine
Titration >100,000 = infections
o Adjustment to the right pH (pH 7.2) 1000-100,000 = contaminants
 Enclonar, Kimberly / MLS 3A

Semi-quantitative Maki Roll Plate
1. Used to culture catheter tip specimens to
diagnose catheter-related blood stream
infection
2. Catheter is rolled back and forth onto a blood
agar plate
3. After incubation, count the colonies
o >15 CFU on the plate: TRUE INFECTION
o